WO2001006269A1

WO2001006269A1 - Method for measuring loss

Info

Publication number: WO2001006269A1
Application number: PCT/AT2000/000198
Authority: WO
Inventors: Roman Koller
Original assignee: Roman Koller
Priority date: 1999-07-15
Filing date: 2000-07-17
Publication date: 2001-01-25
Also published as: DE10082058D2; AU6138500A; DE10082058B4; WO2001006269A9

Abstract

The invention relates to an improvement of DE 42 40 739 C2 for measuring a loss (1/RVM) coupled to a measuring circuit (LM, Cp), whereby the loss is ohmically or inductively coupled to a measuring coil (LM) or additionally by means of a capacitance. The circuit is characterized in that it influences measurement with a loss (1/RVL) by means of a resistance value (Rp) that can be regulated by an adjustment signal (BD) at a constantly switched measuring value (1/RVM). The measured value (mp) is detected in several (at least two) measuring steps (t1, t2) in which the adjustable resistor (Rp) is variably adjusted.

Description

METHOD FOR LOSS MEASUREMENT

description

Properties / Applications: The invention relates to a loss measuring sensor that can be used particularly universally, in particular a method for measuring a loss using a corresponding sensor. In short, this sensor is also referred to simply as “loss sensor” before explaining this sensor or method some properties of the sensor should be anticipated-

• Measuring principle, measures inductively without contact or via fixed contacting all physical quantities that can be derived from measuring parts, liquids and gases via ohmic resistance or conductance, which forms a loss to be measured for the measuring circuit, such as distances, temperature, humidity, Conductivity, scanning of oscillations and vibrations, statements about molecular structure (in the case of gases) or also direct signal transmission, whereby instead of signals distorted by transit time and scattering, signals coded by loss variation can be transmitted without problems over long lines, by measuring the loss independently of absolute amplitude values

• Furthermore, the present sensor can be used for any physical sensor whose measurement size is measured via a part that moves to a fixed point and has electrical conductivity that can still be detected by the sensor, if, for example, the measuring coil that detects the loss is attached to this fixed point of the part moved by the physical size (e.g. the distance from the surface of a pressure transducer to a measuring coil, etc.) Further possible applications arise from the prior art for such sensors, such as layer thickness measurement, scanning of floating bodies for flow measurement, etc. It is evident that the measuring part can also be fixed and the measuring coil can be moved if necessary

• As an alternative to non-contact measurement, connection via contacts is also possible

• The measurement can be carried out at the lowest power, with high admissible interference radiation suppression The suppression of the interference radiation at the measuring point is essentially carried out by the measuring principle and not by shielding measures.This means with non-contact measurements, such as distance measurements, open construction and best integration into the respective Application is possible without having to consider possible interference radiation

• Free choice of a lower measuring frequency in the measuring coil (LM) over which the loss of the measuring coil is measured with free choice of the good

• Measuring the influence of the skin effect during the non-contact loss measurement on solid bodies (especially layers), liquids (eg blood, or determining the purity of distilled water), and gases, with the same loss of the sensor for different measuring frequencies

• Absolute temperature compensation of the temperature response of the measuring coil, high temperature versions of the measuring coil with any alloy with freely selectable (best) quality of the measuring circuit

• Absolute insensitivity to interference radiation, especially for frequencies that directly correspond to the measuring frequency of the measuring current flowing in the measuring coil and overlap them "with the measuring current to a significant disturbance variable. The interference radiation may have any (also modulated) frequency spectrum

• Due to its extremely low measurement performance and immunity to interference, the sensor can also be designed wirelessly according to the transputer principle. The wireless sensors can be well interconnected via RF transmission, or networked with one or more central controls. As an alternative, the sensors can also be contactless, inductive via a single core Induction cables are connected continuously, the induction cable ¹ inductively supplying the supply voltage and data communication to the sensors • The method can also be used to eliminate losses (evaporation) on completely different measuring principles, which otherwise have nothing to do with a loss measurement and the loss that occurs. Also for such applications, protection is sought, in particular with regard to claim 2 and its subsequent claims

• All measuring processes can be sabotaged safely, and self-tests can be carried out reliably and reliably over the entire measuring range

Preferred applications are: Precise non-contact length and distance measuring sensors for all physical sensors in which a dynamic or static change in distance is to be measured, such as angles or displacement position detectors, torque sensors, dent detectors on bodies, pressure sensors, measurement of spring travel, non-contact temperature measurement on parts and also in gases , e.g. combustion chambers of internal combustion engines. Networked measurements with wireless sensors for screw locking detectors (installed directly in the head or nut), monitoring the connection strength of connected parts, monitoring the connection strength of rotating parts, scanning structure-borne noise and vibrations of fixed or moving or rotating parts, length or temperature measurement in the high temperature range or for Large temperature differences, measurements of resistances for the medical sector, wirelessly networked security applications: railway track monitoring, security coding of objects and components such as cars or aircraft spare parts. Networked position detection of transponder-secured parts, such as goods storage locations, file storage locations. Furthermore, non-contact measurement of particularly high-resistance conductance values for layer thickness such as cannot currently be carried out with sensors corresponding to the state of the art, for example measuring the layer thickness of printer ink resins or coloring; in particular also for inductive measurement of the degree of moistening of new inks that can be switched in color by means of an electrostatic field. Furthermore, locally specific layer thickness measurement of particularly high-resistance layers via low frequency (e.g. sensor head with measuring coil LM for line-by-line scanning of surfaces, furthermore e.g. measurement of very thin self-adhesive aluminum or copper foils, which are glued to temperature surfaces to be measured, e.g. skin temperature for medicine are for the purpose of temperature measurement, ditto direct measurement of skin resistance, determination of the conductivity of blood, etc statement about the influence of the skin effect in blood measurements, similar to the measurement of gases, etc

Background and inventive idea:

The invention relates to the essential improvement for a loss measuring sensor in order to make the sensor completely insensitive to interference radiation at the measuring point.This is done by a method which uses a loss measurement to measure the conductance of an electrically conductive measuring part (K) inductively coupled into a measuring coil (LM) or one galvanically or capacitively connected resistor, or a connected or coupled capacitance, completely independent of the amplitude of the measuring AC voltage occurring at the measuring point over two or more steps or measuring time intervals in relation. Two alternative measuring methods are provided, which, however, can be derived from a common inventive idea: In a first embodiment variant, the measured value is derived from the associated voltage values according to a predetermined relation of loss values varied directly at the measuring point by means of the manipulated variable. In a second variant, the measured value is derived based on a predetermined relation of the voltage values, as they result from the corresponding associated setting of the loss values varied directly at the measuring point by means of the manipulated variable, from the manipulated variable of the loss values (or the relation of the loss values). Both variants have the inventive idea in common, over two or several measuring steps directly at the measuring point, without having to use a switching device or the like at the measuring point, to carry out a variation of the loss measured directly at the measuring point, and from the existi to determine the relationship between loss change and the associated change in amplitude to determine the measured variable at the measuring point completely independently of the absolute amplitude value (the oscillator oscillation or a scattering, etc.) It does not matter whether the measured variable existing as a resistance or conductance value is connected ohmic to the sensor (Fιg.6) or contactless and contactless inductive from a measuring coil (LM, Fgι.1) is detected. The measuring method according to the invention is thus universal and can be carried out directly with a circuit arrangement designed according to the prior art. In the following, however, further circuit measures are specified which are particularly well suited for carrying out the method according to the invention. Applications are: In the case of inductive coupling, the contactless measurement of distances and conductance values or, depending on their function, other physical parameters such as the temperature of the measuring part, strain measurement, layer thickness measurements of coatings etc; In the case of direct contact connection, for example, low-resistance resistors in series with the measuring coil or, as can be seen, for example, from documents (DE3248034 or DE3825111 / EP0352507), high-resistance resistors in parallel, or corresponding physical dependency functions, such as temperature, moisture, via loss of the dielectric a resonant circuit capacitor, etc. In particular, the method uses a measuring coil arrangement consisting of an alternating field coil (LM), the loss of which is also determined by the electrically conductive measuring part. A resistor (Rx, Fig. 6) can be connected as a measuring part, for example, directly to the alternating field coil (LM) via ohmic contact, or the measuring part (K) can be coupled into the measuring point in a contactless and non-contact manner via the electromagnetic field of the alternating field coil (LM) be (Fig. 1). Thus the measuring part determines the loss of the coil or the coil circuit (loss 1 / RVM) and is measured by a measuring device, in particular in a further embodiment according to claim 1. Since the measuring part K does not have to be electrically connected to the coil. the distance between the alternating field coil (LM) and the measuring part (K) can thus be measured without contact on the measuring part or medium, or the temperature of the measuring part (K) can also be measured without contact if the distance remains constant. The measurement of the measuring part (K) is a great advantage, but the invention can also be used, for example, for non-reactive radiation, especially low-resistance small resistance values (Rx, Fig. 6) that are connected in series with the alternating field coil (LM) to eat. Or in further training, to carry out a method for a signal transmission carried out by loss variation.

State of the art, in general:

The state of the art knows for loss measurement in addition to tip measurements, which evaluate the transient or decay process on the measuring coil, also bridge circuits, or filter circuits, such as resonant circuits (LM, Cp Fιg.1) or band filter circuits, in each of which the measuring coil (LM ) is switched. See e.g. DE 37 33 944 C2, DE 34 40 538 Cl, DE 32 13 602 C2, DE 30 42 781 C2 DE 28 05 935 Cl. DE-AS 26 41 798, DE 42 22 990 AI, DE 39 20 051 AI, DE 39 19 916 AI. DE 31 31 490 AI, DE 2 54 96 27B. FR 26 64 972 AI, EP 04 04 065 AI, EP 02 61 353, EP 02 45 605. Other sources: the documents further specified in DE 42 40 739 C2 and the further documents cited below.

Requirements:

The method according to the invention can in principle be carried out with any sensor corresponding to the state of the art if it has the following property: it requires a loss detection device which can be switched via an actuator and which must have the property that the loss value measured by the loss measurement sensor is directly at the measurement point, that is the point where the field lines penetrate the medium (K) or measuring part (1 / RVM) (or, in the case of an alternative galvanic connection, the area or the volume of the measured resistance value), the loss value measured by the loss measurement sensor in its measured value by means of the manipulated variable (BD Fig . 1) can be influenced as if this influence had been made at the measuring point itself (1 / RVM) by the measuring part. At this point (measuring point), any interference signal interference that may be present is recorded, which cannot be shielded in the case of non-contact measurement in practical use.This property is to be referred to as measuring points identical to the sensor's self-test property, in which an additional ohmic loss is directly present at the control signal or manipulated variable BD Measuring point can be fed in as an offset measurement quantity without the use of additional contact connections or switchover devices in addition to the currently measured loss. According to the prior art, this property only fulfills one sensor principle, which in the Patent specification DE 42 40 739 C2 is published and is shown in FIG. 1 as an example. However, almost all sensor variants corresponding to the prior art can be converted to this principle

In contrast to this unique principle, it is otherwise customary in sensor technology to carry out self-test or calibration cycles via a replica component connected to the measurement input, using appropriate switches or multiplexers. Such a method is used for a sensor of DE 32 48 034 The calibration pincnip used can eliminate disturbing side influences on the measuring resonant circuit, but not the interference radiation on the measuring point, since these have different effects on different components in different measuring cycles (measuring resistor and replica or reference resistor). Furthermore, a sensor according to DE 32 48 034 cannot be non-contact In particular, the disconnection of the resistance to be measured as a loss from the sensor input is absolutely necessary during the mutual connection of the simulation or reference resistors, therefore this principle has to be fulfilled The underlying task of the invention is fundamentally unsuitable

Another document considered, EP 0352 507, describes a loss sensor which works on the principle of the decay of a damped oscillation of the hull curve of a freely oscillating oscillator and which evaluates the hull curve over several successive measurement intervals. The capacitive loss of an oscillating circuit is primarily evaluated as a measurement variable, the loss itself is not varied during the measurement. A similar principle for measuring an inductive loss is described, for example, in DE 34 40 538 C1. The sensors mentioned do not see any variation in the loss at the measuring point. Ditto, no relationships between controlled loss changes and amplitude changes for determining the measurement result are made, as in the method according to the invention.

For the sake of completeness, the document SU 1651255 A, which is included in the test procedure, is given, but likewise does not affect the invention

In the case of sensors discussed according to the prior art, the interference is accepted at the measuring point. There are currently no sensors which, to the extent permitted by the principle in the present invention, were completely independent of interference at the measuring point

The present invention comes closest to the sensor published in patent DE 42 40 739 C2 by the same applicant with non-contact measurement, which is the only sensor with the above-mentioned measuring points that has identical self-test properties, via which an offset measurement quantity can be fed in directly at the measuring point without a A switch, changeover switch or multiplexer would be required if the measured variable was continuously switched on (1 / RVM)

State of the art, selected correctly:

The present invention can therefore be used as an improvement invention for the subject matter of DE

42 40 739 C2 (illustrated in FIG. 1), which relates to a method for measuring a loss coupled into a measuring coil arrangement (1 / RVM), consisting of an alternating field measuring coil (LM) and a resistor which can be distributed by means of a control signal (BD) (Rp) which is connected to the measuring coil as an additional loss (1 / RVL) and the total loss (1 / RVM + 1 / RVL) of the measuring coil (LM) varies accordingly. Furthermore, an evaluation (BW) results from the value of the adjustable resistance (Rp) and an amplitude measurement (us) of the measuring coil determines the loss coupled into the measuring coil as a measured value (mp). The measuring coil (LM) is preferably part of a parallel resonant circuit (LM, CP) via the transformation effect of which the adjustable resistor (Rp) connected in parallel is coupled into the measuring coil LM as a serial loss and occurs as a total loss (1 / RVM + 1 / RVL) where 1 / RVM is the loss coupled in via the measuring point (K), including the self-loss due to the ohmic serial resistance of the measuring coil, unα 1 / RVL is the loss of the Variable resistance Rp is. As a special case, the variable resistor Rp is designed as a switched fixed resistor which can be switched on or off (infinitely) via an electronic switch HS. The different design variants can be found in DE 42 40 739 C2 (as prior art). FIG. 1 is also taken from this application. FIG. 1 shows the embodiment variant already proposed in DE 42 40 739 C2, in which the measuring coil (LM) is part of a resonance circuit (LM, Cp). K ... affects the electrical conductivity of a material or an environment within which the field lines of the measuring coil (LM) are located.

The object of the present invention is to change the method from DE 42 40 739 C2 so that it is completely immune to interference radiation. If e.g. a frequency corresponding to the measuring frequency radiates directly into the resonance circuit (LM, Cp) of the alternating field coil (LM), then this should not matter, even if e.g. the recorded interference radiation would be a multiple of the measurement amplitude. This object is achieved in that, in order to obtain a measured value corresponding to the loss of the sensor to be measured, not only is an individual or constant amplitude value measured, but several measurements are carried out as relative measurements to one another (relations), which are thus related to one another, that the measurement result can be derived independently of the absolute values of the measurement amphtude of the resonance circuit (for example, as their ratio), taking into account the resistance conditions used. The method is not limited to a resonant circuit, just as e.g. with a band filter circuit, or other filter circuit, or also with a bridge circuit, the method can be carried out. See DE 42 40 739 C2. In a further improvement, when using the option in which the alternating field coil (LM) is connected in a resonance circuit, a constant current feed for the resonance circuit is still used, which further improves the method with regard to interference signal suppression. However, this constant current supply is not absolutely necessary.

The improvement (in the present case, according to the characterizing part of claim 1, illustrated in FIG. 2b and FIG. 2c) relates to the inventive measure that a measured value (mp) is determined over several (at least two) measuring steps (tl, t2) , in which the adjustable resistance (Rp) is set differently and for these different resistance settings (Rpl, Rp2) the ampiitude measurements (usl, us2) are made on the measuring coil (LM), whereby in contrast to DE 42 40 739 C2, the Measured value (mp) is determined from the change in value (eg from the ratio) of the resistance settings (Rpl. Rp2) used in the individual measuring steps (tl. T2) and associated amplitude changes (usl, us2), eg using a ratio calculation and / or retrieving function values stored in tabular form. See below for the embodiment variants described for Fιg.2b and Fιg.2c

In the preferred method, the property of the method according to DE 42 40 739 is still used, which allows the assessment device (BW) to control a change in loss of the measurement result (cf. actuating variable BD, Fig. 1) as if this influence were on the Measuring point itself, which is (for example, contact-free) in the electromagnetic field of the measuring coil

The solution to the technical problem corresponds to the above-mentioned improvement or claim 1. The preamble of claim 1 corresponds to the prior art according to the cited DE 42 40 739 C2 with a suitable circuit design according to FIG. 1, but taking into account that the inventive Methods can be carried out with general circuits known in the art.

The circuit according to Fig. 1 can be used directly to switch the Rp values accordingly via a control signal (BD) in accordance with the method according to the invention in the measuring time intervals tl and t2, which according to DE 42 40 739 C2 means a corresponding variation in the measured variable at the measuring point (1 / RVM) by the measuring part itself. In an expansion of the method according to the invention according to DE 42 40 739 C2, for each switchover value of Rp (Rpl, Rp2), or for the resulting variation value of the total loss at the measuring point, the associated associated occurring different voltage values ul and u2 measured. In the following section "Preferred exemplary embodiments and variants", two special cases for the implementation of this measuring method are described and referred to as variant 1 and variant 2.

Significant differences from the state of the art:

The following differences thus result with reference to the cited prior art:

The circuit which is included in the test method and which is specified in DE 32 48 034 and which, by using reference resistors, connects the calibrated actual values to the measuring gear as an alternative, is generally known to the person skilled in the art as a calibration method by learning and must not be confused with the method specified in the present invention. The method used in the present invention does not connect calibration resistances to the measured value as an equivalent resistance to the measured value, but only increases the loss of the measured variable at the measuring point when the measured value is switched on continuously (ie continuously) over all measuring steps of the method (without a changeover being carried out at the measuring point) is). In a further development, the loss of the measured variable at the measuring point can not only be increased, but in particular also reduced by adding an exact negative loss. This opens up a completely new field of application for such a sensor.

In all measurement cycles, the actual measurement variable remains switched on (in contrast to the documents included in the test procedure) Ditto, no multiplexers are provided for the connection of reference resistors at the sensor input.

In addition, and that is a very important difference, the publications of the researched publications do not provide any relation definitions for loss values set differently in different measuring cycles by (additive) manipulated variable to corresponding measured value or voltage value relations for the determination of the measured value completely new territory for the possibilities of using a loss measuring sensor is entered in DE 32 48 034, which is included in the test procedure, no evaluation of the ration is carried out for the calibration measurement described, but instead the internal absolute measurement of a reference resistance around a table is carried out by learning from measured values when the measured value input is switched off To be able to calibrate absolute values, on the other hand, in the present invention, the preferred relation definition is integrated into the method according to the invention, and in two alternatives Variants can be applied in both directions (via the measuring steps tl and t2: with 1 / RVL1 and usl in tl; or with 1 / RVL2 and us2 in t2) - a) in a first variant, the result is the loss value relation (1 / RVL1 + 1 / RVM or 1 / RVL2 + 1 / RVM) set via the manipulated variable (BD) Amplitude value relation (usl, us2) infer the measurement quantity (mp) (loss value relation is specified as a constant, resulting amplitude value relation is measured) b) in a second variant, a predetermined amolitude value relation (usl, us2) is obtained, which is determined via the manipulated variable (BD) by adjusting the loss value relation (1 / RVL1 + 1 / RVM, 1 / RVL2 + 1 / RVM), the measurement variable (mp) is deduced from the corresponding loss value relation (amplitude value relation is given as a constant and set via the loss value relation)

These essential differences also concern the publications EP 0352 507 and SU 1651255 A, which are also cited

Preferred examples and variants:

Version 1: For embodiment variant 1 explained below, measured loss intervals or resistances (changeover from value Rp = Rpl in tl to value Rp = Rp2 in t2) are used in the measurement intervals tl and t2. The measurement intervals tl and t2 are selected so that a constant measurement size (1 / RVM) can be assumed in the successive measurement intervals. The amplitude values associated with the switched loss values (voltage values ul in tl or us2 in t2) are measured and the measured variable is determined from the relationship between loss values (Rpl, Rp2) and voltage values (ul, u2). This preferred variant of the method is illustrated in FIG. 2b (cf. supplementary explanation in the following chapter "Show the individual figures").

In a preferred development, for a further simplification, the preferred connection of two different loss values (1 / RVL) via the adjustable resistor Rp, the special case is preferred to switch on a constant parallel resistor Rp for one of the two measurements (t2) and for the other measurement (tl ) to switch off, the measurements being carried out so quickly in succession that the measured loss value (1 / RVM) does not change significantly between these measurements. With a constant resonant circuit current (ires), the relationship is: usl / us2 = Rpl / Rp2, where Rpl = infinite, thus 1 / RVL = 0 and 1 / RVM is measured;

Rp2 = Rp, or 1 / RVL is switched on and 1 / RVL + 1 / RVM = 1 / Rp ^'is measured.

Goods e.g. usl = 2 * us2, then 1 / RVL = 1 / RVM with 1 / RVM loss to be measured, from which the self-loss of the coil has to be deducted, which e.g. is taken into account by the table, cf. DE 42 40 739 C2. Depending on the requirements, the sensors can also be exemplarily calibrated through a learning process, e.g. even in temperature measurement applications with a reference sensor that has a different physical principle. Or for layer thickness measurements of coatings through exemplary testing.

In general: RVM ~ Rp '* usl / us2, where - stands for proportional (e.g. as

Input value for a linearization table). Rp can also be a constant, which is why a resistance value for Rp is sufficient.

Version 2:

In variant 2, explained below, a fixed relation of the respectively measured voltage values (ul in tl or us2 in t2) is established in the measuring intervals tl and t2 by corresponding resistance adjustment variation via the loss values or resistances switched in the measuring intervals (switching of value Rp = Rpl in tl is set to the value Rp = Rp2 in t2) and the measured variable is determined from the loss value relation obtained in the resistance comparison. This preferred variant of the method is illustrated in FIG. 2c (cf. also the following chapter "Show the individual figures").

This embodiment variant enables the analog / digital converter for the conversion of the measuring voltage us to be saved, as well as the arithmetic operation usl / us2. Instead of the analog / digital converter, a fixed ratio usl / us2 can be checked using a voltage divider and comparator, e.g. whether usl / us2 = 2. If this is the case, then 1 / RVL = 1 / RVM (see example above). In order to achieve usl / us2 = 2, the adjustable resistor Rp is then designed as a digitally adjustable resistor cascade, e.g. a network common to A / D converters whose first or further MSB mosf sgmificant bit) set the relevant resistance value statically with high resistance (as offset value) ), whereby the less significant bits are compared by usl / us2. See also DE 42 40 739 C2, further example of Fig. 3 explained below. The setting of usl / us2 = constant, for example = 2, is then made by stepwise advancement or successive approximation performed. The ratio usl / us2 can be set arbitrarily for this constant if this is taken into account when converting the results. Furthermore, as already proposed in DE 42 40 739 C2, the resistance cascade Rp can be adjusted via a measurement table in such a way that the end result is already the measured value, which then corresponds to the above-mentioned mathematical relationship (scaled according to measurement task) in distinction to DE 42 40 739 C2, however, at least two measuring steps are provided for the determination of a measured value (mp) in the method in the present invention, one measuring step (tl), in which the resistance Rp = infinitely switched (for simplicity only switched off with HS) and a further measuring step (t2), which is divided into a large number of adjustment sections for establishing the fixed ratio usl / us2 = constant (for simplification, so that the dividing process can be saved with a cheap microcontroller). However, if the procedure with direct calculation of the ratio usl / us2 (variable) is used with Rp2 = constant value according to variant 1, the balancing within t2 is omitted, but usl / us2 can no longer be defined as a constant.

For example, if variant 2 is selected for the present method according to the invention using the preferred adjustment after a constant voltage ratio usl / us2 = constant with variable Rp2 and a table is used for the evaluation, e.g. described in the following explanation to Fιg.2c, then it is not necessary to keep the resonant circuit feed current constant; it is sufficient if the feed resistance (Ri) of the resonance circuit remains constant, in which case, for example, a correspondingly sufficiently stable feed circuit, e.g. an oscillator (OSZ) in which the resonance circuit (LM, Cp) is connected to determine the frequency, is used. See the following explanation of the figures for Fig.2c.

Advanced version with constant alternating current supply of the resonant circuit current:

If the feed resistance (Ri) of the resonance circuit for the required measurement accuracy cannot be made high-resistance compared to the measured variable RVM (see 1 / RVM) for the circuit design, then a constant alternating current supply (ires) is provided as an optional further development for the feed of the parallel resonant circuit. This ensures that the different voltage values ul and u2 measured at different Rp and 1 / RVL values over the time intervals tl and t2 always occur at identical currents (iresl = ires2) of the resonance circuit (LM, Cp)

In a simpler version, constant control of the constant alternating current (ires) fed into the oscillating circuit can be carried out well by setting the supply voltage of the oscillator if the output internal resistance of the supply circuit coupled to the parallel oscillating circuit (LM, Cp) of the sensor coil (LM) remains constant. The resonance circuit current is monitored for maximum amplitude (sensor voltage) via a measuring resistor (Rmi, Fig. 5) connected in series with the output internal resistance of the oscillator (OSC), and a D / A converter is controlled via the microcontroller, which converts the oscillator supply voltage via a corresponding amplifier circuit delivers, (see also below to Fig. 5).

Furthermore, instead of an oscillator circuit which is self-excitedly connected to the frequency by the parallel resonance circuit and which determines the frequency by feedback of the resonant circuit, external supply of the parallel resonant circuit (LM, Cp) can be carried out, in which a constant alternating current is fed into the resonant circuit by a further oscillator circuit (e.g. as a square wave voltage). However, the external supply of parallel floating circuits designed as loss measurement sensors is basically state of the art, cf. e.g. the cited DE 32 48 034.

Further basic further developments of the invention are described below: one relates to the use of the preferred relational measurement to establish a correlation relationship between a possibly present envelope curve of the signal occurring at the measuring resonant circuit and the associated derivation of the signal for the Loss determination required voltage values usl, us2, or ditto for the compensation measurement uoff, uon described further below

Preferred further training measures of the invention are described below.

Analysis of the properties for the interference suppression of the preferred method: cf. see also Fig. 49.

The required measurement period Ttot must take into account the settling times (tset) given when adjusting the loss (Rp) of the parallel resonance circuit until after an adjustment of the loss (Rpl or Rp2) the amplitudes correspond to the relations of usl and us2. The settling time is also in tuset for the constant control of the oscillation circuit amplitude included. As will be explained in more detail below, the time grid of Ttot is also used to sample the error of the measurement signal caused by the hull curve of a interference signal overlay in order to correct this error. A distinction is made between an asynchronous and a synchronous mode: In the asynchronous mode, a fixed measurement time grid Ttot is used, in synchronous mode, on the other hand, the measurement time grid is formed by periodically repeating digits of the hull curve of the fault signal (e.g. maximum-minimum values).

For a Storsingal, the possibly existing Hullkurvenpeπodengauer (TH) is much longer than the required measurement period Ttot, for the selection of the measurement time grid for carrying out the measurement steps tl or t2, in which the loss value setting (Rpl, ditto for Rp2) for the subsequent measurement the maximum values (usl, ditto for us2) of the voltage amplitude takes place, no synchronization to the Hullkurvenpeπode the interference radiation required Since such a measurement the amplitude values are sampled in an arbitrary phase position to the Hullkurve of the measurement signal, we refer to this mode of operation (mode) as asynchronous mode.

If, on the other hand, a Hull curve period duration (TH) which is too short in relation to the required measurement time period Ttot affects the required accuracy of the measurement value determination, then the times for the initiation of the measurement steps t1, t2 are synchronized according to stable phase positions of the measurement signal with respect to the podicity of the interference signal envelope curve of the measurement signal The type of measurement is therefore referred to as a synchronous mode. The stable phase positions result, for example, from a minimum or maximum value of the Hull curve in the steady state of the parallel resonant circuit. These values are sampled, for example in such a way that (seen in absolute values) the reversal point of the continuously increasing (or negatively decreasing) amplitude values of the Hull curve is determined by constant comparison with the respective previous value, and upon receipt of the reversal point, the previous value is defined as the maximum or minimum value becomes.

In a preferred further development, an automatic switchover from synchronous and asynchronous mode is provided, with the advantage that the measurement repetition rate of the sensor does not decrease inadmissibly in the event of a particularly low envelope frequency compared to the measurement frequency of any interference radiation (e.g. network interference) (which is the case in synchronous mode) would). A detector signal for switching over the two modes is derived by continuously measuring the times TH between the maximum minimum values of the Hull curve that may be present. If the TH / Ttot ratio falls below a certain value, the system switches to synchronous mode; if this value is exceeded, the system switches back to asynchronous mode

Detailed description of the asynchronous mode:

In the asynchronous mode, the hull curve of the interference signal is detected for the purpose of deriving a correction value for the relationship between the loss value relationship Rpl / Rp2 and the voltage values measured in order to be able to carry out a correlation method. Care is taken that the for derivation the correction-sized scanning of the Hull curve over the period of a stable variable resistor Rp (corresponding to the preset value Rpl or Rp2) is carried out with this Hull curve scanning, it is assumed that within the required measuring period Ttot, which includes all processes for determining a loss value to be measured in each case (cf. . tl: Rpl, usl, ditto t2: Rp2, us2), the respectively measured voltage values follow an interpolation prescription which permits a linear interpolation of the change in values made by the Hull curve within the measuring period Ttot. The query is also implemented as to whether this also applies within the required measuring accuracy of the sensor.

There is a fixed time grid for dead, which is started (triggered) for each switch from synchronous to asynchronous mode and then runs freely and, if necessary, can also be re-synchronized with a synchronous signal derived from the frequency of the Hull curve in such a way that the frequency of the measuring time grid Ttot has a stable ratio to an integer multiple of the measuring frequency of the parallel resonant circuit (LM, Cp) used for loss measurement.

The loss value Rp set by the manipulated variable BD is kept constant over two successive time periods of (each) Ttot, the resistance value Rp being adjusted at the beginning of the first time period Ttot (n). At the end of Tot (n) the associated voltage value us * is measured (* stands for usl, or us2 depending on whether Rpl or Rp2 is selected) and as a comparison value us * (before) = us * in the subsequent second time period Ttot ( n + l) accepted In the second time period Ttot (n + l), the loss value of Rp set in the previous time period Tot (n) remains unchanged. At the end of Ttot (n + l), the current value of us * (usl or us2 depending on whether Rpl or Rp2 is selected) is measured again and with the value us * (n taken from the previous time period Ttot (n) ) to determine the rise of the envelope (by forming a difference), results / us * (before) -us * / = DIFF (usl) or DIFF (us2), depending on whether Rpl or Rp2 is selected.

Since, in accordance with the method according to the invention, two general method steps, designated tl and t2, are provided, and each of these steps contains two successive time segments of the time grid Ttot, four successive time segments of Ttot are thus used to process method steps tl and t2 for the determination of a measured value. With this method, a hull curve that may be interspersed with a disturbance signal can also be completely eliminated for a very large degree of modulation or superimposition when determining the measured value. The rise in the Hull curve can be determined both for the manipulated variable Rpl with usl and for the manipulated variable Rp2 with us2. Thus we get the results DIFF (usl) and DIFF (us2) as difference values of the amplitude difference, which correspond to the hull curve of the interference signal in the measuring time grid Ttot at the measuring times of usl and us2 respectively. In order to make a statement whether over a small signal range (when the Rise with a tangent corresponding to the rise) of this small signal area is sufficiently linear over the duration of the method in accordance with steps tl and t2, the difference values DIFF (usl) and DIFF (us2) obtained in each case become in each case with those from the previous steps DIFF (usl beforehand ) and DIFF (us2 before) in relation to obtain the change (i.e. the second derivative) from the rise in the Hull curve: Vusl = DIFF (usl before) / DIFF (usl) or Vus2 = DIFF (us2 before) / DIFF ( us2). Depending on the requirements, Vusl / Vus2 can also be related, ie the relationship chain can also be formed from DIFF (usl before) / DlFF (us2) or DIFF (us2 before) / DIFF (usl), etc. This relationship chain is used checked whether the values involved in the measurement us / us2 follow a somewhat linear relationship for the change in slope corresponding to the Hull curve profile, if so the results are used, if not the results are not used. Depending on the effort involved, it can also be calculated instead of the linear curve whether the curve corresponds to a sine function, for example.

Thus, the last eight time segments of the time grid Tot with the repetitive measuring steps pairs (tl_vorher and tl), respectively (t2_vorher and t2) are involved in the envelope curve scanning. For an absolute linearity of the tangent (this is a constant increase in the Hull curve over the entire measurement sequence of all eight time grid steps, meaning dead), if there is no change in the increase between the measurement steps pairs (tl__vorher and tl) or (t2_vorher and t2), then this value V (usl) = l or V (us2) = l. Deviating from this (1 + x or 1-x), the result shows whether the error F (F larger or smaller x) is permissible. If the error F is too large with regard to the required accuracy, the value is not taken into account and the output of new measured values is suppressed until the error F is again within the permissible range. However, this depends on the application. For certain applications it also makes sense to use imprecise measured values (usl, us2) by correcting them according to the envelope curve.

It is also planned to set the absolute difference values DIFF (usl) or DIFF (us2) as a kind of squelch in relation to the existing absolute value of the amplitude us * measured as the maximum value: W = DIFF * / us * (* stands for corresponding usl or us2), whether the superimposition or modulation degree of the envelope near the zero crossing still allows usable measurement signal sampling. In the event that W is too small, the amplitude us * is too small compared to the difference formed with this amplitude value DIFF, i.e. the sampled us * is close to the zero crossing of the envelope if the overlap or modulation factor of the scattering is too large. In this case (W too small), the measured values are left out until W again becomes sufficiently large.

If W is sufficiently large and the determined curvature error F (with regard to the comparison of the rise of the tangents in the measuring points ul (previously) with usl, or us2 (previously) with us2) is within the permissible tolerance, then the error value obtained x or the relation factor 1 + x obtained (where x is positive or negative) corrects the amplitude ratio usl / us2 accordingly, since the relation definition requires a horizontal tangent (i.e. an envelope with zero rise, ie no envelope). This is easy if the first embodiment variant 1 is carried out with a predetermined loss value relation (Rpl / Rp2). If, on the other hand, the second embodiment variant 2 with adjustment of the resistance value Rp is used for the purpose of comparison for a defined amplitude ratio (us / l / us2 = constant), then instead of a mathematical correction of a measured amplitude ratio usl / us2, this constant is corrected after the Rp with us2 (with Rp switched on) to be adjusted in each case. For a circuit according to Fig. 4b, this constant corresponds to the resistance ratio of the voltage divider Rva / Rvb, one of the two resistors of the voltage divider being made digitally adjustable and this setting being made by the microcontroller in accordance with the result obtained from V (us2) as a correction variable. The result of V (usl) is not taken into account here, since this amplitude value is measured without adjustment when the variable resistor Rp is switched off in the simplified method using the circuit according to FIG. 4b.

Example: Time grid Ttot (n) Ttot (n + x), triggerable and quartz stabilized

The section shown below begins and ends after the control of the rise of t2 and correction step of us2 in constant repetition, if not switched to the synchronous mode, tl and t2 respectively designate the usl and us2 associated measuring cycles or steps according to the preferred method. See also Fig. **.

Rpl with measurement of usl affects adjustment step 1 (Rp-infinite) Rp2mιt measurement of us2 affects adjustment step 2 (Rp = switched on)

For embodiment variant 1, Rp - fixed resistor which can be switched on and off, usl / us2 measured and measured value 1 / RVM ^' determined from it, mathematically: RM = Rp * (ul / u2-l), the relationship between RM and 1 / RVM ^{' being} over Table, or 1 / RVM ^' directly via table from usl / us2.

For variant 2, Rp = cascade (eg D / A converter network) and voltage divider to determine the constant usl / us2 digitally adjustable, whereby measured value 1 / RVM ^{'is determined} from the table from the manipulated variable BD of Rp.

, Ttot (n-4) was the adjustment step for tl , Ttot (n-3) was control step of the rise of tl, provides DIFF (usl), sign of the rise

, Ttot (n-2) was the matching step for 12

, Ttot (n-1) was control of the increase in t2, provides DIFF (us2), sign of the increase in Ttot (n-3) DIFF (usl) caching;

Ttot (n): adjustment step for tl

(1) Set Rp, e.g. rpl

(2) Adjust Ires (option), tiset over time

(3) At the end of Ttot (n), i.e. time tuset also observed with certainty, e.g. usl

Rpl remains unchanged, usl caching,

Ttot (π + l): Control of the increase of tl from Ttot (n-3) DIFF (usl before) is taken over, from Ttot (nl) DIFF (us2 before) is taken over, ditto sign of the increase, from Ttot (n) is taken over usl (before),

(1) At the end of Ttot (n + l) measure usl again and form the difference DIFF (usl) = current usl minus accepted usl (before),

(2) V (usl) = DIFF (usl before) / DIFF (usl) V (us2, l) = DIFF (us2 before) / DIFF (usl)

Note: rise relation of usl (previous / current)

If V (usl) does not match, then invalid values.

If V (us2, l) does not match, then invalid values. When the sign changes, a gate pulse is generated for the continuous monitoring of TH.

(3) W = DIFF * / Amplitude * Relation from DI FF * to Amplitude us * If W is too small, then invalid values.

DIFF (usl) buffering,

Ttot (n + 2): adjustment step for t2

(1) Set Rp, e.g. Rp2

(2) Adjust Ires (option), tiset over tedding time

(3) At the end of Ttot (n), i.e. tuset also observed with certainty, measurement of e.g. us2,

Rp2 remains unchanged, us2 buffering,

Ttot (n + 3): Control of the rise of t2 and correction step of us2 from Ttot (nl) DIFF (us2 before) is taken over, Ttot (n + l) DIFF (usl before) is taken over, ditto sign of the rise Ttot (n + 2) is taken over us2 (before),

(1) At the end of Ttot (n + 3) measure us2 again and form the difference DIFF (us2) = current us2 minus us2 (previous),

(2) V (us2) = DIFF (us2 before) / DIFF (us2) V (usl, 2) = DIFF (usl before) / DIFF (us2)

Note: Rise relation of us2 (previous / current) If V (us2) does not correspond, then invalid values. If V (usl, 2) does not correspond, then invalid values, when changing sign, generating a gate pulse for the constant monitoring of TH.

(3) W = DIFF * / Amplιtude * Relation from DIFF * to amplitude us * If W is too small, then invalid values.

DIFF (us2) buffering,

(4) If there are no invalid values, then derive the correlation from the rise curve V (usl), V (us2, l), V (us2), V (usl, 2) (arithmetically and / or using a table).

For variant 1, the correlation result is a new us2,

For variant 2, the correlation result is a new us2 / us2 = constant.

Note: This scheme primarily concerns the dynamic value correction of us2, depending on the respective increase in the hull curve, or for variant 2 the dynamic value correction of the constant us2 / usl. Furthermore, the query whether such a value correction depending on the rise of the envelope in relation to the measurement amphtude (usl, us2) of the higher frequency is still permissible, if not, the values are rejected and the mode switches to the synchronous mode. An example of rejected values is outlined in Fig. ** b, e.g. if in the time period Ttot (n-l) the envelope has already passed its turning point (from increasing to decreasing), V (*) is therefore negative. Ditto if there is too much curvature of the hull curve. The change of the sign from V (*), in each case from plus to minus, ditto from minus to plus, indicates the turning points of the Hull curve and can therefore be used immediately for the generation of the gate signal (gate signal) for measuring the time TH for the detection of the possibly to be undertaken automatic switch to synchronous mode.

Detailed description of the synchronous mode:

In synchronous mode, the inflection points of the Hull curve (maximum or minimum values) are sampled over the duration of the loss value setting of the preferred variable resistor Rp and used as a trigger signal (measurement trigger signal) for triggering the measurement of usl or us2 within the measuring steps tl and t2 The constant time interval TH between these sampling points of the envelope is constantly monitored. It is evident that the measurement sequence was impaired if the hull curve frequency was too low, which is why a switch back to the asynchronous mode takes place immediately when the ratio TH / Ttot again exceeds the predetermined threshold value

Example: It was switched from asynchronous mode to synchronous mode, whereby one of the two loss values Rpl or Rp2 is currently selected.

For the drawing of the measuring process, the maximum (u ^Λ ) and minimum values (u ^A ) of the voltage amplitude us at the parallel oscillation circuit are continuously sampled until u ^{Λ is} detected.This point in time triggers the measuring process from u * (usl or us2 depending on whether Rpl or Rp2 is currently selected), then Rp is switched to the respective other value (Rpl or Rp2 according to the method) or set in a corresponding step, then the generation of the measurement trigger signal is blocked for the duration of Ttot. After Ttot has elapsed, the generation of the measurement trigger signal is released again until the next measurement trigger of us * (usl or us2 depending on whether Rpl or Rp2 is currently selected) with subsequent adjustment of the variable resistor Rp, blocking the measurement trigger until Ttot expires, repeated measurement of us * if u ^{Λ of} the envelope is recognized after Ttot has expired ... etc. The time interval of the U ^Λ detected Meßauslosezeitpunkte TH for the measurement is constantly measured when TH / T tot is too large, then the downshift is performed in the asynchronous mode.

Another application for further training relates to measures for the evaporation of the total loss in order to increase the sensitivity and / or the measuring accuracy to increase relatively high resistance losses and / or to reduce the influence of the temperature response. This variant of a vaporized sensor will be explained in more detail below:

Variant of damped sensor, basics: The following preferred embodiment of the sensor is based on the further technical task of additionally steaming a loss sensor with a precisely defined value, so to speak for the total loss 1 / RVM + 1 / RVL (Fig. 1) a precise negative loss value (- 1 / RVM_NEG) to add. The principle can be traced back to a sensor according to claim 1, using further features of a sensor functioning according to the principle of the cited DE4240739C2 and the following further training measures: The state of the art for this further training according to the invention is supplementary to the arguments already mentioned at the beginning of the description indicated that for oscillator circuits with parallel resonant circuits, evaporation through a negative resistance characteristic, as e.g. Have tunnel diodes, is known, but these circuits are completely inadequate for the purpose intended here. The circuits customary in the prior art use the property that the limit range of the part of a tunnel diode characteristic used for the differential negative conductance (- gT) (or similar characteristic of another component with a negative conductance) becomes zero at the turning points of the characteristic, whereby the from the parallel connection of the series resistance rs of the oscillation circuit coil transformed into a parallel conductance and the negative conductance (- gT) the sum loss becomes positive and so the amplitude limitation of the oscillator oscillation is adjusted according to the modulation of the tunnel diode characteristic. In the present development of the sensor, however, is the setting or determination a precisely defined value for the negative loss is intended, without the operating point for the control of the differential negative conductance - gT having to be used for an amplitude limitation in order to produce stable conditions. The most accurate and drift-free setting of the negative conductance - gT, or alternatively the exact measurement of its set value, is the task for the training variant for evaporation of the total loss of the sensor method according to the invention in order to convert the total loss 1 / RVM + 1 / RVL + (-1 / RVM .EG), or [1 / RVM + 1 / RVL + (- gT)] to determine the measured loss value 1 / RVM. It is also possible to set the negative conductance - gT in any value via a control signal. The solution to this problem is given in claim 3, with further training options specified in the corresponding subclaims, and is explained in detail in particular in the following part of the description of FIG. 8 in the chapter "The individual figures". Associated circuits are shown in FIG. 9 to FIG The preferred method for the exact addition of a negative loss value (as a component of 1 / RVM and 1 / RVL or Rp, cf. FIGS. 1 and 8) has in common with the method according to claim 1 in its characterizing part that the measurement or setting of the negative loss value is likewise carried out over several steps in which the variation or switching of the loss (cf. Rpl, Rp2 as part of Rp in FIG. 1 with Fιg.2b, Fιg.2c and further - gT and GTCOMP in Fιg.8) during the constant connection of the loss to be measured (1 / RVM ^' ) takes place directly at the measuring point (K) without the corresponding switch for switching off de s measured loss (1 / RVM ^' ) were required; and the determination of a respective measured value from a relation definition of the loss value change made in relation to the amplitude values (us *) corresponding to the switched losses, which are measured in the corresponding measurement steps, is obtained as follows in detail with respect to FIGS. 8 to 10b is explained, the method uses two constantly repeating measuring cycles, one measuring cycle for the setting (or the exact comparison) of the negative conductance - gT, and one with which the preferred method (according to Ausfunrungsvaπantel or Ausführungsvarιante2) is used. For the exact adjustment of - gT, a parallel switched compensation variable GTCOMP is provided, which can also be implemented as part of the loss adjustable with variable BD (1 / RVL) or Rp. Thus, the total loss 1 / RVM ^' + 1 / RVL + (- gT) is measured on the resonant circuit during the actual loss measurement in steps t1 and t2, or the sum loss 1 / RVM' + GTCOMP during the comparison to determine - gT + (- gT) measured. The proportions of - gT or GTCOMP relevant for the compensation of - gT can be set to zero in a relevant measuring step (toff), or the negative conductance - gT and the compensation conductance GTCOMP can be switched off for simple execution. This connection (or the zeroing of the conductance components involved in the balancing) is carried out in a first step (toff) within the balancing cycle of - gT and the voltage uoff occurring at the resonant circuit is measured. In a subsequent step (tone), both conductance values - gT and GTCOMP are switched on and the voltage uon occurring at the resonant circuit continues to be measured. In this state, the - gT is adjusted until uon = usoff thus / - gT / = / GTCOMP / (where // stands for absolute value) Conversely, by adjusting GTCOMP, you can also read -gT. Details and optional variants are described in detail in the later part of the description, in the chapter explaining the individual figures, in the text relating to FIG. 8 (and the subsequent figures). When 1 / RVM was specified, 1 / RVM ^'was specified. 1 / RVM 'contains, in addition to the loss to be measured, the intrinsic loss rs of the measuring coil LM (or the measuring circuit LM, Cp), the actual loss 1 / RVM via, when determining the measured loss in the subsequent measuring cycle according to Vaπantel or Varιante2 Table which contains (correct) the self-loss rs of the measuring coil determined from 1 / RVM ^'

It is evident that because of uon = uoff for a deviation from / - gT / = / GTCOMP / the measurement is independent of the interference voltage if the proportions of the interference voltage in the two measuring steps ton and toff are the same, or this applies to an existing one Hull curve of interference signal interference only if the measurement is synchronized after the period of the Hull curve or if the previously described correlation method of the preferred Hull curve scanning is used. The correlation method for measuring the voltage values uoff and uon in the measuring steps ton and toff can be used in exactly the same way as for measuring the voltage values usl and us2 in the measuring steps tl and t2. Alternatives: The training method for the exact addition of a negative loss can, however, also be used independently of the method of a measurement signal independent of the interference signal, for example if the problem of the interference signal immunity is not present; can therefore be seen as an immediate improvement of DE 42 40 739 C2. A precise distinction from the state of the art results from the following argumentation: The method is carried out by means of two successive measurement phases: an adjustment phase and the actual measurement phase. At first glance, this type of implementation would correspond to the principle of DE 3248034 AI already cited in the introductory part of the description of the prior art, but with the essential difference already explained that the actual measured variable (in our case 1 / RVM ) always remains switched on to the sensor. The method is thus more closely oriented to the method of DE 4240 739 C2 cited, but with the essential extension that the adjustment phase takes place in several measurement steps connected by the preferred relationship rule. Further alternatives for the use of a negative resistance in the present method, as a replacement for a tunnel diode , were corresponding operational amplifier circuits, but with the disadvantage of their low cut-off frequency, such as so-called NICs (negative impedance converters); A distinction is made between INICs (reversal of current) and UNICs (reversal of voltage). An INIC connected in parallel with the resonant circuit directly or via transformer coupling can thus directly replace the tunnel diode circuit for low frequencies. In contrast, a UNIC would correspond to a negative resistance in series with the coil

Preview of the described application examples: Adding (evaporating) a negative loss to reduce the sensor's own loss brings a number of advantages: a) it can be measured at a particularly low measuring frequency with high good and smallest measuring performance, with the advantage that due to the low measuring frequency the skin effect in the inductive coupling of the loss resistance of a measuring part (K) is avoided, thus the sensitivity at a higher measuring frequency comparable good, especially with measuring parts of higher specific resistance increases significantly b) for the coil wire of the sensor coil can instead of a material, although a particularly low-resistance specific resistance, but has a very unfavorable temperature coefficient, an alloy can be used, which has a much higher specific resistance but has a much better one Has temperature coefficients (a compensation alloy). Since the negative loss added by the method according to the invention is particularly precise and its stability is coupled by the preferred measuring method to a standardized calibration resistor (or conductance GTCOMP), the temperature dependence of the measuring coil can be significantly improved in this way. This application is discussed in more detail below in a numerical example for an alloy in which the alloy manganin is used as coil wire material. Furthermore, with such compensation of the coil sense resistance, coil wire materials that withstand high temperatures but have a high specific resistance can also be used as the measuring coil (air coil LM). c) Loss measurements can be carried out on particularly high-resistance resistors or media, in particular on liquids and gases. Eg purity measurement of distilled water via conductivity. Or also layer thickness measurement of particularly thin vapor deposition layers, or also in paper production, or also in the manufacture of electrical radiation shielding substances, etc. Furthermore, it is preferred that the sensor covers a wide variety of applications: eg measurement of temperatures, pressure and conductivity. Furthermore, measurement to identify the type of gas as a gas detector (or gas molecules), depending on the skin effect. In this measurement, the loss 1 / RVM caused by the gas is measured with different frequencies and the same inherent loss of the sensor. The different losses that occur for different gases are decoded accordingly for the generation of a corresponding signal. Ditto the evaporated sensor applications for monitoring on gas lasers, etc. Another application would be, for example, the self-ignition timing of a direct-injection high-performance gasoline engine via the increase in conductivity of the compressed gas with the sensor coil measuring in the displacement to recognize in good time and before an unwanted self-ignition occurs to open an electrically controlled emergency valve and to reduce the boost pressure the next time it is compressed (to be regulated via the sensor).

However, the high-resistance loss measurement also allows distance measurements (displacement sensors, angle sensors, variable area flow meters, etc.) as the loss-generating core material (K, Fig.l) to use relatively high-resistance materials with temperature-compensated resistivity, such as occurs with alloys, e.g. For example, for alloys with a particularly low temperature coefficient (TKR) of the electrical part, which is made, for example, from a temperature-compensated alloy (e.g. manganin with a TKR of l * 10 (exp-5) / ° C. Manganin is an alloy made of 86% Cu, 12% Mn, and 2% nickel). The material manganine is also used for the further training execution for the coil wire of the measuring coil. Another interesting application is with electrically only slightly conductive liquids, e.g. water trapped in closed cape to build an inclinometer. With a large number of such inclinometers, which are networked to a computer, seismographic measurements can be carried out very well, in particular early warning systems for mountain movements above or below day, and for warning of murmurings. d) loss measurements with extremely low measuring power can be realized at the measuring point, e.g. for the detection of letter bombs, etc. The advantage: measuring power and measuring frequency can be kept so low that the electronic circuit for the bomb drawing can no longer recognize this, e.g. if a measuring frequency in the vicinity of the network hum is used e) a large number of other applications are listed in the introductory part of the description and described from FIG. 8 on the figures.

Discussion of errors to determine the temperature response for the compensated series resistance of the measuring coil: Through the drift free exact setting or determination of the negative conductance -gT connected to the parallel oscillation circuit (LM, Cp) not only completely new fields of application are opened up for the loss measuring sensor, it can also immediate temperature dependency of the ohmic resistance rs of the measuring column (LM) can be significantly reduced. The negative transformed into the measuring coil (LM) Conductivity -gT as negative series resistance - RtsT in series with coil loss resistance rs and thus results in the reduced series resistance Rstot of the measuring coil (LM). Rstot = rs + (-RtsT) If, for example, the direct ohmic series resistance (rs) of the measuring coil (LM) is to be reduced to 10% (gives 10 times the good), ie Rstot = 0.1 * rs, then Rstot = rs + ( -RtsT) or Rstot = rs * (1 - 0.9). A drift of 10% of RtsT therefore causes 0.1- (l-0.99) /0.1 = 1-0.01 / 0.1 = 0.9 in the worst case, which is 90% error drift of Rstot with a reduction factor for the coil sense resistance (Fv = rs / Rstot = 10) for the good improvement of 10, hereinafter referred to as the coil improvement factor. A coil improvement factor Fv of 10, for example, enables the measurement frequency to be reduced by a factor of 10 or a corresponding reduction in the coil diameter of the measurement coil designed as an air coil, while at the same time increasing the number of windings (a correspondingly thinner wire) by a value that is 10 times ohmic Series resistance corresponds to the larger comparison coil (ie reduction in size of the sensor component) If you were to strive for an improvement factor of Fv = 100, then there would already be 1% drift of RtsT, i.e. Rstot = 0.01 * Rs, or Rstot = Rs * (1 - 0.99), im worst case error of 0.01- (1- 0.9999) /0.01 = 99%. If, for example, a maximum drift of 0.025% (corresponds to approximately 12 bit resolution) is assumed for the negative conductance -gT or for (- RtsT), the maximum deviation for Fv = 10 would be 0.1- (1- 0.900225) /0.1 = 0.2%. or for Fv = 100 the maximum deviation 0.01- (l-0.9902475) /0.01 = 2.5% The calculation example shows how important it is - to determine gT exactly in order to enable the reduction of the coil sense resistance with a negative resistance

Error discussion for the improvement of the temperature response of the measuring coil (LM) and possibly the material used for the scanning (K):

In this variant, the temperature coefficient of the coil is to be improved accordingly by using an alloy (e.g. manganin).

The alloy manganine has 24 times the resistance value (with the same wire cross-section) compared to copper, but it has a 393 times better temperature coefficient (TKR). This means that the temperature dependence on copper can be significantly improved by a factor of 393/24 = 16 if the negative resistance is correctly dimensioned. The negative resistance, or conductance -gT, of the tunnel diode (DT) can be adapted transformer-wise so that a suitable ohmic series resistance for Rstot = Rs + (- RtsT) can be set for each Rs, e.g. with Fv = rs / Rstot = 24, in order to obtain the same good for a manganese wire coil (air coil) as for a copper wire coil (air coil) that is comparable in size and number of turns, but with a temperature coefficient that is 16 times better for the total series loss resistance Rstot = Rs + (- RtsT)

The preferred precision setting of the negative conductance of -gT used for evaporation of the series resistance rs enables the temperature response of the measuring coil (LM) to be improved compared to a copper coil by a factor which corresponds to the ratio of better temperature coefficient to increased resistance of the selected material the consideration shown is the term alloy to understand beyond the melting of different metals, since we only need the properties of the specific resistance with its temperature dependence and a nomogenic heat transfer of the material used as coil wire. It is therefore sufficient to produce the coil wire from a type of "virtual alloy", preferably from two wires (which can also be bare) wound in parallel on a corresponding coil body (eg ceramic) and made of different materials, one positive and the other has a negative temperature coefficient of specific resistance, the choice of the cross-sections of the wires among one another being matched to the resistance ratio of the two materials to the winding length of the coil such that the temperature coefficient of the specific resistance formed by the pair of wires is canceled Wires wound in parallel are then connected in parallel at the coil ends. For dimensioning, it should be noted that in this case we connect the conductance values of the specific resistances in parallel (see also text for Fig. 33 for an example of a printed conductance on the coil). To create a good heat transfer between the materials, it can also useful to twist bare wires. Thus, for example, we get a small measuring coil (LM) wound on a ceramic coil body, which we can use on the inside (similar to a spark plug) in an engine compartment, either just to monitor the compressed gas, or in conjunction with a small load cell with which we can Being able to measure compression pressure directly in the high temperature range; For example, the switching time of electronically controlled valves of an explosion engine can also be electronically adjusted, since the pressure sensor provides good feedback on the actual switching times of the valves to the valve control.

The parallel resonance capacitance (Cp) is then connected via a corresponding contact bushing on the outside thermally insulated via cable, ie the secondary side of a transformer connected in parallel with the resonant circuit, which couples in the negative conductance -gT of the tunnel diode. Just as we compensate for the temperature response of the measuring coil with a corresponding "alloy", this is also possible for the temperature response of a correspondingly sampled material K (e.g. for scales, protractors, etc.). Either we use a direct alloy, such as manganin, or we take very thin, layered laminated sheets with opposite temperature coefficients of their specific conductance to compensate for the temperature change.Alternatively or in addition, we can use the temperature compensation described from Fig. 8 by means of a further measuring coil (LT with CT) a selected material the improvement of the TKR (relative to copper) equal to the factor of increasing the resistance (increasing the specific resistance relative to copper), then there would be no relative improvement, since the resistance for both materials would change to the same extent depending on the temperature (we nn same number of turns, dimensions and same wire cross section of the coils). In this consideration, it is assumed that the negative resistance or conductance has practically no temperature deviation which has a significant influence on the final accuracy, which can actually be achieved by the present invention; by adjusting or precisely determining -gT (or -RtsT) with a resolution of 16 bits and more. the resistance or conductance used for the adjustment or compensation measurement of -gT (GTCOMP see FIG. 8) also consist of a series connection or parallel connection of a fixed resistor and a digitally adjustable resistor with which only the drift is compensated for in each case. In addition or as an alternative to the measures described, the temperature coefficient of the selected material for the coil wire can also be compensated for by wiring with a resistor with negative temperature coefficients (NTC), whereby a high-resistance NTC resistor can also be connected in parallel with the resonant circuit (ditto a low-resistance the coil in series). In addition to the possibility of being able to design the ohmic measuring coil resistance for the purpose of temperature compensation with a higher resistance, the compensation of the negative resistance also enables a further series resistor to be connected in series directly to the measuring coil, via which the zero crossing of the coil current for the purpose of determining the voltage maximum at the resonant circuit (LM, Cp ) is tapped by means of an operational amplifier or comparator, or if necessary this tap is used for the constant regulation of the alternating current amphtude.

Further measures for the most accurate setting or determination of the negative resistance (see also text for Fig. 8):

Since different amplitudes of the measurement signal on the parallel resonant circuit can already make up a drift fluctuation of the negative resistance, which is due to the failure of the characteristic curve of the negative resistance, it makes sense to measure the deviation of the negative resistance separately at a time when the signal amphtude on the parallel resonant circuit already has the value as in the later measurement of the actual loss (1 / RVM). This means that the value for which the amplitude uoff = uon (cf. above all the text relating to FIG. 8 and the examples in FIG. 8 below) on the resonant circuit has been compared to determine -gT, is also used below for the measurement of ul, conversely, the value of ul can subsequently also be used for a comparison of uoff = uon, and this comparison is carried out again after the measurement of u2, see above all text for FIG. 8, in the chapter in the chapter “The individual figures show ''In addition, another possibility for an improvement in accuracy should be de' Determination of -gT can be addressed. The table shows the dependency of the conductance on the signal modulation (us * in the required ranges of usl and us2) for a given differential conductance -gT as the operating point, the comparison or determination of -gT to voltage values other than usl or us2, then the deviation of the differential resistance can be corrected using the table: either after a measurement of usl, us2 (in steps tl, t2) or before a measurement of usl. or us2 for the respective setting of -gT. If necessary, this table can also include a temperature dependency of the tunnel diode characteristic when measuring the tunnel diode temperature, or the tunnel diode is cast in a thermostat housing. The setting of -gT takes place either via the voltage-current characteristic curve of the tunnel diode or via a total master value setting 1 / Rp + (-gT) directly digitally via the digitally adjustable master value network 1 / Rp (e.g. a corresponding D / A converter). GTCOMP can also be realized by a D / A converter master value network (with binary gradation of the switched master values). Alternatively, a binary adjustable resistor network can be used instead of the master value network. When measuring the total loss, e.g. according to variant 2, Rp2 is compared according to a fixed voltage ratio usl / us2 (whereby usl measured eg at Rp2 = infinitely) and with the value of Rp2 obtained or its manipulated variable a table for reading out the measured value Hiebei has already taken the negative part of 1 / RVL = [1 / Rp + (-gT) + 1 / RS] into account for the measurement of 1 / RVM. 1 / RS ^" corresponds to the series resistance rs of the measuring coil transformed via the resonant circuit for parallel loss, is stably regulated as a constant. In the case of relative measurements, where -gT is provided as an adjustment variable, on the other hand, -gT is not taken into account in the value table, since not the absolute value but only Other values are to be measured, see also text for Fig. 8 In a further alternative to the exact setting or determination of the negative resistance -gT ^' occurring at certain measuring voltages usl, us2, a separate resonant circuit is for the deviation from - gT ( LgT, CgT,) is provided, with which the value of -gT is set or determined simultaneously immediately before the actual loss at the resonant circuit (LM, Cp), since the effect of frequency for the differential resistance -gT in a tunnel diode at the same operating point is insignificant in a wide range, the resonant circuit intended for the determination of -gT (LgT, CgT) can be set with h Be operated as the resonant circuit for the measurement of the loss (LM, Cp) herer frequency. For this purpose, the tunnel diode with a changeover switch (HS_gT / LM) can either be connected to the resonant circuit (LgT, CgT) for the determination of -gT or to the resonant circuit (LM, Cp) for measuring the actual loss (if this resonant circuit is constant) connected loss 1 / RVM) can be connected. This switchable switch is also used to switch off the conductance -gT for the measurement of uoff (for the comparison). The adjustment conductance GTCOMP is switched on for the resonant circuit (LgT, CgT) for the determination of -gT. If the adjustment component is switched off (see text for Fig. 8) and the tunnel diode -gT is switched off, the resonant circuit voltage ugT (from LgT, CgT) of the hull curve of the resonant circuit voltage us *, which occurs on the resonant circuit (LM, Cp) intended for loss measurement, is readjusted , This readjustment can be carried out, for example, directly by varying the matching resistor GTCOMP. For a particularly precise setting of -gT, this readjustment on the resonant circuit (LgT.CgT) for the determination of -gT is a voltage which is increased or reduced by a proportion compared to the resonant circuit voltage (us *) of the loss measurement resonant circuit (LM, Cp) set so that the (hull curve of) the resonant circuit voltage at the resonant circuit LgT.CgT each has a value corresponding to the respective rise in the resonant circuit voltage at a lagging point in time with the rising or falling hull curve of the resonant circuit voltage at the loss measuring resonant circuit (LM, Cp) is to be expected in each case. As with the sampling of the measured values usl, us2 for the determination of the loss, we also use a correlation method for the setting or determination of -gT. The corresponding lagging spread is based on the maximum time required to determine the negative conductance -gT according to a value specified by GTCOMP or to determine the difference -gT = GTCOMP - 1 / RVLo, see text for Fig. 8, where 1 / RVLo is the loss that the adjustable master value GTCOMP had when adjusting ugT (at LgT, CgT) until the adjustment was switched over to determine -gT. Instead of switching GTCOMP on and off, this occurs Fig. 8 explained change in value After the adjustment of -gT, the respectively set negative master value -gT is switched on the loss measurement resonant circuit (LM, Cp) to measure usl (in tl) according to the preferred method. If it is found that the negative conductance -gT has been adjusted to a voltage value deviating from usl, then the correction value can be read out via a corresponding correction table in which the differential resistance as a function of the small signal modulation is stored in the operating point -gT, and if the application requires it, the correction component of the negative resistance is taken into account accordingly via the adjustment cascade Rp (1 / RVL). The same applies to the adjustment of -gT before the immediate measurement of us2. If the measurement procedure for the loss determination is carried out according to variant 2, then due to the precisely defined ratio of usl / us2 (as a measurement constant), the measurement of usl can be carried out in a fairly precise range using a cascade adjustment, ditto us2, so only a few Storage spaces are required for storing a table that takes into account the small signal modulation of the negative resistance

Additions to the transputer application variant: As explained below for Fig.lOb (sheet 25), the preferred sensor is ideally suited for transputer applications due to its extremely low need for measuring power, in which the supply voltage is supplied via a transmitted RF signal rather than via cables whose frequency and required radiation power are designed for the respective application. A distinction can be made between shielded (closed) applications and unshielded (open) transputer sensor applications. Another particularly interesting application is to be classified, in which the supply voltage is supplied via a transformer-coupled conductor loop (or winding) of the connection as a continuous wire The cable is carried out by an HF current and inductively transmits the supply voltage to the HF receiving circuit for the voltage supply of the transputer sensor. We would like to refer to this type of supply as induction cable powered transputer sensor applications. In addition to the possibility to allow the voltage-supplied sensors to communicate with each other via radio, there is also the possibility of the data transmission described using the preferred loss modulation and measurement principle (using the sensor method according to the invention). via the HF cable provided for the voltage supply. We want to call this type of supply using the same induction cable with a combined data combination an application. In this case, the HF is fed into the cable with a very high resistance, for example via a stray transformer-controlled constant alternating current, with several such feed points along the line connection, with the negative evaporation conductance values already discussed, for the exact setting of a defined loss value of the line The ohmic loss given along the induction cable for the RF receiving circuits of the transputer circuits is thus kept stable on the one hand, and is varied by the transmission method on the other hand, the dynamic relative measurement described below for Fig. 8 being used to stabilize the operating point When designing the RF receiving circuit of the transputer circuit, care is taken to ensure that the change in loss resistance given by fluctuation in power consumption does not affect the induction circuit abel has a retroactive effect. Hiebei should be noted that the power for the evaporation of the induction cable (regarding the setting of the working point) is essentially not provided by the tunnel diodes connected in the transputer sensor sensors (since there is no perpetum mobile), but by the induction cable at regular intervals Ohmic or inductively connected negative resistors for line evaporation To suppress through

The following circuit measures are preferred: As explained below in relation to Fig.lOb, the transverse control carried out on the RF reception circuit of the transputer circuit is carried out in such a way that the rectified envelope curve amplitude of the RF reception circuit remains constant, that is with a constant hull curve of the input amplitude, the load from the transverse control is kept fairly constant. Slight fluctuations lie in the low-pass range in accordance with the filter capacitance switched on in the rectification after the rectifying diode. If the data loss modulation carried out on the par end is not to have any particular effect on the control, ie be prevented that the data transmission is also regulated, then a modulation method must be used for the data transmission that operates with a reasonably stable duty cycle, for example a modulo-2 method, which has a low variation ratio of the duty cycle. The change transitions of the data signal can be defined in a lower ratio instead of the usual pulse duration variations of 1: 1 and 2: 1, with a clock frequency accordingly included in the data signal.This type of modulation method is known: the exclusion of data and clock is the modulo-2 data signal is generated, or the data are decoded from the resulting different pulse lengths and the associated clock signal is decoded from the exclusive or / nor of this data signal and the modulo-2 signal. If this clock signal is significantly higher than the filtering frequency at the filter capacitor of the supply voltage of the HF rectifier, then the regulation of the DC voltage described for Fig.lOb has no effect on the loss modulation of the data signal. This is achieved by switching resistance values directly at the HF receiving resonant circuit Corresponding load variation carried out (good switching) and measured on the receiver side by an amp sampling performed on the HF oscillating circuit (cf.usl, us2) .For the coupling of the supply voltage and the carrier frequency for loss modulation of the data signal, different frequencies can also be used, as shown in Fig .lOb already explained, the transputer circuits with their RF receiving circuits can also be directly connected (eg against chassis ground), the cable being directly contacted or via capacitive coupling the supply and the data connection ng. Depending on the weather, a shielded cable can also be used, in which the shielding is removed at the coupling points.For the preferred method, because of the good interference signal suppression and the high-resistance cable routing, it is sufficient if the shielding is a metallic coating (e.g. by vapor deposition) of the plastic insulation is carried out, for example also in several layers with a separate high-voltage coating for the bite protection. The loss measurement can also be used to trigger a high-voltage pulse for the bite protection in the event of a spontaneous loss change in the insulation.

Below are some examples of shielded (closed) applications and unshielded (open) applications, furthermore for transputer sensor applications fed by induction cable and transputer sensors communicating via induction cable. Examples of shielded applications: Use of the transputer sensor for loss measurement of rotating parts enclosed in a housing, for example for a torque sensor according to Fig. 19, the sensor on a rotating part and the transmitter for supplying the supply voltage and communication to the sensor, is housed on the inside of the stationary attached housing of the torque sensor. A similar application is the distance measurement of the clutch disc distance shown in relation to Fig. 20 in relation to the actuation path of the clutch pedal, etc. Another shielded application e.g. is to use sensor coils for scanning the tooth position of gearboxes in the housing and to feed them within the housing by means of a central HF transmitter. Or inside the bonnet are a variety of sensors, such as pressure gauges, or level gauges for measuring the level of the brake fluid, or sensors for sensing accelerator pedal positions, clutch pedal, steering lock, etc., which are fed by a central HF transmitter. Or on the dashboard there are a large number of switches, the switch positions of which are coded as loss (rotary switches, toggle switches, slide switches, etc.), the switches being fed by a central HF transmitter (control center) housed on the dashboard. The body is an ideal shield against interference to maintain radio data traffic between the sensors and the control center, or other central transmission units can be networked accordingly by cabling. Examples for open applications: Monitoring the strength of rims mounted on the wheel plate in accordance with Fig. 22 also measuring tie rods, determining the position of parts on which the sensor is mounted in relation to loss-controlled limit marks.

In the case of open applications, the great advantage is shown against the measurement principle of the sensor, which is insensitive to interference. A variant is also provided for the coupling of the voltage supply and the data exchange, which is illustrated in FIG The sensor has a holder (opening or cylinder, etc.) in its housing, which is in the inductive area of the RF receiver coil of the transducer circuit used in the sensor, and around this holder (or through a hole, or cylinder body, etc.) a conductor loop is drawn or wound, if necessary the loop being wound once or several times around the inductive area of the RF receiving coil of the transputer circuit. This method means that the contacting problem for the wiring of the sensors, which is known in the automotive field due to corrosion damage, is no longer present, the conductor loop or the line which connects all sensors in series with one another is supplied with high impedance by an HF generator; the reference potential is then the chassis of the vehicle. Data communication can also take place via the conductor loop. In addition to standardized transmission methods, the method of data transmission by means of loss variation and loss measurement (by the sensor) described for FIG. 37 (sheet 15) can also be used for interference-proof transmission. The transputer sensor circuit then has at least two loss measurement sensors, one for the actual loss measurement (1 / RVM) and one for the reception of the data. A preferred embodiment is to use a high voltage for the high-impedance HF generator feeding into the conductor loop, which via the Isolation capacity discourages biting animals (e.g. martens). Dabet can recognize the loss change occurring when trying to bite a line from a loss measurement connected directly to the line connection and trigger a spontaneous increase in the high voltage. Further examples of open applications relate to the railway sector for the exemplary embodiments described for monitoring railway tracks. The special case is provided that the supply power is supplied by direct HF radiation, but not the communication of the individual transputer sensors with the control center. The supply line is emitted, for example, directly via the high-voltage contact wire, on which a corresponding RF signal for supplying voltage to the loss measurement sensors arranged along the track is superimposed. An alternative to this would be to route the voltage supply to the sensors via existing telegraph wire connections running along the track, or the variant of inductive coupling by means of a continuous line already described for the automotive sector when the sensor is wound around a conductor loop. The sensors communicate with the control center in the following way: Each sensor has a mini transmitter and a mint receiver for communication with the closest transputer sensors. The sensors are sent one after the other according to the "ping" principle (ie knocking on with an initiation word). Starting from a 2TB central unit at the beginning of the chain, the first sensor (SO, which corresponds to the central data protocol) receives one with a "Ping" signal provided with the reception address is sent until it receives the receipt (ACK) from the receiving sensor (SI). If this is not the case within a certain period of time (TIME-OUT), then it is assumed that there is an error. The error handling is discussed below, a convenient method for entering the receive address assignment of the sensors is explained below for Fig. 23. For the ACK signal sent back by the receiving sensor, a different transmission frequency can also be provided than for the data transmission and the "ping" signal, so that the sending sensor is constantly ready to receive the ACK signal while it is still transmitting the "ping" signal. After receiving the ACK signal, the sending sensor begins to send its data. Which data this is, whether your own or previously received from a neighboring sensor in the chain, depends on the respective status (STATUS) of the protocol, with an address being added to each data packet sent, which indicates which sensor for a corresponding data packet as Data source can be viewed, since all the sensors in the chain only pass this data packet through. The protocol is designed so that all the sensors (SO,

SI, S2, S3, S4 Sn Se) one after the other, send (pass through) the data packet received from a sensor arranged one position earlier to the one arranged later, until the last sensor (Se) in the chain transmits this data packet for the direct forwarding of a control center ( ZTE at the end of the chain). The central units (ZTB and ZTE) provided at the beginning of the chain and at the end of the chain are networked via a corresponding external data connection (e.g. radio, fiber optic cable, etc.). In this way, protocol data is passed between the central units by forwarding them transfer. This protocol data contains information about the self-test statement of the sensors in the transmission chain. Because the endpoints ZTB and ZTE are also directly networked the transmission chain can be checked by simply comparing the protocol data. In order to limit the protocol data to a minimum, each sensor independently checks whether the sender address given for a received "ping" signal (from the sending sensor) corresponds to the recipient address of the receiving sensor has the minimum step size (for example of 1.) If so, then the "ping" signal has been emitted by a sensor directly adjacent to the receiving sensor within the chain, and this sensor is therefore ready for operation. The step size of the sender address to the addressed recipient address of the receiving sensor however higher, then a number of sensors corresponding to the step size has failed. If such a case is recognized by the sensor emitting the "ping" signal, then it logs the number of failed sensors in the passed-on data protocol, which it sends after receiving the ACK signal to the sensor previously addressed with the "ping" signal. In order to be able to carry out this method of checking for errors and, if possible, to be able to directly bypass one or more sensors which fail to pass on data, if the ACK acknowledgment expected for a sent "ping" signal fails, the "ping" signal is repeatedly sent out by the sensor concerned, the received address given is increased by one step to the second closest sensor that is still in the receiving range (or, depending on the current transmission, may also be decreased). This is carried out by the sensor repeatedly emitting the "ping" signal as long as it does not receive an ACK acknowledgment for the emitted "ping" signal and the receiving addresses provided for the "ping" signal are within the range of the emitted "ping" signal (corresponding to the current transmission) correspond. If this is no longer the case (the limits of the range of the sending sensor, based on its local receiving address, being stored by the receiving addresses corresponding to the limits), then the sensor which repeatedly transmits the “ping” signal changes the transmission and begins, starting from it local reception address, to repeat the attempt to respond to the other transmission value (for the reception addresses corresponding to the sensors closest to the location). It is essential that the "ping" signal not only encodes the reception addresses, but also the transmission transmission, with the characteristic state of a relevant one bits br. The characteristic bit bR informs the sensor receiving a "Ping" signal in which transmission channel it has to select the new reception address which it has to pass on when it subsequently sends its "Ping" signal, with a reception address for each possible transmission night , which designates the respectively closest sensor locally, is provided. For a straight line, therefore, two (one pointing forward and one pointing back) receiving address (for transmitting a transmitted "ping" signal) are programmed in each sensor. If a star branch, for example a switch, is provided, then three such neighboring receiving addresses are provided encoded for a sensor arranged on a star, four at an intersection, etc., so that in the event of a fault, branching is possible in all local directions in which the sensors are arranged on the track section. If complex branching options are required, each sensor has the receive addresses to be addressed corresponding to their priority in the event of a fault (instead of a linear increment / decrement)

We can therefore differentiate between four cases when establishing a data connection using the "ping" signal:

1., the error-free normal case, in which one sensor announces its readiness to send with a "ping" signal and a receiving address relating to an adjacent sensor, to which the neighboring sensor responds with an ACK signal and the sensor which sends out the "ping signal" to receive the ACK Signals sends the data. After the data has been received, the sensor in question again sends a "Png" signal with a sensor address corresponding to the direction of propagation of the chain.

2., the simple Störfall_A, in which the data transmission of some sensors in the chain has failed, but a receiving sensor with functioning data transmission can still be reached within the range of the sending sensor, so that a direct bridging of the data path is possible and the receiving addresses of the erroneous Sensors are immediately reported to the control centers provided at the line end or line sections.

3., the interruption fault B, in which so many sensors in the chain have failed that a receiving sensor can no longer be reached in the specified data transmission direction, but data transmission from the sensor detecting the fault is still possible starting in the opposite data direction. In this case, the data transmission takes place from the two end points of the sensor chain. The failed sensors can be reported immediately to the control centers provided at the line end or line sections.

4., the interruption accident C, in which so many sensors within the chain have failed that a receiving sensor can no longer be reached in the specified data transmission direction, but data transmission in the opposite data direction is still possible, but no longer from the Stodall recognizing sensor. In this case, the data transmission takes place from the two end points of the sensor chain. However, the failed sensors cannot be reported directly to the control centers provided at the line end or line sections. The control centers must recognize this case by the absence of acknowledgment signals from the protocol. This case occurs very rarely. There must be so many sensors failing at the same time that in both transmission directions with a "ping" signal no more receiving sensors can be reached. If the control panels detect the absence of acknowledgment signals, each individual sensor is gradually started at the line ends via a backward addressing of the sensor chain, starting with sensor SO and Se, a data connection from ZTB to SO and ZTE is established, then a data connection from ZTB to SI and ZTE to Se-1, etc., until each at the end of the chain of the central station there is no response from the With this protocol, the control centers each provide a reference address that is incrementally increased after each complete forward-back addressing. This reference address relates to the receiving addresses of those sensors that result in a received "ping" signal after they have received the associated Receive data h the transmission pending signal (i.e. change the characteristic state of bit bR) so that the transmission runs back to the control center until the end of the line, which in the next cycle increase the reference address (for the location of the sensors) for this backward addressing. This process is carried out by the two control centers provided at the end of the line (or partial sections of the line) for each of the individual sensors until the fault location is identified.

The following is an example of the content of a "ping" signal, which contains a "ping" signal: r The receiving address = address of the sensor authorized to receive. r The sender address = address of the sensor that sends the "ping signal".

> A identification bit bD, which indicates to the authorized sensor that data is still being forwarded to the Pmg-Smgal after receipt of an ACK signal, possibly also the registration of the word length, or that indicates that no more data should be sent for a received ACK , therefore the sensor authorized to receive the ping signal with the receiving address of the next sensor in the chain can immediately send the ACK signal. A characteristic bit bR which is emitted by the sensor emitting a "ping" signal and which indicates the transmission direction (ZTB to ZTE or ZTE to ZTB) to the receiving sensor. In the present explanation, bR is only shown as a single bit. However, this relates This data word, which is very sensitive to the protocol as a redundant error, is saved in the transmission protocol, possibly with block repetition for absolutely reliable transmission of the characteristic state of BR r Redundant bits corresponding to the required Hamming distance in order to be able to carry out an error detection or, if necessary, also an error correction for the Pmg signal.

Below are some examples.

Example for the normal case: If sensor S3 receives a "ping" signal (with its address "0003" as the receiving address), then it emits an ACK signal, expects to receive further data depending on the characteristic bit bD, and then sends the ping signal with it the selected receiving address, namely "0004" for bR = 1 (transmission night from ZTB to ZTE) or "0002" for bR = 0 (transmission night from ZTE to ZTB). For the sake of simplicity, the receiving addresses of the sensors are arranged according to consecutive sections in which they are arranged on the track, according to increasing digits.

Example of a malfunction: As long as a transmitted "ping" signal is acknowledged with ACK, the transmission night transmitted via the identification bit bR to a transmission signal is maintained and is transmitted accordingly when the next "ping" signal is transmitted. However, if a sensor no longer receives an ACK signal for a transmitted ping signal, the transmission device is changed in the manner described. In the event of an error, each sensor in the chain is able to change the transmission device and build up the data chain in the reverse direction in order to report the point of interruption. The same is the case if, for the purpose of testing, the reference address already explained is given by the central transmission device and the transfer device is reversed in a relevant sensor when it is set.

For example, if the data traffic runs from ZTB to ZTE and sensor "0100" no longer receives an ACK signal on its transmitted ping signal, then it initiates the data transmission back to via sensor "0000" to ZTB and reports that in the direction of ZTB to ZTE only to Sensor "0100" can be communicated. This message is given by ZTB via the existing direct connection (eg Internet backbone, etc.) to ZTE. ZTE then controls the data connection using the appropriate protocol (sensors control from ZTE to sensor "00F00" or Sensors reading from sensor "00F00" to ZTE) and ZTB control the data connection (sensor control from ZTB to "0100", or reading from "0100" to ZTB). Thus, despite the interruption, all sensors, except for the faulty ones, with the central ZTB / ZTE can communicate and the exact location of the fault is automatically determined immediately. Sensor control is understood to mean the data transfer to a relevant sensor, for example to Selbs to set ttest values (via Rp, cf. also the cited DE 42 40 739 C2) or to set query criteria (e.g. setting limit values to be monitored). Sensor reading is to be understood as querying the values or monitoring states. Here, e.g. neighboring sensors can also carry out self-tests, or the reversal of the communication direction can also be selected for reasons of urgency over the shorter distance from one sensor to a central unit, or several central units can be interposed along a linear path, both via the sensors and can communicate with each other accordingly.

A watchdog is also provided in each sensor circuit and is controlled by the microcontroller in question. If the watchdog indicates that the microcontroller has crashed, it immediately switches off the hardware output option of an ACK signal so that the sensor in question can no longer disrupt the protocol

By controlling the direction of the data chain and the respective initialization of the data transfer via each individual sensor, it is possible for individual sensors to insert any data blocks for transmission to a central station in accordance with the urgency. For example, sensors that are currently scanning the track of a moving train can always transmit their data to the control center in a compressed and fast manner, or sensors that have to transmit a dangerous message to the control center. However, the data transmission chain can also be used for direct data transmission one in The reception area of the sensors of the train currently traveling is directly involved. The transmission device of the train sends a correspondingly coded "ping" signal. If a sensor located near the train detects this "Pmg" signal belonging to the train, it initiates the further sensors via a to communicate appropriate data transmission via the train. In this case, for example, each wagon of a train can also have a corresponding transmit / receive device in order to be able to communicate with the sensors. Likewise, the same principle can also be used to wirelessly operate sensors mounted on the wagons or the chassis of the wagons and to allow them to communicate wirelessly, or the method can also be used to correspondingly switch the sensors via standard power lines of the wagons operate and connect to a central office.

The "Pmg Signal" method described has the property that interference traps can be localized immediately according to the physical conditions (distances). Of course, this does not only apply to interference traps, since each response point (sensor receiver / transmitter) reports a special event regarding its physical position Therefore, this method is also particularly suitable to support the line diagnosis for power lines explained in Fig. 40, further for alarm systems in which the sensor is used. Also particularly as motion detectors in the border protection area. In this application, a large number of sensors are in one If a loss is detected, the position is passed on using the preferred method, and if a sensor is removed, this is also reported. These transputer sensors are then fed, for example, by means of an induction Cable connection inductively manufactured supply data line, in particular via the quick contact described below (to establish a detachable connection safely, permanently and quickly). The induction cable buried in the ground can be patched back together at any time if necessary.Furthermore, the transputer sensors can communicate autonomously, even without a power supply, long enough to transmit a position report (as sender / recipient address) in the event of sabotage, e.g. if gold capacitors are used for energy storage , The GPS coordinates to which the sensors have been buried are then stored in the control centers, e.g. only protrude with a short antenna. If the induction cable is removed from a sensor, the control center has immediately detected the position. In this context, reference is also made to the following chapter “safety-coded loss measurement sensors”.

Fig. 44 and Fig. 45 illustrate a further application for the described networking of loss measurement sensors. For example, with sensor coils embedded in the carriageway to enable the cost-free detection of driving behavior (overtaking, speed detection, traffic light stop, driving against one-way traffic, etc.) of vehicles at exposed points. It is provided that a flat coil consisting of a few turns and extending over the roadway is let into the roadway. In a preferred embodiment, a simple, very cheap to manufacture ribbon cable, the ends of which (the outer conductor progressing inwards in each case) are connected in series and thus form the coil. A corresponding test section has a large number of such cable coils in the detection grid at corresponding distances across the carriageway placed in the lane, separate for each lane strip. Such a flat coil is shown in Fig. 44. The contact is made at the end of the ribbon cable with the usual pressure connectors, which make the connection via a narrow circuit board. The ribbon cable shown for Fig. 44 symbolizes, for example, a 64-pohges cable, of which only 6 lines are shown for drawing reasons. On the side corresponding to a roadway edge, the printed circuit board has a coupling coil (LKT) connected to the ribbon cable spool, which is potted together with the plug at the end of the ribbon cable, the other end of the ribbon cable is also potted. The ribbon cable can be provided with a tar protective layer. To increase the compressive strength, an iron wire can be used instead of a copper strand, or solid wires can also be used. The preferred evaporation by means of negative resistance and measurement independent of the interference voltage make such a construction possible since the high inherent loss of the cable coil is evaporated by the preferred negative resistance component of the sensor. The preferred sensor becomes contactless on the coupling coil LKTk e.g. by a cheap plastic mounting part, clamped, the sensor also having a matching coupling coil LKTs. This contact-free connection means that replacing the sensor is completely unproblematic. The low measuring power of the cable coil of the preferred sensor makes this construction possible.

Furthermore, the sensor housing, which is connected to the ribbon cable coil by contactless clamping connection (via coupling coils LKTk / LKTs), has a cylindrical extension with flanges, similar to a coil body, which contains the encapsulated RF circuit coil of the transducer circuit for the inductive supply of the RF supply voltage inside the sensor. In further training (see Fιg.43, Fιg.45), this is e.g. made of plastic bobbin approach (winding body) provided with a centrally guided pulling cap held by spring force, which pushes over the winding on the winding body fixed by looping the induction cable entering and exiting on both sides of the pulling cap in corresponding slots, the pulling cap passing through the Spring force is pressed on the outer flange of the winding body. Furthermore, a snap-in device is provided which, after pulling off the cap, holds the cap against the spring force (e.g. by means of a rotation lock), so that the fitter has both hands free when winding and unwinding the induction cable. We then unlock this latching device by turning the cap slightly and the relative induction cable wound loosely around the bobbin is sufficiently fixed by the pull-off cap. Furthermore, the winding body can also be provided with appropriate thread shafts in which the induction cable is wound.

It is evident that such a type of contacting, including the preferred loss-modulated data transmission method, can also be used very well in the area of installation, in line monitoring of high-voltage networks, in aircraft construction, shipbuilding and especially in vehicle construction, in order to be absolutely reliable , Durable, but at any time without having to manipulate the cable and without the need for connectors, contact connections for supply voltage and data line supply with a simple insulated wire cable. It is evident that this contact connection is suitable for any type of electronic component (ie not only for sensors) using the preferred method for loss sampling of data encoded by loss, and therefore the request for the protection request extends accordingly in general

The combined supply and data cable, which connects all sensors in sequence, only needs to be wound once or several times in a loop around the coil body cylinder in order to contact the sensor. When the sensor is replaced, this winding is simply removed and attached to the new sensor. Such a simple induction cable is laid on each edge of the road, which can also be laid unshielded in the ground when using the interference signal-independent data transmission method. At the point where the sensors are plugged in or the induction cable is wrapped, corresponding stripes (which interrupt the asphalt of the sidewalk) are paved on the roadside or sidewalk, so that in the event of a sensor exchange, only the paving stones have to be removed without breaking the asphalt.

According to this method, it is easy to "pave" the street with such very cheaply manufactured ribbon cables. The costs for this are less than one percent of the road construction costs. The ribbon cable coils are each located as a horizontal strip above the roadway at a distance from one another which is adapted to the average car length The loss measurement is used to detect between the same events (reaching or exiting) of a strip for the cars driving over it. Thus, in flowing traffic, each vehicle can be tracked in its driving behavior via such a chain. This also includes a detection depending on the direction of travel In order to directly detect the direction of travel, two sensor coils placed parallel to one another are provided for a measuring line, of which one is vaporized first according to the direction of travel, before both coils are simultaneously vaporized by the vehicle in question n. For the recording, a memory organization (a computer RAM) is used which has as many memory words as it corresponds to the detection grid which is formed by the measuring line. Between these measuring lines, which are each formed by the ribbon cable coils, the speed of the vehicle traveling over them is measured in each case and stored together with the virtual vehicle identification number and the driving data in the memory location corresponding to the relevant measuring lines. The driving data relate to speed and lane change detection. If there is no physical overtaking possibility, then with larger distances between two measuring lines, there may be several cars at the same time within the measuring range and can be clearly identified on the basis of the pulse pattern (when the vehicles are unlocked into the measuring line limit, there are briefly more at the input measuring range If there is an overtaking possibility (also the overtaking lanes and those of the oncoming lane each have a separate detection grid), then overtaking maneuvers can also be assigned to the correct vehicle when swerving, if several vehicles are between two successively arranged measuring knees, we carry out a few additional criteria and a more complex pattern recognition, assuming that a vehicle cannot accelerate as quickly as desired within the measuring grid divided by the measuring knees, we iters that at a known speed (e.g. a column) the exact length of the vehicle can be deduced from the duration of the loss vaporization of a single measurement line, and furthermore that when a vehicle swings out, a time gap occurs at the sensor pulses that otherwise arrive at regular intervals and, depending on Whether an additional impulse occurs on the fast lane, the time gap is caused by the delay of the vehicle column, or by swerving, this also applies to the overtaking lane evaluated in coincidence, whether an additional impulse is caused by acceleration or by a vehicle being cut in (squeezed). Since it is also possible to infer the respective vehicle lengths in this serial tracking scan of the driving style, the distances between the vehicles can also be monitored well. Furthermore, if, for example, there are two vehicles within a measuring grid enclosed by two measuring ranks, then from the time comparisons of an extended impulse pause in the lane to a shorter impulse pause in the fast lane, the correct vehicle that has overtaken can be concluded. When the monitoring memory (RAM) is designed, as many memory locations are provided for each measuring grid section as there is a maximum space for vehicles between two measuring nodes. The virtual ID numbers of the vehicles in RAM are moved in the same way (corresponding to a shift register or FIFO first in first out) as the sensor signals of the scanning coils deliver the impulses. Such a virtual shift register simulation is simulated for each lane, the sequence of the lanes (or the lane number) being recorded via the index of a multidimensional array (as it were, as a multidimensional or multitrack shift register). As long as the pulse train (of the sensor coils) occurs in each lane according to a reasonably constant frequency, all vehicles drive without overtaking. If the pulse sequence is controlled spontaneously, the pulse pause increases on one track and a corresponding delay of the pulse pause occurs on the other track. This is decoded by a change detector, which always detects the change in the pulse frequency (as the first derivative and also as the second derivative, i.e. how quickly the change occurs) and the search pattern for determining the course of time (or successive memory locations of the RAM FIFO) of this change started with a multiplex query of all indexes (tracks) The assignment of a virtual vehicle identification number takes place at the beginning of the surveillance chain when passing over the first sensor coil, deletion if there are no special occurrences, or if the camera installed (somewhere) at the end of the surveillance chain does not indicate the vehicle recorded, so the ID number can be reassigned. Several cameras can also be networked for better control

Another embodiment variant is to be discussed below:

Variant: "safety-coded loss measurement sensors". This chapter highlights another interesting aspect. It is obvious that the sensor according to the invention is particularly useful in the communication options described in the previous chapter and below in the alarm security and monitoring areas To be used, for example, as motion detectors in the border protection area or as locks for doors and windows, etc. However, there are a number of things to consider. The present invention offers the possibility of compensating for positive and negative losses. The principle of inductive (transformer) coupling of losses has been explained in a special way Detection method already mentioned in the cited DE 42 40 739 C2. D h one only had to decouple the loss fluctuation by listening to the sensor (by means of a coil) and correct it with this measured variable.A direct transformer-based amplitude-based regulation (to bypass the sensor) would not work with the new sensor, since it measures an absolute measurement amp, or measures the envelope curve independently This gives rise to the technical problem of generally preventing loss-based regulation (by transformer coupling of a positive or negative loss). It is preferably provided that using the property of a sensor of DE 42 40 739 C2, which enables that by means of a control signal a loss influencing of the sensor is possible as if it had been carried out at the measuring point itself, this possibility of attack of the sensor is used directly for defense. This is accomplished by (as a solution feature of the technical task) the parameter (BD, Fig. 1) for Influencing the at the Measuring point occurring loss controlled variable resistance Rp (loss 1 / RVM) is varied according to a temporal code pattern and furthermore, the overlaid with this variation, total loss occurring at the measuring point (total loss) is measured for monitoring and checked according to the temporally running code pattern corresponding comparison values ( or compared), the following consideration is assumed. The loss is varied with the variable resistance on a filter or resonance circuit (LM, Cp), so a listener must also use a filter or a resonant circuit (LM, Cp) .We can also use the safety-coded loss measurement sensor as a further safety option, also the measurement voltage of the Modulate the resonance circuit in addition to the loss vanation (of course, according to a different Hull curve than the loss vanation). The eavesdropper, since he cannot orient himself on a decoupled voltage, but must measure the loss directly regardless of absolute voltage values or independently of an existing Hull curve, in any case, it takes longer to determine a loss value than the internal loss measurement of the security-coded loss measurement sensor allows, but then it is already too late, since the code pattern in progress has already changed its value. In this case, the internal measurement of the security-coded loss ustmeßsensors are under no circumstances waited until a value at the resonance circuit has settled, since the reference values are known.Therefore, the values can already be compared according to the respective rise or fall of the Hull curve, so that a listener is unable to adjust and therefore the loss fluctuation is not The safety-coded loss measurement sensor was also immediately recognized when the offset value of the loss overlaid on the loss vanation via BD or 1 / RVM changes

In addition to the alarm security applications mentioned, an embodiment is preferred in order to be able to electronically code parts, for example aircraft or car spare parts, etc. In this way, similar to a chip card, the sensor is provided with an encryption, by means of which it can be read out which part it protects or resp still associated specific data, such as date of manufacture, etc., and whether an attempt to attack to remove the sensor from the part has taken place. An attempt to attack, to remove the sensor from a part to be protected, is determined by changing the offset value of the measured loss, on which the loss vanation is superimposed via BD or 1 / RVM. For this purpose, two fundamentally different design variants are provided - one in which the sensor module is mounted directly on the part to be protected and measures the loss via its conductivity, e.g. aircraft sheets, engine blocks, body parts, or any type of spare part surrounded by a metal housing, and a further variant, in which the sensor module is used as a closure detector of a package, within of the parts to be protected For direct mounting of the sensor on the part to be protected, the sensor is provided with an adhesive layer, for example, and simply glued to the part in question, the part in question optionally also having a snap-in for additional fixing of the part can A further possibility is to fix the part concerned together with the vacuum-packed sensor, etc. Furthermore, a simple embodiment variant is preferred, which can be used both as a closure detector of a packaging and for immediate assembly suitable part: A band is pulled through the sensor housing, which is designed as a potted module unit, on which the sensor can be moved. This plastic tape corresponds to the usual packaging tapes that can be welded with a suitable welding gun. This tape has the property that it can be welded again after it has been cut through, but the new joint cannot be hidden. The packaging chosen for the parts to be secured is, for example, a simple tin box, the lid edge (a hinged or peel lid, etc.) however, has lead-through slots for pulling the tape through. The tape placed around the box closed with the lid, on which the sensor is slid over the appropriate tape guide slots in the sensor housing, is welded under tension as standard (e.g. in the middle of the box). The sensor is then pushed and fixed exactly over the welding point. The fixing is carried out, for example, by pulling surfaces which protrude from the sensor on the side of the tape on the underside of the sensor for exposing a self-adhesive layer of the sensor with which it is glued directly onto the packaging box. In order to also be able to detect a careful shifting of the sensor, a metal wedge running obliquely in the direction of the tape is provided on the inside of the box, so that even a simple shifting of the sensor (with a loosened adhesive causes a change in loss). In such a variant, a plastic box can also be used. The place where the sensor is to be placed or the tape is to be welded is then marked by printing. In this way, for example, a box with aircraft bolts can be secured by three bands, each of which carries a sensor. Evidence that the forgery of expensive aircraft bolts has already caused aircraft crashes Circuit: The sensor is switched according to the preferred transputer sensor variant, and contains a non-volatile read-write memory (e.g. FLASH memory, EEPROM, or battery-buffered RAM), a button cell battery or battery , where appropriate a gold electrolytic capacitor can also be used as the battery for the intermediate storage of the energy of the HF receiving circuit, furthermore a monitoring circuit for the supply voltage (for example the battery) which, when falling to a minimum value, at which the processor circuit still works, in the writes a code to the non-volatile memory to indicate this. After the supply voltage has failed, the transputer sensor chip can be reinitialized at any time by transmitting an HF via its HF circuit in order to read the non-volatile memory using the encryption protocol (similar to a chip card) .If this memory indicates an interruption in the supply voltage, then it is generally assumed that the part in question to which the sensor is attached is not genuine. If, on the other hand, the chip has been constantly under supply voltage since its initialization during packaging, the further data read from the memory decide whether the part in question is genuine. The part is genuine if there is no registered attempt to remove the part, ie no loss change has occurred outside of the changes specified by the temporal loss code pattern. To save performance, the sensor in question can also take a short break after each generation of a loss code pattern (duty cycle). In the storage room, the sensors are charged, for example, using the supply described by means of induction cables. During transport, a central HF transmitter in the cargo hold can continue to supply the transputer sensors, or the sensors are powered by the built-in rechargeable battery (or battery). Communication with the Em output device takes place via its own RF transmit / receive frequency or also via the RF circuit of the transputer sensor provided for the voltage supply. The temperature response can be compensated for in different ways, depending on which of the two methods of dynamic or static relative measurement described below for Fig. 8 is used. In the case of dynamic relative measurement, any loss change that occurs outside of the very slow adjustment process in the automatic adjustment of the working inconvenience is displayed as a response point. It makes sense to modify the adjustment described for Fιg.8 by means of payer clocks so that the very slow adjustment is not in regular cycles but in clock pulses with different time intervals (ta, tb, tc, td, te, ...., etc .) between the number pulses (za, zb zc, zd, ze etc.) is made. The time intervals (ta, tb, tc, td, te, .... etc.) are also set according to a predefined code pattern, with any further loss change outside the counting pulses corresponding to these time intervals (za, zb, zc. Zd, ze etc. ) not as an adjustment of the offset value to adjust the operating point in order to eliminate the influence of temperature, but as an attempt to shift or Distance of the sensor from its target loss range is evaluated. In this case, however, the measurement or loss assessment takes place taking into account the loss change BD to be expected according to a predetermined code (for encoding the loss) both for the variation of the total loss by manipulated variable BD (according to a predetermined code_BD) and for the respective setting of one (also after a changed Code_Tz) set time value to compensate for the temperature drift via a corresponding change in the offset value (see text for Fig. 8), both code values (Code_BD and Code_Tz) can also be generated by a random generator. The offset loss value changed at a time value of Code_Tz (with corresponding number pulses (za, zb, zc, zd, ze etc.) is then taken into account for the reference evaluation of the loss measured in each case by the proportion in the variable resistor corresponding to the offset loss value Loss 1 / RVM is retained accordingly (remains stored as offset value for measurement of usl). In principle, the measurement method can also be carried out without a negative resistance component. For static relative measurement, a reference measurement coil LT (with CT) is provided in addition to the loss measurement coil LM (with Cp) , which is also fixed to the tin box with a suitable tape and glued to the tin box, or can optionally also be attached to the inside of the tin box.

Further education:

Variant: Use of the loss measurement sensor for signal transmission that is completely insensitive to interference. In particular, the request for protection extends not only to an application as a loss-measuring sensor for recording corresponding physical measurement quantities, but since the inventor has apparently broken new ground with his invention, the possibility of using the sensor in particular for signal transmission that is completely insensitive to interference is to be used for signal decoupling. In the text for Fig. 36 and Fig. 37, the delimitation from the prior art, new solution paths, and applications for such a transmission are described for the most varied of applications: standard data line connections in mechanical engineering, transmission of data on existing power networks (external, land lines, City lines) and internally (in rooms, e.g. for computer networking or machine networking, etc.), and furthermore the use of such a signal transmission to network the sensors designed as transputer sensors using a simple induction cable (cable or current loop wound around a winding mandrel) ,

The individual figures show:

The circuit from FIG. 1 is taken directly from DE 42 40 739 C2 and is directly suitable for carrying out the method of the present application without substantial changes if the software of the microcontroller (MP) used is modified accordingly. Examples of the process sequence of the method according to the invention are described in FIGS. 2b and 2c. Fιg.2b and Fig.2c represent two different variants, which use the same inventive principle according to claim 1. In contrast, Fig. 2a illustrates a method as has already been proposed according to the prior art in DE 42 40 739 C2. 3 to 6 relate to further developments of the invention with regard to circuit configurations. 7 relates to an application on a brake disc in which the method is also described for a temperature measurement, as already proposed in the cited DE 42 40 739 C2. 8 shows an equivalent circuit with a detailed explanation of the preferred evaporation of the loss measurement with a negative resistance or conductance. The other figures relate to further developments of the invention, which show the possibilities of the new method for the most varied of applications. for FIG. 36 the application of the method for a signal transmission method that is insensitive to a disturbance signal is described, with the various application possibilities described for further figures

The individual figures are explained in more detail below:

Fig.l is taken from DE 42 40 739 C2 and shows the corresponding principle.

2a illustrates the process according to DE 42 40 739 C2 without applying the process improvement according to the invention: the value of 1 / RVL is changed at Rp within process step (t) until us is set to a specific value

2b illustrates the sequence of the preferred interference signal suppression using the following method steps t1 and t2 (variant 1):

• tl: set (set) at Rp value Rpl and measure usl

• t2: set (set) Rp value Rp2 and measure us2

The preferred alternative (option) is that, for simplification, a value of Rp = infinite (ie switched off, see HS Fig.l). The other value of Rp is a constant. The ratio Rp '* usl / us2 becomes RVM (measured loss). The ratio usl / us2 is set as a variable corresponding to RVM and the predetermined constant Rp, where Rp ^' = 1 / RVL + 1 / RVM, as previously described for variant 1.

2c illustrates the sequence of the preferred interference signal suppression using the following method steps (variant 2):

• tl: Specify (set) Rpl value at Rp and measure usl

• t2: Change (scale) at Rp value Rp2 until usl / us2 = constant

There is the option of a value of Rp = infinite (ie switched off). The other value of Rp is varied (adjusted) until the constant usl / us2 is satisfied. Ie in this variant, in the second method step (t2) Rp is a variable and us / us2 is a constant, which can thus be detected by a comparator circuit and therefore usl / us2 does not have to be calculated, which has advantages for the smallest microcontrollers. For simple applications, Rp can also be, for example, a linear binary graded master value network that is switched directly by the CMOS microcontroller outputs (high-resistance or against GND ... ground). The microcontroller then also contains a table via which the conductance network is graded in such a way that a calibration in the measured physical quantity results for the comparison usl / us2 = constant, e.g. in ° C (or deg) if the coil is to be used to measure the temperature on a metal (e.g. a brake disc) without contact 3 shows the exemplary embodiment mentioned in FIG. 2b, in which the microcontrolier MP directly controls a binary master value network (Go .... Gn) (switched between GND and open). Go ... Gn (corresponds to the resistances Rn ... Ro) and corresponds to a linearly adjustable master value 1 / Rp. For a non-contact temperature measurement, for example on brake disks, the function master value = function (temperature) can be assumed with sufficient accuracy in the microcontroller using the table. The same also applies to distance measurements. The zero crossings (SYNC) of the coil current are detected by LM via Ro and amplifier V. Optionally, a transformer coupling can also be carried out via a corresponding winding to LM via the summation point S of the master value network

FigAa shows a detail for an example in order to carry out the method according to the invention in accordance with the sequence according to Fig. 2b, consisting of an S&H (sample and hold) A / D converter, which measures the voltage values at the resonant circuit at the time of the zero crossing of the resonant circuit coil current (= Voltage maximum) samples and supplies the microcontroller with a switching signal BD (Fιg.5) for the semiconductor switch HS, which switches the variable resistor Rp to the resonant circuit in the manner described

4b shows an example for carrying out the method according to the invention in accordance with the sequence according to FIG. 2c, consisting of a comparator circuit (C) with two comparison inputs (a, b), one of which directly and the other via an S&H (sample and hold) memory circuit voltage values on Scans the resonant circuit at the time of the zero crossing of the coil current (= voltage maximum), this time being realized by a validity signal at the comparator output. (SYNC, see also Fig. 1 and DE 42 40 739C).

The S&H (sample and hold) memory circuit is required so that the voltage values can be compared at different times from the different measuring cycles (tl, t2). One of the two inputs has a voltage divider (Rva, Rvb) that is dimensioned such that the inputs have the same voltage at the comparator output for the fixed constant value of the ratio usl / us2

The detection of the coil current zero crossing (cf. Cu in Fig. 5) to determine the voltage maximum at the resonant circuit can be carried out in addition to the use of a small series resistance (Rmi), for example also by means of a coupling coil or Hall generator

Fig. 5 shows an example for constant control of the resonant circuit current, which is coupled out to a comparator (Ci) via a measuring resistor (Rmi) connected in series with the internal resistance of the supply circuit as a differential voltage (DIFF) and supplied with a comparator (Ci) corresponding to the desired maximum value of the resonant circuit current amphtude

Reference voltage (Ref =) is compared. When the resonance current (ires) is exceeded, the comparator output generates a clock edge (CKminus) for the gradual readjustment to gradually reduce the resonance circuit current amphtude. The output signal of another comparator (Cu, compared to zero) is reversed via the zero crossing of the resonance current (ires = 0, see DIFF) converted into a clock edge (Ckplus) to gradually increase the resonant circuit current amplitude. Both clock edges are, for example, fed directly to a microcontroller (MP), which forms a corresponding forward-back counter (Zint) with the clock edges, the output (x) of which via a corresponding resistance network (D / A) compensates for the resonant circuit current (ires) by means of compensating variation the signal voltage (external supply to coupling capacitor Ck of the resonant circuit) via the supply voltage control (VCCosz) of the supplying oscillator is kept constant.This is intended to measure the width of the CKminus pulse occurring at the output of comparator Ci and, if exceeded, the pedometer (Zint) with several cycles for to clock the faster feedback control of the resonant circuit current (ires) For further signals and components in Fig. 5, see Fig. 4b and Fig. l A particularly preferred simplification version is to connect the resistors of the D / A converter directly to a CMOS microcontroller, and its Supply current output to a summing amplifier, the mede Rohmiger output directly feeds the supply voltage of the oscillator

Control cycles for adjustment of the resonant circuit current and the measuring steps tl, t2

Based on a time grouping for the adjustment of the coil measurement current (from LM) or resonance circuit current in successive period groups, in which a control or measurement cycle takes place over a variety of periods, the following example is given: For example, the oscillator supply voltage (VCCosz) is adjusted for the purpose the constant control of the resonant circuit current (ires) only for every third period group of the resonant current, the preferred measuring steps (tl, t2) for determining the measured value being carried out in the period groups in between (two in succession) and when using the variant for the adjustment of a constant predetermined usl / us2 behavior (cf. variant 2), this comparison (Rp) can also be divided over several such pentode sequences. A period group is to be understood as the number of periods that the resonant circuit (LM, Cp) needs to settle the settling time after a step of voltage change (VCCosz) caused to keep the resonant circuit current constant (ires) or a step of adjusting the adjustable resistance (Rp) Resonance circuit to be considered. The detection of whether a process has settled when VCCosz is changed (so that measuring steps tl, t2 can be carried out validly) can, for example. by evaluating the tactile ratio with which Ckplus and Ckminus alternate. If there are more Ckplus pulses than Ckminus pulses, or if the Ckminus pulse is too wide, the resonant circuit has not yet settled to the setpoint value of its resonant circuit current and the measurement triggering of steps t1, t2 is prevented

Option phi relates to a control signal emitted by the microcontroller (processor) MP to the supply oscillator OSZ of the resonant circuit (LM, Cp), which causes the oscillator via its output (coupling capacitor Ck) to the resonant circuit LM, Cp, if necessary, to phase the (with Cu) dedicated resonance circuit current (ires) feed in phase opposition oscillation in order to keep the resonance circuit current amphtude (ires) at a constant value. This is the case when the disturbance signal is so large that the resonance current ires would otherwise no longer be reduced by reducing VCCosz The circuit shown in FIG. 5 is particularly suitable when the resonant circuit (LM, Cp) is supplied by an external supply (OSZ), the phase position of which compared to a scattering picked up by the resonant circuit coil by shifting the phase position (or an equivalent throughput time) by the microcontroller made displaceable via control signal In a further addition or variant for a self-excited resonant circuit oscillator circuit, an adjustable phase shifter is provided in the feedback path of the oscillator circuit to the resonant circuit, the phase delay of which can be controlled by a control signal from the microcontroller. For example, if there is interference on the measuring or resonant circuit coil (LM) that would be in phase opposition to the feedback voltage of the oscillator, then the feedback would only act as negative feedback and the resonant circuit voltage would drop below the control range for the constant supply alternating current. Conversely, in the case of strong interference at the measuring or resonant circuit coil (LM), which is in phase with the feedback voltage of the oscillator, an overdrive was caused, ie, the control range for the constant supply alternating current was exceeded. In both cases, the microcontroller can use the phase shifter to shift the oscillation circuit amphtude into the desired measuring range, in which the control range for the constant current control described is located. The alternating current amplitude of the resonant circuit feed current can thus be constantly controlled in the manner described. As an alternative or in addition to this, amp regulation could also be carried out by connecting corresponding further losses (offset value) in parallel, but this would influence the overall measurement characteristic (sensitivity, resolution) of the sensor.

6 shows an example in which the measuring principle is used to measure a low-resistance Rx, for example a wire or strain gauge. The complete insensitivity of the method against interference radiation benefits the measuring principle. In the example according to Fig. 6, the measured ohmic resistance is connected directly in series to the measuring coil (LM) via ohmic contacting (KTK).

7 illustrates the example of an application on a brake. In the brake shoes (1), which hold the brake lining (2), there is a sensor coil (LMla.b or LM2a, b.) On one or both sides of the brake lining edge (3) ) and another sensor coil (LM3a, b) is used on the outside of the brake shoes. The inside of the sensor coils (LM1, LM2) measure on the one hand the distance (4) to the brake disc (6) to determine the thickness (5) of the brake pad (2) and also the symmetrical wear (or asymmetrical) in the case of defective brakes. The sensor coil (LM3) used on the outside, on the other hand, measures the temperature of the brake disc (6) at a constant distance, the

Form measured values aO to the running mean (M): M = [M * (n-1) + an] / n, where M ... on the right side of the equation is the current (most recently determined) mean, n .. .dιe sequential number of a current measured value is, and M ... on the left side of the equation is the newly formed mean value, taking the current measurement into account. The temperature measurement of the brake disc (6) also provides a correction value for the sensor coils (LM1, LM2 ) for measuring the brake pad thickness. Furthermore, a standard temperature sensor ~ standard) can also be provided, which measures the cooling effect of the air flow acting on the brake discs, this sensor also being able to be heated directly, if necessary, e.g. two thermally connected transistors, one of which is used as a temperature sensor and the other as a heating element, thus by means of a regulation of the heating power to a temperature corresponding to the temperature of the brake disc, a statement about the braking power of the brake disc can be made about the heating power. The temperature sensor is heated to the temperature of the brake disc (regulated) and is mounted on a surface (standard) which has approximately the same heat dissipation to the environment as the brake disc. The braking power thus obtained is still related to the braking force exerted by the braking system (e.g. measured via braking force or pressure measuring system) in order to measure the efficiency of the brake.This consideration assumes that the greater the heating of the brake disc in relation to the applied brake pressure The better the effect of the brake pads If the efficiency falls below a predetermined value, then either the brake system is defective (uneven pressure distribution of the brake pads) or the brake pads do not meet the requirements. Or, if the brake linings and the brake system are in order, then there is a permanent slip when braking between the road and the tires, e.g. is due to bad tires, or to a corresponding poor road grip. Thus, an ABS braking system can also be calibrated well via the controlling microprocessor from the measurement described, or influenced before a tire still locks, to reduce the braking force-free slip distances.

The variant described corresponds to a further training option, although it is also a great advantage if the brakes overheat, or loss of grip when braking, is signaled to the driver acoustically or optically, or if the risk of overheating activates an engine brake (e.g. by switching off or throttling the exhaust for a part of the exhaust phase with an electrically switched valve or slide) or an automatic transmission.

Another application for temperature measurement is e.g. measuring the temperature on turbine blades, which can be done at a large distance, since the sensor is insensitive to interference.

FIG. 8 shows an equivalent circuit diagram to illustrate the method for the exact setting of the negative resistance (or negative conductance -gT) used in a preferred development for the additional evaporation of the measuring circuit. The serial loss resistance rs of the measuring coil LM can be understood as a parallel conductance transformed by the parallel resonant circuit (LM, Cp), which is compensated by a negative conductance -gT (e.g. a tunnel diode) parallel to the resonant circuit (e.g. a tunnel diode), with the measurement variable switched on of the loss to be measured 1 / RVM. As already explained for FIG. 1 and for the associated method steps, the loss resistance rs of the measuring coil LM is already included in the value of 1 / RVM ^' , a table for the actual assignment of the measured value 1 / RVM from the measured 1 / RVM ^' is used. In order to be able to precisely set or measure the value of the negative guide value -gT, reference is already made to DE 42 40 739C proposed compensation measurement method, this method applied accordingly modified, using the relationship measurement specification specified in claim 1 of this application, in a preferred embodiment carried out according to claim 3, the preferred setting or measurement of the negative conductance -gT switched on for evaporation takes place completely independently of the permanently switched on loss 1 / RVM 'As a reference resistance or for the determination of -gT, a value of the calibration or calibrant conductance GTCOMP is provided in parallel with the negative conductance -gT, whereby the conductance zero can also be provided as a setting value and, if necessary, the switchover of two Values are sufficient. The value of the negative conductance of the tunnel diode -gT can also be changed, the conductance zero can be provided as the setting value and, if necessary, the switching of two values is sufficient. Whether the relevant guide values -gT and GTCOMP are made adjustable within a value scale by means of manipulated variables, or can only be switched between two values (e.g. zero and GTCOMP, or zero and -gT) depends on the relationship condition set up for a desired application according to the losses present at the resonant circuit in addition to the preferred measurement method for the interference signal independent measurement of a loss 1 / RVM (cf. measurement steps t1 and t2 with ul, u2) for the determination of -gT. With reference to Fig. 8, the adjustment procedure for determining -gT is carried out as follows: 1): When -gT is switched off and GTCOMP is switched off, the resonant circuit voltage uoff is measured at the parallel resonant circuit LM, Cp. 2): In a subsequent step, -gT and GTCOMP are connected to the resonant circuit. If both values are equal (-gT = GTCOMP), the same voltage uon = uoff occurs on the resonant circuit as before when -gT and GTCOMP were switched off, since -gT and GTCOMP compensate. If instead of switching off the master value GTCOMP, there is only a corresponding reduction in value (to 1 / RVLo), then the adjustment to the corresponding value difference -gT = (GTCOMP - 1 / RVLo) takes place, see also the following table. Likewise, as an alternative, instead of switching off, only a corresponding change in the value of -gT could be carried out in order to be able to determine the value of -gT from the amphtudic changes (us *) of the resonant circuit voltage resulting from the changed values. For the sake of simplicity, only -gT = GTCOMP is specified below for the adjustment condition. In order to achieve this adjustment, with a given GTCOMP, the negative conductance -gT can be adjusted (set) to the value of GTCOMP (-gT = GTCOMP) until the voltage measured on the resonant circuit is equal to uoff, or the respectively set negative The conductance can be determined by comparing GTCOMP (GTCOMP = -gT) until the voltage uson measured at the resonant circuit is equal to uoff (uson = usoff). When carrying out the adjustment of -gT = GTCOMP or -gT = (GTCOMP - 1 / RVLo), it must be taken into account that the differential resistance is also slightly dependent on the amplitude of the small signal modulation at the selected operating point. Therefore, when determining the negative conductance -gT, it is provided that the voltage value uoff (after which uon is compared) should be selected so that it corresponds to the voltage values usl (in step tl) and us2 (in step t2) that occur during the actual loss measurement. equivalent. These measures are described in detail in the previous chapter "Variant of Evaporated Sensor, Basics" with exemplary embodiments.

It is evident that as with the measurement of the loss 1 / RVM in the measuring steps tl, t2 for the determination of ul, u2, also for the comparison of -gT (in the measuring steps ton, toff), instead of one directly on the resonant circuit in each case voltage measurement (us * or uson, usoff), voltages proportional to the resonant circuit voltage can also be measured, e.g. Via a voltage tapped at a series resistor to the resonant circuit Since the same voltage is measured on the resonant circuit in each of the two measuring steps ton, toff for an equalization uson = usoff, the method is independent of an interference signal radiation as long as there is no Hull curve; or in the presence of a Hull curve, the measuring method is synchronized according to the period of the Hull curve; or in a further alternative, for the measurement of uson = usoff the voltage values in question are correlated in accordance with the envelope curve.The same options and measures apply as for the measurement of ul and u2 for the measuring steps tl and t2 for the two process variants embodiment and Execution variant2 have been described (cf. synchronous and asynchronous mode) For particularly precise measurements, however, it should be taken into account that the operating point of the tunnel diode is placed in a linear range where possible, in which the differential conductance of the tunnel diode -gT is greater than that of the actual one Loss measurement occurring control range ul and u2 remains constant. By transforming -gT to the required parallel conductance, the tunnel diode can be operated with the lowest voltages in order to keep -gT stable in the required modulation range. Furthermore, it is provided, if necessary, to determine the conductance of -gT for two different values of uoff, namely, for example immediately after the measurement of ul (in tl), a measurement of -gT for uoff = ul with a deviation uon = uoff , whereby, since the measurement -gT takes place regardless of the loss 1 / RVM that is switched on, the condition uoff = ul can be set via the offset value of GTCOMP = 1 / RVLo, or can be further adjusted. The same applies after measuring step t2, for the amplitude u2 of the resonant circuit voltage. Depending on the requirements, the actual loss (via usl, us2) can be measured in asynchronous mode, but the comparison, or the determination of -gT, is synchronized in synchronous mode after stable phase positions, with respect to the penodicity of the interference signal envelope curve of the measurement signal after each measurement of usl (in tl) or us2 (in t2), the resonance circuit amphtude is sampled until the value usl or ditto for us2 occurs again on the hull curve of the resonant circuit voltage, or at least an approximate value. Such an amplitude sampling is prepared for each of the two measuring steps tl (with usl) and t2 (with us2), even if tl and t2 are measured successively in accordance with the asynchronous mode (in order to obtain as many measurement results as possible). This means that there is no need to adjust ul = uoff with GTCOMP = 1 / RVLo; for the measurement of u2 = uoff, the value switched on via Rp to u2 (in order to obtain u2 for the actual loss measurement in t2) corresponds to the offset value GTCOMP = 1 / RVLo obtained for the setting u2 = uoff. The corresponding value difference -gT = (GTCOMP - 1 / RVLo) then applies to the comparison of uon = uoff, as has already been explained. See also the previous chapter “Variant of evaporated sensor, basics.

Is for the measuring process, e.g. According to the implementation variants2, a loss resistance Rp that can be set by means of the manipulated variable (BD) is already provided (e.g. for a comparison according to the given ratio usl / us2 = constant), then Rp can also take over the function of GTCOMP at the same time without the need for a further cascade. After setting -gT with Rp e.g. the comparison of us / us2 = constant in the process according to the execution variants2. With reference to the names HS (gT) for -gT and HS (GTCOMP) for GTCOMP used in the equivalent circuit diagram for the electronic switch (eg FET switch) for switching off the negative conductance -gT and the calibration conductance GTCOMP, the following superordinate can therefore be used Summarize measurement steps that are repeated for each loss measurement carried out:

Sheetl:

STATUS HS (gT) HS (GTCOMP) us *

1st adjustment step toff open open or offset value 1 / RVLo * 1) usoff 2nd adjustment step ton closed closed * l) uson

1st measuring step tl closed open or difference *!) Usl 2nd measuring step t2 closed open or difference *!) Us2

*): Note: If GTCOMP is made adjustable by manipulated variable, then instead of switching off HS (GTCOMP), a corresponding value variation of GTCOMP can also take place when the HS (GTCOMP) is closed (or not available): HS (GTCOMP) is in toff a value 1 / RVLo switched, which corresponds to a permanently switched on loss value 1 / RVLo during the adjustment of HS (GTCOMP) in steps toff and ton, which corresponds to the good and thus the settling time of the measuring oscillating circuit to accelerate the adjustment of the negative conductance -gT accordingly reduced. The setting of GTCOMP to the value 1 / RVLo therefore corresponds to the state of the shutdown of GTCOMP in toff, the value of uoff being set to a (predefined) amplitude of uoff (or also ul) corresponding to the desired good with 1 / RVLo can be

For a comparison uson = usoff in the adjustment step ton, -gT is therefore not directly GTCOMP but rather -gT = GTCOMP - 1 / RVLo (the losses corresponding to the guide values). Depending on In the adjustment cycle, the desired formation of the measuring method can be maintained in the subsequent measuring step tl, the loss value 1 / RVLo which is permanently switched on as offset value for the measurement of usl, with appropriate consideration for the determination of the loss value in measuring step t2 (when measuring us2). If necessary, GTCOMP can also be used as a variable resistor Rp in measuring step t2. Furthermore, the master value 1 / RVLo could also be switched on externally and therefore a comparison -gT = GTCOMP was carried out, or for most applications the loss 1 / RVM coupled into the measuring coil is large enough to compensate for the -gT = Set GTCOMP accordingly. The requirement for a good reduction for the compensation of -gT = GTCOMP is interesting if particularly low losses (or conductance values) 1 / RVM are measured absolutely with measuring coils LM, e.g. distance measurements on materials such as carbon fiber, high-resistance measuring Detectors with the smallest measuring power in the nW (nanowatt range) at the lowest measuring frequency in order to be able to automatically scan letters for letter bombs safely, for example, or slowly integrating measurements on gases to determine ionization, etc. A calibration for -gT = GTCOMP can also be used separate resonant circuit Lneg, Cneg.

The direct comparison of -gT to a specified value of GTCOMP is useful if -gT is specified as a constant value (or measurement constant) for setting a desired good to reduce the loss of the measuring circuit (LM, Cp), and the loss to be measured 1 / RVM is measured as a total loss together with the negative conductance -gT according to one of the two methods, variant or variant 2. The loss actually measured can then be read from a table that takes the set measuring constant into account, e.g. is directly calibrated in the size to be measured.

On the other hand, the direct comparison of GTCOMP to a set value of -gT makes sense if the negative master value -gT is to be read. The fact that a respectively set value of the negative master value -gT can also be read, makes it possible for the measurement of the loss 1 / RVM to be measured in addition to the two preferred variants, execution variant or execution variant 2, to have a third variant, execution variant 3, for determining a loss measured with the measuring circuit can be used. In this variant, the -gT is first compared to the total loss 1 / RVM ^' + (- gT), with the negative conductance beginning approximately at zero, as long as it is gradually increased in the negative direction until a self-oscillation (without to use a feedback amplifier or a third-party supply) Then the negative conductance -gT (of the point of oscillation) is measured in the described manner by means of adjustment by GTCOMP. GTCOMP therefore corresponds to -gT or 1 / RVM including the inherent loss of the coil (rs) transformed as parallel conductance, which is corrected via the table. This embodiment variant3 was briefly described here in order to clarify that such an embodiment of the invention is also covered by the basic claims is covered (see claim 2).

Relative measurement: That a set value of -gT can be read directly via the comparison of GTCOMP is particularly interesting for applications where the total loss (K or 1 / RVM) in which the measuring coil LM is located is not measured but only the measurement of minor additive changes (dK or 1 / dRVM) as a relative measurement to the existing total loss. The total loss corresponds to the offset value l / RVM_Offset, which is reduced with a negative resistance or negative conductance -gT by a corresponding negative loss (-1 / RVM_NEG) to the remaining measuring constant 1 / RVM_Q. The sensor measures the total loss 1 / dRVM + 1 / RVM_Q, with 1 / RVM_Q = l / RVM_Offset + (-1 / RVM_NEG), whereby in l / RVM_Offset, and thus in 1 / RVM_Q, the exemplary scatter of the sensor structure, such as the measurement error caused by the temperature response of the material measured as loss (K) are also included. It should be taken into account that, for example, if the total loss is reduced to 10% (ie 1 / RVM_Q = 0.1 * l / RVM_Offset), a 15% change in the total loss l / RVM_Offset specified by the structure of the sensor application is 150% Change of the reduced offset value 1 / RVM_Q corresponds, and if we go to the desired good of the resonance circuit corresponding offset value 1 / RVM_Q for a full modulation of 1 / dRVM Measure 20% (fill scale) as a relative measurement, a measurement error of 750% related to 1 / dRVM has already been obtained. Why the setting of 1 / RVM_Q takes place automatically, using the negative loss component (-1 / RVM MEG) that can be precisely set or read using a reference resistor or calibration conductance GTCOMP. A distinction is made between two variants, which are to be selected in accordance with the required application or, if necessary, both variants can be used for a sensor via a switchover mode

The setting of the sensor to the value of the operating point 1 / RVM_Q for the measurement of 1 / dRVM takes place either automatically over the entire defined measuring range, e.g. if the starting point 1 / RVM_Q is based on a low-frequency total loss or RV / offset as a DC component via readjustment of (-1 / RVM__NEG) so that the loss l / d ~ RVM can be optimally measured as a pulse or high frequent signal in a dynamic relative measurement, without any drift of l / RVM_Offset or 1 / RVM_Q special measures had to be taken. Or the setting of the sensor to the value of the operating point 1 / RVM_Q for the measurement of 1 / dRVM is for a readjustment of (-1 / RVM_NEG) by a comparison sensor (cf. LT, CT) which also measures the temperature influence as a loss, or provides a minute end or subtrahend of a difference measurement. We want to call this variant a static relative measurement

In comparison with conventional terms from amplifier technology, the relative measurement is best comparable to a small signal coupling of a DC-coupled summing amplifier, the small signal having a much higher equal component than zero point and the zero point position being set by a negative signal corresponding to this direct component and fed to the summing amplifier. The difference between dynamic and static relative measurement is that the control variable used to set the zero position of the small signal in dynamic relative measurement is decoded directly from the Kletnsignal (l / d ~ RVM), especially from the envelope curve corresponding to the degree of amplification of the small signal, comparable to dynamic compressors and automatic gain control. In contrast, in the case of static relative measurement, the zero position is set by an immediate difference signal, in the present case in particular by a further sensor (1 / dRVM), which stabilizes the zero position of the clamp signal sensed by the first sensor against third flows. Or the difference signal of two sensors can also be sampled directly. In contrast to this comparison from amplifier technology, we do not primarily measure amplitudes such as voltages or currents with the sensors, but rather we measure or determine losses directly, regardless of the degree of amplification of the voltages or currents occurring at the measured loss. Thus the clamp signal is a loss (l / d ~ RVM or 1 / dRVM), and the negative summand used to set the zero position of the clamp signal is a corresponding loss (-1 / RVM_NEG)

Dynamic relative measurement: The offset value l / RVM_Offset given by the physical measurement setup of the sensor is reduced by the steepening of the negative loss component (-1 / RVM_NEG) to such an extent that an operating point 1 / RVM_Q is set for which the dynamic loss change size l / d ~ RVM can be measured in the desired amplitude range (us *) of the resonant circuit with a desired degree of amplification. This operating point can also be set, for example, in an automatic calibration step if necessary. Depending on the application, the self-test characteristic of the sensor can also be used to do this (see also cited DE 42 40 739 C2) in order to increase the dynamic loss cycle size l / d ~ RVM by varying the value of a controllable (BD) loss Rp connected to the resonant circuit simulate as if it occurred at the measuring point (K) (see also Fig.l). This procedure is expedient if the expected loss measurement l / d ~ RVM is to be pre-calibrated to a certain input sensitivity without a dynamically changing loss l / d ~ RVM in question having to be present as a measurement variable coupled in via the measuring coil LM, which is the case, for example, with Switching on or resetting the sensor, or when an external synchronization signal arrives, can take place during the measurements of the loss of l / d ~ RVM coupled in via the measuring coil LM in the manner described (tl, t2 with usl, us2; or ton, toff with uon , uoff) the constant Monitoring the Hull curve usH of the resonant circuit voltage for exceeding a maximum value (REFHJWAX) and a minimum value (REFH_MIN). REFHJVIAX defines the permissible maximum good of the resonant circuit via the permissible maximum amplitude. If this good was exceeded, the bandwidth was reduced to such an extent that the dynamically measured loss l / d ~ RVM can no longer be transmitted, so if REFH_MAX is detected, the negative portion of the loss (-1 / RVM_NEG) must be reduced accordingly until the Hull curve falls below the value of REFH_MAX If the minimum value of the hull curve falls below the value of REFHJVIIN, the sensitivity of the sensor set by operating point 1 / RVM_Q is too low and is increased accordingly by increasing (-1 / RVM_NEG), thus reducing the Hull curve of the resonant circuit voltage again in the measuring range of l / d ~ RVM. Since this regulation takes place via the value of (-1 / RVM_NEG), the change in this value or this value can also be used, if necessary, for a corresponding correction of the measured value l / d ~ RVM. For most applications in which a dynamic Loss to be measured l / d ~ RVM is measured, the evaluation of the relativity of successively obtained values is sufficient If the values are to be recorded absolutely, then the change in sensitivity caused by the change in the operating point via (-1 / RVM_NEG) is for the sampling of l / d ~ RVM to be taken into account, for example, using a table that was created in a learning process on the fully assembled sensor. The negative part of (-1 / RVM_NEG) can be regarded as a drift due to the adjustment of -gT for each loss measurement and are thus directly fed to a table as an input variable in order to determine an output variable corresponding to the temperature influence Maintain it is assumed that the zero point of the dynamically measured loss l / d ~ RVM corresponds to the working point set with (-1 / RVM_NEG). The readjustment of (-1 / RVM_NEG) for the setting or stabilization of the operating point 1 / RVM_Q = l / RVM_Offset + (-1 / RVM_NEG) takes place, for example, with a pre-backward payer, which uses the software of the loss value (-1 / RVM_NEG) controlling microcontroller is implemented accordingly and is controlled via control signals which are appropriately detected by the amphtudy monitoring REFH_MIN or REFH_MAX of the oscillation circuit voltage (us *) depending on whether the amplitude is fallen short of or exceeded. This detection can be carried out using simple comparators, or also via Operational amplifier, whereby the deviation (us * from REFH_MIN or REFHJWAX) then also controls the clock frequency of the forward-back payer, which uses (-1 / RVM_NEG) to control the resonant circuit voltage amphtude (us *) to counteract the deviation (according to the direction of payment) (eg via a VCO circuit, voltage-controlled oscillator circuit) The clock frequency and Sc The step size (from -1 / RVM_NEG) with which the forward / back payer is clocked depends on the application. Via the automatic operating point setting (or gain control) of the sensor, the working point of the dynamic relative measurement can be used for periodic signals (e.g. vibration sensing, structure-borne noise or vibration measurement, etc.) as well as for event measurements (measurement of individual pulses or needle pulse trains with a large duty cycle) , etc.) can also be stabilized.For example, the mean value (summing or determined via low-pass filter) resulting from the oscillation curve sampling of the resonant circuit amphtude us * can also be included, depending on how the application requires it. Another option is for the automatic adjustment of the operating point to use enable signal (eg to switch on / off the payment clocks) Relevant examples are described for Fig. 15 and Fig. 30

Static relative measurement: As already explained, with 1 / dRVM <«l / RVM_Offset, the measurement error of 1 / RVM_Q caused by the drift of the set working point 1 / RVM_Q is particularly large if no compensation has been carried out. As with dynamic relative measurement, the adjustment is in this case , or compensation of the drift via the negative portion (-1 / RVM_NEG) of the total loss. However, the static relative measurement 1 / dRVM differs from the dynamic (l / d ~ RVM) in that the controlled variable for the adjustment of (-1 / RVM_NEG) to compensate for the drift deviation is not from the signal curve of the one measuring the loss 1 / dRVM Sensor resonant circuit is decoded (see REFH_MAX and REFHJVIIN), but a reference loss is measured with another loss measuring resonant circuit, after which the drift of the operating point for the measurement of 1 / dRVM of the first resonant circuit is adjusted by adjusting (-1 / RVM_NEG) Applications is temperature compensation by means of separately provided Sensor coil LT, or sensor resonant circuit LT, CT possible, cf. also the cited DE 42 40 739 C2. With such a compensation, the temperature-dependent conductance of the part (K) measured via the sensor oscillating circuit LM, Cp is measured with a second oscillating circuit LT, CT provided for measuring the temperature dependency, the temperature measuring coil LT being arranged such that over the measuring range , or the range of motion of the approach measurement of the measured part (K) at the temperature measuring coil LT, no distance-related loss change occurs. However, DE 42 40 739 C2 does not make use of evaporation of an offset loss, which is why the temperature compensation described there is sufficient. For the preferred static relative measurement, due to 1 / dRVM <«l / RVMJ3ffset, care must be taken to ensure particularly good synchronization for the two resonant circuits LM.Cp for measuring 1 / dRVM (via LM) and the loss measurement of the temperature response (via LT) corresponding to different resonance frequencies (fm and ft). In order to achieve this synchronization, the following dimensioning is preferred: If other losses of the sensor mounted in the measuring field are switched off (Rp = infinite or GTCOMP = 0, and -gT = 0 or -1 / RVM_NEG = 0), ie only the loss l / RVMJ3ffset of the measuring coil LM, or the loss VR_T detected by the temperature measuring coil LT, including the loss caused by the ohmic coil resistances rs, are each coupled into the resonant circuits as a loss. Care is taken to ensure that the two measuring coils (LM and LT) of the resonant circuits (LM, Cp or LT, CT) have the same ohmic series resistances with the same temperature response and that the loss resistances 1 / coupled into the same material of the measured part (K) RVMJDffset or VR_T are also of the same size and, because they correspond to identical materials, also have the same temperature response. For example, both resonant circuits can have identical coils, the different resonance frequencies being set via the parallel resonant circuit capacitors (Cp, CT). For a certain nominal temperature (e.g. 25 ° C), the working point of the resonance circuit LM, Cp intended for the static relative measurement (1 / dRVM) is set via (-1 / RVM_NEG) by corresponding setting of -gT (1 / RVM_Q), if assumed l / dRVM = 0 for 1 / dRVM <«1 / RVMjDffset. On the resonant circuit LT, CT provided for the measurement of the temperature response, the same loss value is set as a negative loss value component in accordance with the setting made on the resonance circuit LM, Cp. With a stable (-1 / RVMJMEG), both resonance circuits therefore have absolute synchronism. In a significant difference to DE 42 40 739 C2, the temperature compensation of the operating point reduced by a significant loss portion by a negative component (-1 / RVMJ.EG) (1 / RVM_Q = 1 / RVMJDffset + + (-1 / RVMJ EG) Attention should be paid not only to a temperature correction of the result, but above all to a temperature-compensated readjustment of the operating point, using the method already proposed in DE 42 40 739 C2 (cf. claims 6 and 10 there) on the resonant circuit LT, CT, which measures the temperature response, regulates the loss of this resonant circuit constantly, which is done in DE 42 40 739 C2 by comparing the resonant circuit voltage us * with a reference voltage, which is why this measurement is not independent of coupled-in interference voltages to keep the total loss occurring at the resonant circuit constant by the Storsigna according to the invention l independent measuring method replaced. In order to keep the total loss occurring in the temperature measuring resonant circuit (LT, CT) constant, it is not the measuring voltage us * occurring at the resonant circuit that is kept constant as the measured variable indicating the total loss, but rather the method according to the present invention, regardless of the absolute value of the signal amplitude occurring on the resonant circuit. or independently of a corresponding envelope curve, certain total loss is regulated via the manipulated variable BD = (-1 / RVMJMEG) for setting the operating point 1 / RVM_Q. This value (-1 / RVMJMEG) measured via the manipulated variable BD (cf. also FIG. 1) of the resonant circuit (LT, CT) for the temperature response measurement of the operating point setting also becomes the same for the operating point setting of the resonant circuit LM, Cp for the actual loss measurement 1 / dRVM (to LM) used. In other words, based on the total sum loss, the measurement coil LM is used to measure: 1 / dRVM + [1 / RVM_Q] = 1 / dRVM + [1 / RVMJOffset + (-1 / RVMJMEG)]. The expression in square brackets corresponds to the operating point adjusted via (-1 / RVMJNEG). Discussion of accuracy: Since the relationship 1 / RVMJDffset + (-1 / RVMJ EG) set up in the given formula is not necessarily exactly linear due to the circuitry, there is one for highly precise measurements Temperature-dependent linearization is provided by means of a table, which, using the synchronization of the two measuring oscillating circuits (LM, Cp and LT, CT) already established via readjustment of BD = (-1 / RVMJSIEG), requires only a few additional memory locations for storing the temperature correction. The respective manipulated variable (-1 / RVMJJEG = BD from Fig. 1) obtained from the constant control of the loss in the temperature measuring coil is used not only for adjusting the operating point offset value for the resonant circuit measuring the actual loss 1 / dRVM, but also in addition still included as a temperature measurement variable in the linearization table. The linearization table is created by learning on the fully assembled sensor. In order to save storage space, the value assignment is not carried out immediately, but using two tables: a first table, which we want to call the temperature correction table, and the actual value table, in which the physical measured value as a function of the input variable for one of the nominal temperature (e.g. 25 ° C) corresponding temperature value is stored. The input value is the measured value 1 / dRVM, or if not previously normalized by calculation, the value l / dRVM + [1 / RVMJ3] is stored as the read address for reading out the measured physical measured value. By using two separate tables, a value table and a temperature correction table, it is ensured that corresponding correction values for which the correction value is not equal to zero are stored only for those total loss values 1 / dRVM + [1 / RVMJQ] for different temperature ranges. Depending on the application requirements, the correction method can be freely defined, for example, the correction value can be saved as a factor (percentage value, etc.) or as an immediate summation. Value table and temperature correction table are organized as follows: The actual loss measurement sensor (LM, Cp) directly addresses the received measured values 1 / dRVM + [1 / RVM_Q] with the value table which corresponds to the physical measured value corresponding to a nominal temperature (e.g. 25 ° C) reads from the value table.

Table∑: table of values

ADDRESS OUTPUT VALUE (at nominal temperature)

MSB LSB physical measurement quantity of the sensor l / dRVM + [1 / RVM_Q] [OUTPUT]

After increasing linear addressing (ie incremental address advancement), correction data words are listed in the temperature correction table, in which correction values ERROR VALUE associated with the respective output values [OUTPUT] of the value table, certain temperature ranges are stored if they have a correction value not equal to zero, and further , the correction value has not yet been saved within the temperature range (see Table 3). These correction data words are then flanked in each case with the temperature ranges (e.g. Ta, Tb, Tc, Td, .... etc.) or included between the temperature data words representing the temperature ranges, e.g. Ta, Tb, Tc, Td, ... etc., whereby within the temperature correction table passed through a pre-backward counter, the temperature values are arranged according to increasing values. And furthermore, the correction data words included between the temperature values (within the incremental address order) are also arranged according to increasing values of the output values [OUTPUT] of the value table. If necessary, to distinguish between correction data words and temperature data words, a corresponding identifier bit (flag, log.O or log.l) provided in the data word.

Tabe // e3: Temperature correction table

ADDRESS BASE VALUE

Forward back payer Wortl Wort2 Flag continuous

Ta = f (BD = (-1 / RVM JMEG)) 1

[OUTPUT value x] ERROR VALUE xl 0 [OUTPUT value y] ERROR VALUE yl 0 [OUTPUT value z] ERROR VALUE zl 0

.etc.

Tb = f (BD = (-1 / RVM JMEG)) 1

[OUTPUT value v] ERROR VALUE vl 0

[OUTPUT value x] ERROR VALUE x2 0

[OUTPUT value z] ERROR VALUE z2 0

Tc = f (BD = (-1 / RVMJMEG)) 1 etc.

The temperature values Ta, Tb, Tc, etc. correspond to the loss values BD = (-1 / RVMj.EG) measured with LT, CT and are arranged according to increasing values and marked with a bit FLAG = 1 to distinguish them from the correction data words. The values (-1 / RVMJMEG) can be saved or rounded to match the required accuracy with a correspondingly reduced number of bits (MSB LSB + n). For every change of (-1 / RVMJMEG), which is determined by the software of the microcontroller / signal processor used for each measurement of (-1 / RVMJ EG) via the manipulated variable (BD) of the temperature measurement resonant circuit (LT, CT) received, occurs Search of the address payer of the temperature correction table in the direction corresponding to the determined change (when increasing in the upward direction, when reducing in the downward direction) until the next temperature value identified by FLAG = 1 or (-1 / RVMJ ^ IEG) is reached (e.g. Tb) and is read from the temperature correction table for the further decision of the process sequence. The read out temperature value or (-1 / RVMJMEG) is compared with the current value obtained via the measurement of the temperature measuring resonant circuit (LT, CT). If the change indicates that the currently measured change in relation to the old (previous) table value (e.g. Ta) is less than the difference from the old table value (e.g. Ta) to the newly obtained table value (e.g. Tb), then the pointer for the Reading the temperature correction table reset to the old temperature value (eg Ta). If, on the other hand, the change currently measured in relation to the old (previous) table value (e.g. Ta) is greater (or equal) than the difference between the old table value (e.g. Ta) and the newly obtained table value (e.g. Tb), then the new table value becomes the current one Pointer for reading the temperature correction table. Depending on the change in temperature or of (-1 / RVMJ EG) of the temperature resonant circuit (LT, CT), this method can be used in both directions to select the current temperature field in the table. Within the between the respective temperature differences (Tb minus Ta, Tc minus Tb; or vice versa if

The change in the negative direction is decreasing). The correction data words are stored, consisting of a word for the value from the value table for a measurement of the value [OUTPUT] obtained for the actual loss measurement (with resonant circuit LM.Cp) and the correction value ERROR VALUE associated with this value. The address counter of the temperature correction table follows the relevant OUTPUT parameters within the temperature parameters. The same principle applies here as for the follow-up of the basic temperature values. For each change in the value obtained from the sensor (LM, Cp) via the value table, the OUTPUT value stored in the table is read out depending on the direction, and it is determined whether the change relating to the old (previous table value) is greater or smaller than that difference in the table resulting from the old and newly addressed value of OUTPUT, if no, then the pointer for receiving a correction value (ERROR VALUE) is reset to the old (previous table value), if so then the pointer remains for Receipt of a correction value (ERROR VALUE) set to the new value. In principle, instead of the output values OUTPUT of the value table, the losses 1 / dRVM + 1 / RVMJ2 measured with the LM, Cp sensor could also be saved, but more storage space was then required. The tables are created in a learning process according to the state of the art, which is adapted accordingly to the given requirements: The physical sensor detected in the learning process is detected by an appropriate arrangement or device (e.g. spindle or pressure generator, or valves, etc.) Measured variable (e.g. distance measurement, pressure measurement, etc.) correspondingly continuously changed (tuned in the value scale) and with a reference calibration sensor (e.g. pressure sensor when generating pressure, etc.) or directly via the precise display of a calibration adjuster (e.g. spindle rotation during distance calibration, etc.) ) measured in addition to the sensor to be verified. For each increment received (with increasing value change) or decrementing (with decreasing value change) by one resolution step (1 digit) of the measuring scale, the measured value is written into the value table, the addressing of the value table with the loss value 1 measured by the sensor to be calibrated / dRVM + [1 / RVMJ2] is addressed. This calibration procedure is first carried out at the specified nominal temperature (eg 25 °) for the entire measuring scale. The temperature correction table is then created. Initially, only a sample calibrated in a slow calibration process can be created and the temperature loss values obtained when calibrating subsequent samples can be simulated on the basis of this pattern instead of using direct temperature influence by means of corresponding adjustable guide values connected to the resonant circuits, corresponding to the temperature influence, in order to use the calibration method for series production to accelerate. During the calibration process, the temperature grid creation table is described as follows: If the measurement scale for a temperature value offset by one temperature unit (this corresponds to an increment of MSB LSB + n of the value -1 / RVMJMEG, or the manipulated variable BD) is recorded, then the value table is used read whether for this temperature change the output value of the table deviates from an measured reference value beyond an increment, if so then the loss relating to the temperature value measurement (- 1 / RVMJ EG) is saved together with the associated temperature value, if not then there is no saving. The loss relating to the temperature value measurement (-1 / RVMJJEG) is also not saved if the correction value has not changed compared to a previous saving, because corresponding [OUTPUT] / correction value data words only occur within the temperature values if there is a change in the correction value in the course of the calibration curve is necessary in order to save the correction values as redundantly as possible

Both for the dynamic relative measurement described and for the static relative measurement, the regulation of -1 / RVMJMEG can also be carried out with a permanently set negative conductance -gT and additionally parallel conductance Rp + (-gT) in the negative range of this conductance sum. For certain applications, the described compensation method can also be controlled only in the positive control range of BD of the parallel resonant circuit LT, CT used for the temperature compensation measurement.

FIG. 9 illustrates the characteristic curve for an example of a tunnel diode used as negative conductance -gT with the two tangential points PA and PB, in which the differential negative resistance becomes infinite, or conductance becomes zero. Depending on the requirements, the area around PA or PB or the area in between can be selected as the operating point. As we can see, the area around PA has about -25mV / lmA = -25 Ohm, whereas the area around PB has about -100mV / 0.25mA = -400 Ohm, with a maximum power consumption of less than 0.3mW. If, for example, we need a negative parallel conductance of 1 / 10k ohms at the LM circuit coil, then this would only allow a very small modulation range when the tunnel diode was directly connected. In order to obtain a larger modulation range, the tunnel diode is adapted to the parallel resonant circuit via a transformer winding. In the present case with the transmission ratio (square root of 10,000 / 400 = 5) Umax, Umin are the corner stress values of the intended working area

Fig.lOa illustrates a circuit in which the control voltage (UV =) is provided for setting the negative conductance of the tunnel diode via a series resistor RV, which increases the output resistance of the control voltage (UV =) and must be relatively high-impedance, since it is AC parallel to Tunnel diode egt. In order to be able to make RV more low-resistance for a lower power consumption, an HF choke (HF-Dr.) Can be connected in series.

Fig.lOb (on sheet 25) illustrates a circuit that is very well suited for the preferred training implementation as a transputer circuit, in which the preferred tunnel diode circuit is supplied via a received RF frequency. The supply voltage VDT of the tunnel diode is tapped via a loosely coupled winding of the HF supply receiver circuit (HFP) (and correspondingly rectified, DGL). The required high-impedance output resistance is via the leakage inductance of the loose coupling produced lossless by VDT. The exact setting of the current takes place via a load regulation of the supply voltage by a digitally adjustable conductance network, the conductance values of which are graduated in binary, controlled by processor MP, which also controls the corner voltage values of the tunnel diode within the intended working range (umax ... umιn, see also Fig. 9 and Fig.lOa) measures. The internal resistance of the supply voltage VDT, given by the stray inductance, is dimensioned such that with a minimal power radiation into the supply / reception circuit HFP at which the entire circuit is still supposed to work (minimum radiation) and a high-impedance setting of the conductor network, the required negative conductance of the tunnel diode (in the working range of the Point PB) can still be set safely via the manipulated variable of the conductor network. If the power radiation in the HFP supply receiving circuit rises above the rated minimum radiation, then its RF input voltage is blanked out by means of a corresponding transverse regulation (load) by means of a switching transistor until the voltage range of VDT is again within the control range of the conductance network. This is done by a simple analog control circuit, with a reference voltage comparison of the controller output of the operational amplifier directly controlling a transverse transistor for loading the received HF voltage, or, in the case of a particularly high HF frequency, the transverse transistor also regulates the rectified HF voltage for reasons of economy can.

A reference voltage is required for the various voltage and current monitors (see umax, umm, VDT, received HF at the HFP supply receiving circuit, constant current supply IK for the excitation supply of the measuring resonant circuit). To generate this reference voltage with the lowest possible power loss, the reference voltage diode must be operated in pulses provided with sampling of the reference voltage after each sample &. Hold principle

For a circuit variant in which the inductance of the supply reception circuit HFP is realized, for example, by means of a conductor spiral printed on the carrier foil, the loose coupling of the second coil for the voltage decoupling from VDT is realized by arranging this coil on the other side in mirror image to the reception coil of the supply reception circuit HFP. The coupling factor is determined by the thickness of the film and a slight misalignment of the conductor track within the distance of the spiral, ditto also by the frequency. Germanium diodes with a low threshold voltage are provided as rectifiers for the HFP supply circuit as well as for the loosely coupled coil for the generation of VDT. Furthermore, a vaporization resistor that can be switched on by a switching transistor is also provided on the supply / receive circuit HFP in order to keep the supply voltage of the entire circuit reasonably stable. In order to get by with the lowest possible power consumption, a power management switchover (PUS) is connected immediately after the supply reception circuit. This switchover alternately switches the supply voltage between two basic circuit units: a supply unit, which relates to the loss measuring device (LM, Cp), Rp, BW, with the tunnel diode circuit and the microcontroller MP, including any reception circuit (RS) which may be present for receiving a via HF-transmitted data signal The second supply unit only relates to the transmission circuit (SE) for sending the measured sensor data, or possibly further protocol data such as sensor addresses, acknowledgment of readiness, etc. This transmission circuit also contains a serial interface receive register capacitively coupled to the microcontroller, in which the Microcontroller MP stores the transmission data before it is switched to standby mode or switched off by the power management switchover (PUS). Whereby this receive register assigned to the transmission circuit can also temporarily store and read back internal data and has a permanently connected supply voltage. The flip-flop controlled power management switchover has two control inputs (set or reset): one that is controlled by the microcontroller (set) for switching on the supply voltage of the transmission circuit, while simultaneously switching off the first supply unit for loss measurement (including microcontroller), and a further input (reset) which causes the supply voltage of the microcontroller and the loss measurement to be switched on again while the transmission circuit is switched off at the same time. A reset control signal is sent from the transmission circuit to the Power management switchover given when the transmission of a data block is finished, with a pause timer optionally being provided in order to insert a standby time in order to save power. The switching on of the supply voltage to the microcontroller caused by the reset control signal brings about an switching reset function, whereby when using a small microcontroller without an interrupt, the microcontroller stores its program address to be jumped after a reset in an external register, for example the serial register of the transmission circuit which is constantly supplied with voltage, back, which he had written into the register before switching off his supply voltage or switching to stand-by mode via the power management switchover. This address, read back in this way, is compared in the microcontroller as to whether it has a valid jump position for the program continuation, if not, the program then begins at its actual starting position. This prevents the program from crashing if there is no valid start address for a corresponding program part after the reset (reset) of the microcontroller. After a reset, the microcontroller initializes the connection of the supply voltage to the loss sensor including the described operating point setting of the tunnel diode and carries out the described measurements ( Adjustment of -gT, then carry out the measuring steps tl, t2 etc.) until the switchover to the transmission of the measured values takes place, etc

Another special feature is how the tunnel diode is driven into the work area (PB) every time the supply voltage VDT is switched on, controlled by the microcontroller (MP). It is assumed that the leakage inductance of the supply coil from VDT of the supply reception circuit HFP is dimensioned such that the tunnel diode can hold the operating point with minimal power radiation in the supply reception circuit HFP. For this, the source VDT must be able to supply a current of 0.7mA (0.33mW) at around 0.47V. When switched on, however, 0.33mW also corresponded to 4.1mA * 0.08V, ie this would result in an operating point (PP) in the positive resistance range of the tunnel diode. To get from this point to the working point PB, at least 0.2V * 2.5mA = 0.5mW is required. Another aspect is that the tunnel diode must be protected in general, for example by dimensioning the circuit (possibly with an additional series resistor) so that at VDT of 0.6V generally no more than 1 to 2mA can flow. The preferred supply circuit of the tunnel diode also has a series inductance (L1), which increases the parallel loss resistance, which is given by the internal resistance of the leakage inductance for the supply VDT and the load control of the digital conductance network. This inductance is also preferably used to generate the power or current required to approach the operating point each time the supply voltage VDT is switched on again. For this purpose, a cut-off transistor HSLI is provided for VDT and a free-wheeling diode D is also provided for the current path: tunnel diode and series inductance (Ll), which is used to switch VDT off for a short time (e.g. if the operating point PP is in the linear positive part) the induction voltage of the Seneninduktivitat (or also the coupling coil LS for the Schwmgkreisekoppelung to LM, Cp) resulting current increase results in the operating point setting in PB. So that the tunnel diode is not overloaded or destroyed by overshoot in an excessively high current range, several measures are provided: 1 The rising edge for the short-term shutdown of the supply voltage VDT is dimensioned so that in the 0.6V range of the tunnel diode the current is generally not up to Destruction limit of the diode can rise, 2. Control areas are provided by voltage comparator monitoring (of umin, umax) of the characteristic curve in order to be able to limit the current through the conductance network controlled by the microcontroller. Doing so. For example, with umin via a time query of how long it takes to reach umin, a first limitation step is initiated with a corresponding master value setting, umax corresponds to the final limitation at which regulation via the master value network starts hard. After the operating point between umax and umin has been set, the two corner points umax and umin are used during the setting procedure to set a defined negative conductance -gT to prevent the negative range between umax and umin from being left out. For example, if a measuring method is used in which the tunnel diode can be connected to a plurality of taps of the coupling coil LS by means of switching transistors for a selection of the measuring range. After the operating point PB has approximately been reached via the voltage measurement umax, umin, the adjustment method can be started in accordance with the described compensation measurement for the setting of the exact negative conductance -gT of the tunnel diode. In order to subsequently initiate the actual measuring procedure for determining the loss value with this value, the negative conductance -gT must be kept stable. For this purpose, further training is provided, in the adjustment process, in which the current setting for the exact adjustment of the negative conductivity value -gT is made by regulating the voltage drop at the leakage inductance at the supply receiving circuit HFP (by load adjustment of a conductance network), to the last setting at which the adjustment point -gT = GTCOMP is reached, the corresponding supply voltage (VDT) of the tunnel diode circuit can be saved with a sample and hold circuit. This stored value is then used during the subsequent implementation of the actual measuring method for the readjustment in order to keep the tunnel diode voltage VDT constant in order to maintain the negative resistance -gT = GTCOMP. Since a step-by-step two-point control by the microcontroller (MP) is sufficient for this purpose, the voltage value stored via sample and hold is fed as a reference voltage to a comparator, which compares this voltage with the current supply voltage VDT as long as the measurement procedure for loss determination is carried out. The output signal of the comparator is fed to the microcontroller, which continuously polls it and performs a gradual adjustment to compensate for the deviation using the binary graded master value network. The master value network controlled by the microcontroller is therefore used twice, once to find out the voltage or current value point of the tunnel diode, in which the deviation -gT = GTCOMP is given, and then to hold the voltage or current value point of the tunnel diode during the actual measurement of the loss. For storing VDT, a sample and hold was used to get by with the lowest possible power, alternatively, of course an A / D converter for the signal conversion with subsequent feeding of the value into the microcontroller can also be used, wherein several sample & hold functions can also be combined using a corresponding input multiplexer of the A / D converter

In order to achieve a linear alignment characteristic as possible, the step size of the digital tail network, which is in each case decisive for a linear step for adjusting the negative loss -gT of the tunnel diode, is stored in a table in the microcontroller after carrying out the measurement method for determining the loss via the fundamental Measuring steps tl and t2, for example after execution variant or version 2 with the supply voltage VDT of the tunnel diode held, the process for re-adjusting -gT is resumed in order to obtain a new value for VDT, and measuring steps tl and t2 then follow again for this new VDT value , etc., constantly alternating between readjusting -gT and performing the measuring steps tl and t2 for the respective determination of the loss 1 / RVM to be measured

Other special features of the circuit (option): The externally supplied resonant circuit LM, Cp used for the loss measurement uses a readjustment of the feed frequency if necessary, whereby the resonant circuit is kept exactly on resonance. This readjustment is carried out by measuring the current-phase relationship (with resonance = 0 °) via a current decoupling resistor connected in series with the measuring coil (which is equally vaporized via -gT). In this context, it should be pointed out that the principle of exact evaporation described in FIG. 8 of a parallel resonant circuit LM, Cp (or an equivalent filter, band filter, etc.) can also be used for the evaporation of losses caused by the capacitance Not only can particularly sensitive moisture measuring sensors be constructed according to this principle, it also facilitates the construction of resonant circuits with high quality using capacitance cascades switched (e.g. binary graded) with switching transistors (e.g. FET) in order to also achieve resonance frequencies in the lower frequency range (as an alternative to one usual capacitance diode) on the resonant circuit In the exemplary embodiment according to FIG. 10b, the external supply takes place by means of a corresponding polarity reversal signal which alternately connects a negative or positive constant current source to the parallel resonant circuit in accordance with the polarity reversal polarity.

The example described illustrates how optimally the sensor according to the invention can be implemented in the most diverse application areas with extremely low power consumption. For example, with a single chip, which alternatively provides a further oscillator with which the HF supply receiving circuit (HFP) can be fed by an external connection, ie serial data inputs and outputs are present via external connections, both a multiplicity of Transputer sensor applications are covered as well as sensor applications networked via cable connection. Furthermore, the circuit is well suited to simultaneously carry out data communication via the HF supply receiving circuit (HFP). Details for this are further described in the chapter "Additions to the Transputer Application Variant"

Fig.ll illustrates an application example for a highly accurate measurement of a dynamically changing loss quantity l / d ~ RVM (cf. dynamic relative measurement according to Fig. 8) of a wheel or tire monitoring for a rail wheel, for example for a train. The sensor attached to the wheel suspension by means of a corresponding mounting bracket, with its measuring coil LM, scans the outside of the wheel tire, which can be mounted, or can also be made of the same material as the wheel, directly above the tire that is brought forward to the wheel, not the absolute distance is measured. but only the change of the distance over one wheel revolution. If one assumes that the tire also has a homogeneous inner diameter on the inside, then the described process automatically adjusts the offset value of the loss via the negative loss component - 1 / RVMJMEG (coupled in via -gT) until it is conditioned by the surface roughness or Manufacturing tolerances these tolerances occur as dynamically changing loss size l / d ~ RVM. However, the loss 1 / RVM_Q for the operating point setting must not be regulated below a value that the good of the parallel resonant circuit becomes so large, or even becomes infinite or negative, that the resonant circuit oscillates independently or its bandwidth for the transmission of the dynamically changing loss magnitude to be sampled l / d ~ RVM is no longer sufficient. Why the negative component -1 / RVMJNIEG, which is set with -gT or with (-gT + Rp), is limited to a corresponding basic value in order to guarantee a minimum positive value for 1 / RVMJQ, which is the maximum permissible good of the measuring oscillating circuit LM, Cp limited If a dynamically changing loss size l / d ~ RVM is detected due to a spontaneous irregularity of the wheel tire diameter measured on the inside, then a spontaneous crack in the material can be concluded. Furthermore, a mode is preferred in which the readjustment process of the operating point setting 1 / RVM_Q is synchronized with the angular rotation of the wheel (from 0 ° to 360 °), in such a way that the maximum modulation amplitude of the envelope curve of the resonant circuit voltage us * is fixed at a certain angle. This angle starts at 0 ° after each wheel rotation offset by a segment unit (eg in raster units by 10 °), but the adjustment is not to the maximum Duty control amphtude, but only to a fraction, e.g. 30%, thus based on a specified angle value, fluctuations of 300% with a measuring range from 10% to 100% of l / d ~ RVM can be measured, or even above prevailing fluctuations (due to overloading of the resonant circuit) are still recognized. The fraction for the determination of the maximum modulation amphtude when comparing l / RVMJJ in the standard mode can be determined by determining the ratio of maximum to minimum amplitude of the envelope of the resonance voltage us * for a full wheel revolution, with a corresponding stepwise shift of the working point 1 / RVMJ5 This example illustrates that for the described method for sampling a dynamically changing loss size l / d ~ RVM, the loss size does not necessarily have to be a periodically changing size, but that these are also spontaneous individual pulses of loss fluctuations l / d ~ RVM can act. It is evident that the described method for scanning the concentricity of each cylinder wall of a wheel cylinder, ditto also an end-side scanning of the wheel can be carried out in order to determine irregularities. Furthermore, this monitoring also includes the timely determination of whether a wheel bearing is defective this sensor too (at Corresponding setting of operating point 1 / RVMJ3) the scanning of vibrations or coping noise, etc. can be carried out. For the described exemplary embodiment of scanning the concentricity of a rail wheel, the sensor is absolutely temperature stable due to the constant readjustment and the resolution is fully usable up to the noise limit. In this way, even the load-dependent deformation of the rail wheel can be recognized. It is evident that a sensor, which is arranged in the vertical plumb line (vert) below the axis and which scans the wheel tire, scans the minimum inner radius of the tire, or a sensor which scans the axis or in the vertical plumb line, which passes through the axis (Horiz) is arranged and the wheel tire scans the maximum inner radius of the tire. In principle, a steel tire on a rail wheel is deformed in the same way as a rubber tire (of course to a much lesser extent). The deformation corresponds to the ratio of the maximum to the minimum inside diameter of the tire during a respective rotation of the rail wheel. The extent of the deformation depends on the modulus of elasticity of the material and the load. As with a rubber tire, the steel tire of a rail wheel can only be loaded up to a certain speed, depending on how quickly the material shifts that occur in the steel tire can follow its deformation during wheel rotation. With a pair of sensors arranged in a vertical vertical axis (vert) and horizontal vertical axis (horiz), the extent of the deformation as well as its temporal course can be measured in each case during a wheel revolution. If there are any special deviations, the deformation is inhomogeneous and the wheel or bearing is at risk. Furthermore, the squeaking noise that is usually present on older wheels or rails can also be sampled as a vibration corresponding to the structure-borne noise of the wheel. The evaporation of the sensor through the negative loss component with the automatic drift readjustment of the operating point makes this possible.

Fig. L2a, b concern, for example, application examples for the compensated good attitude 1 / RVM_Q = 1 / RVMjDffset + (-1 / RVMJMEG) described for Fig. 8 for measuring a static loss change 1 / dRVM which is slight compared to the set offset value and which corresponds to Fig. 8 has described temperature compensation (cf. static relative measurement). Fig.12a shows a screw, Fig.12b shows a nut, both have the property that they allow measurement in the preferred transponder embodiment of the sensor, which shows how tight the screw connection is, any amount of such screw connections can be Monitoring center can be networked wirelessly via the transponder connection, or also via the inductive coupling described for Fig. 43 by means of an induction cable.

The loss l / RVMJ3ffset given by the construction of the sensor is correspondingly high, since the metal screw or nut goes directly through the center of the sensor coil LM. On the other hand, the elastic deflection of the washer, which is dependent on the tightening strength of the screw connection, is very low via a very massive washer (each for screw head and nut), which is measured as a loss quantity 1 / dRVM that changes only to a small extent. The resilient washer is set a little lower on the outer edge, the outer edge of the washer on the fastening part, which is held by the screw connection, firmly pressed flat on the fastening point, and does not rest resiliently and only the center of the washer has a slight spring travel, around which the The distance between the screw head or nut and the fastening part changes depending on the tightening strength of the screw connection. In the case of a static measurement, which uses a direct assignment of the tightening strength of the screw connection to the deflection of the washer, the temperature profile caused by the material of the screw connection including the washer must also be used

become. What can be done by a second sensor coil (LT), which scans the screw head or the nut at the non-hanging end at a fixed distance, cf. also the cited DE 42 40 739 C2. The specific conductivity of the washer used has the same temperature coefficient as the screw connection (or nut and head). In order to be able to measure the small measured variable 1 / dRVM, the large loss 1 / RVMJDffset caused by the screw is evaporated in the manner described in Fig. 8 with (-1 / RVMJ EG) (set with -gT, whereby -gT variable or (-gT + Rp), where Rp variable Thus 1 / RVM Dffset is reduced to the value 1 / RVM_Q

Another possibility, which does not require temperature response compensation, is to measure the measurement of a dynamic changing loss size l / d ~ RVM, as described for Fig. 11, instead of a static measurement of 1 / dRVM, as occurs when the screw connection vibrates. By appropriate evaluation of the vibration signals picked up by the preferred sensor on the screw and on the nut (caused by a slight change in distance to the sensor corresponding to the vibration of the washer), e.g. by a phase comparison of the vibration tapped at the screw head with the vibration tapped at the screw nut (or also Fouπer analysis, etc.), the strength of the screw connection can be determined using the preferred sensor using a method known in the prior art

Fig. 13 shows an application for measuring the respective load on a shock absorber spring (FSP). Here, too, the loss given by the construction of the sensor is correspondingly high.Unlike spring travel sensors which measure the spring directly as a coil in a resonance circuit, this principle not only because of the extraordinary sensitivity to interference within the bandwidth of the Resonant circuit frequencies is unusable, but also the heavy steel spring had to be isolated at least on one side (at a load of a few tons>). the sensor according to the invention can be excellently integrated into existing shock absorber designs. The outer steel spring (FSP) of the shock absorber forms the loss 1 / dRVM to be measured for a measuring coil (LM) placed on the core Kover of the shock absorber (telescopic rod) at an appropriate air gap distance. However, since it is located outside the measuring coil LM, the loss 1 / dRVM in relation to the loss of the shock absorber core Kover pushed through the center of the measuring sphere (at an air gap distance dx), it is considerably small cf. 1 / dRVM «1 / RVM_Q, whereby 1 / RVM_Q is part of the loss 1 / RVMJNff) evaporated with (-1 / RVM_NEG) is. Thus 1 / RVMJDffset corresponds to the loss of the shock absorber core Kover present in the center of the coil

As already explained for Fig. 8 for the temperature compensation described, the sensor has two measuring coils LM and LT, each in an oscillating circuit (LM, Cp or LT, CT) with different resonance frequencies but identical resonance loss resistances (at nominal temperature Tm and l / dRVM = 0) are switched. The measuring coil used for the temperature measurement is attached underneath the (lower) support plate (TELL), where the steel spring (FSP) is supported or mounted.As with the measuring coil LM, 1 / dRVM is used for measuring the loss galvanization caused by the spring compression , the temperature measuring coil LT for measuring a loss-related temperature response (see VRJT, text for Fιg.8, Fιg.8_T) is pushed onto the shock absorber core (telescopic rod) in a corresponding air gap distance (dx). The specific conductivity of the support plate (TELL) and the steel spring ( FSP) each have the same temperature response, thus the temperature response of the steel spring (FSP) is also recorded via the loss of the support plate (TELL) Since the temperature measuring coil LT below the support plate (TELL), on which the steel spring is immovably fixed, measures the loss VRJT , this loss is independent of the respective compression of the steel spring (FSP) mounted above the nozzle divider (TELL) it support plate (TELL) equally on the shock absorber core (telescopic rod) in a corresponding air gap distance (dx) measuring coil (LM) measures the loss 1 / dRVM of the steel spring movement in such a way that when the steel spring (TELL) is compressed, more electrically conductive volume or material in the field line area surrounding the measuring coil on the outside than when the spring is released. That is, when the spring is compressed, the measured loss 1 / dRVM is increased accordingly, when the spring is released, it is unproblematic that the change in the loss of 1 / dRVM with respect to the loss l / RVMJ3ffset (including 1 / dRVM) generated by the shock absorber core located in the center of the coil is only very small. since 1 / RVMJDffset is reduced by the negative component (-1 / RVMJ4EG), set with -gT, to an arbitrarily adjustable value 1 / RVMJ3 (see Fig. 8). The same also applies to the resonant circuit of the temperature measuring coil (LT) with the loss resistances (or nominal temperature Tm and l / dRVM = 0) for the same resonance care must be taken that the two resonant circuits (LM, cp and LT, CT) have the same resonance even without negative evaporation, ie with 1 / RVMJMEG = 0, the assumption of l / dRVM = 0 corresponds to a certain travel position, in which the the loss coupled into the measuring coil LM by the steel spring is approximately equal to the loss coupled into the measuring coil LT by the support plate, assuming approximately the same losses present inside the coils due to the telescopic rod of the shock absorber pushed through the coils (with air gap x) (possible dimensioning adjustment) the differences due to appropriate air gap adjustment x by appropriate selection of the inner diameter of the coil). This optimal synchronism condition ensures that the calibration process of the table carried out by learning (cf. also text for Fig. 8_T) requires as little storage space as possible for the error correction of the synchronism deviation of the two resonance circuits (LM, Cρ or LT, CT). If the resonance loss resistances at nominal temperature Tm and l / dRVM = 0, and further assumed 1 / RVM_NEG = 0, do not exactly match, then more memory locations are required for the synchronization correction

In addition to the good applicability for shock absorbers and scales, the described sensor can on the one hand measure the load absolutely, on the other hand this sensor arrangement is ideally suited to perform differential sensor measurements in which the different shock absorber loads between the shock absorbers on the right and left side are measured during cornering , so a good statement about the centrifugal force can be made, for example hydraulically controlled suspension travel harder to control with higher centrifugal force Or to provide such a differential measurement on railway wagons or trailer undercarriages in order to register excessive cornering speeds and overloaded containers while driving.

Another application is the path detection on telescopic headers controlled by linear motors.

Fig. 14 shows the scanning of a leaf spring as an example.

Fig. 15 relates to a further application of the sensor for the railway area, in which the sensor is used at a very short distance from the rail for scanning railway tracks. The sensor perfectly meets the high requirements against interference radiation, since the rail compensation currents form huge electromagnetic fields that are scattered into the sensor coil that is open on the scanning side. The purpose of this application is to scan the rail profile for lateral displacement (x) as well as for changing the altitude (y). For this purpose, sensor holders are inserted into the ground of the rail body on the outside of the rail professional in corresponding route sections, this holder forming the reference point for a two-dimensionally oriented distance measurement of the sensor head from the rail profile. The sensor head measures with two sensor coils LMx, Lmy (of the measuring resonance circuits LMx, Cpx and Lmy, Cpy) decoupled from each other by different resonance frequencies (fx, fy) in the horizontal and vertical coordinate direction. The LMx scanning end face is aligned parallel to the vertical rail profile part, engaging laterally in the profile at a short distance from the rail wall, the LMy scanning end face is parallel to the lower rail lying horizontally on the track body (or the sleepers Holzern) Profile part (rail support surface) aligned at a short distance from the inside of the rail support surface. Both sensor coils LMx, Lmy are housed in a common holding head, which is held by a horizontal holder tube which engages in the projecting rail profile from the outside. In its horizontal orientation, the holding tube is rotatably attached to a bolt that is anchored vertically in the ground, where it can be plugged onto the bolt from above via the swivel joint. The pivot bearing serves the purpose that first the bolts can be fixed vertically in the ground, then the horizontal holding tube of the sensor head can be attached to the pivot joint for each bolt and swiveled into the lateral cavity of the rail profile on the outside of the rail, and then the pivot joint can be fixed against rotation can be. The sensors are designed in the transputer version, whereby the voltage supply via an HF feed into the contact wire and the Data communication via radio or, for example, via the inductive coupling described in FIG. 43 can be carried out by means of an induction cable

The sensors arranged in corresponding sections over the rail section serve the following purpose: The sensor (LMx), which scans the rail in the horizontal (x) direction, measures the displacement of the rail that yields laterally due to the tensile load, in particular caused by the centrifugal force in curves. The sensor (LMy), which scans the rail from the inside of its support surface in the vertical (y) direction from above, measures the movement of the rail, which is resiliently resilient due to the tensile load. Instead of the older rail brackets, modern spring steel wires (brackets) can be well monitored in their mode of operation, in particular whether the rails are held with equally distributed fastening forces.

All sensors are networked to a central evaluation device, which means that the following statements can be made while the train is traveling a route: The load resistance of the track body is constantly monitored, whereby an exact statement can be made as to which trains can travel a route at which speed without the Track bodies or safety at risk - damage to the railroad body caused by unstable displacements in the ground can be recognized in good time, acts of sabotage are indicated in good time and newly built railroad bodies are immediately localized, especially sensitive high-speed lines, and can be diagnosed immediately over the entire route; The influence of poorly maintained trains, especially freight trains (due to defective wheel bearings, etc.), which is harmful to the track body, can also be recognized and logged by the sensor system. Using a dynamic measuring system with automatic readjustment of the working point 1 / RVMJ3, as already described in detail for Fig.lla, the distance measurement (via loss measurement l / d ~ RVM) can detect rail movements down to the nm (nanometer) range. The system is suitable Not only for classic rail operations, but above all for sensory "feed back" support for modern tilting technology. Temperature compensation: Both variants, dynamic relative measurement or static relative measurement, can be used for the use of equal path scanning. A static temperature measurement requires a corresponding temperature measurement sensor with its sensor coil (LT) simply mounted at a fixed distance from the rail wall, e.g. welded or mounted to the rail on the upper side of the lower contact surface of the rail. The measured values corresponding to the temperature compensation can also be transmitted to the sensor via the data interface sor (LM, Cp), which measures the actual loss (1 / RVM) are transmitted In a dynamic relative measurement, a control signal is provided for constant readjustment of the operating point (enabie signal), which automatically sets the operating point while a train is passing switches off, otherwise permanently activated So the temperature adjustment is only switched off for the short duration of the track scanning during the train journey. The detection of when a train is passing by, for example, is carried out by additional sensors which sense the wheels of the train with a relatively high loss fluctuation (e.g. also in a dynamic relative measurement), which is much larger than the sensitive absolute relative measurement of the track movement

Fig. 16 shows in addition to Fig. L5

Expansion with networking of sensors that sense the wheels of the train on the rail. The addition of such sensors not only helps to avoid train accidents, but also enables the location of a train where possibly derailed, which is caused by the interruption of the otherwise at regular intervals incoming impulses (for each loss measurement of a wheel), the communication can take place via the neighboring sensors directly to the control center, or directly by train, or via an induction cable directly to the control center (in party ne mode)

In addition to Fig. 15, Fig. 17 shows the expansion with networking of sensors that monitor the function of a switch. However, the loss measurement sensor is mounted on the inside of the rail below the rolling area of the wheels on the track body or the rail

Fig. 18 shows an example of a pressure cell, consisting of a tube provided with resilient beads. The diameters of the beads are parallel to the tube cross-section and geoen the tube thus has a resilient property in the axial direction for an elongation of the tube. The tube is closed at one end of the tube, the axial movement of this tube end being sensed by the loss measuring coil LM of the preferred sensor. This front end of the corrugated tube is made of the same material as the tube in order to enable the preferred temperature compensation. This measuring coil is inserted on the inside into another holding tube and held by it. The holding tube (as the housing of the pressure sensor) is loosely pushed over the beaded tube and held in front of the beading by a widening made on the beading tube, so that the beads are freely movable, and in the event of a crack in the beads, the retaining tube Protects pressure sensor against exploding The other, smooth end of the bead tube (without beads) has the pressure inlet. For example, a thread for fastening. Thus, the pressure causing the longitudinal expansion of the corrugated tube is the differential pressure to the pressure prevailing on the outside of the corrugated tube. If this outside is open to the air pressure hm, the differential pressure is measured to the air pressure, if it is closed, the differential pressure to the inside pressure of the housing. These two variants are common for pressure gauges. The temperature measuring coil LT is pushed over the beading tube in front of the beading attachment, so that the sock tube with its smooth cylinder wall part passes through the center of the temperature measuring coil. For the selected working point, the synchronous adjustment of the temperature measuring coil LT and loss measuring coil LM takes place in such a way that the loss values of the beading tube that are coupled in (for LM on the end face of the corrugated tube, or for LT on the cylinder outer wall) for both coils LM, LT are the same. See the explanations given for Fig. 8, in the chapter "static relative measurement" for temperature compensation. The synchronism setting of the with different resonance frequencies Operated coils (LM, LT) is done by adjusting the coupling to the corrugated tube (front for LM, or distance of the inner diameter from LT to the tube wall.) For applications in which the temperature profile of the tube decreases from the screw-in end, the temperature measuring coil LT is on one leaves nong smooth end of the corrugated tube (without corrugations) directly in the vicinity of the end face on the corrugated tube, firmly arranged (cf. Fig.lβb). Instructions for the calibration of the sensor: In addition to the possibility of directly calibrating each sensor manufactured directly with a reference pressure meter when the pressure scale has been passed, it is intended to ensure good reproducibility of the rolled-in beads during manufacture, so that the pressure is only for one copy through a learning process must be calibrated, the length extension being recorded as a function of the pressure value. For a quick calibration of the other specimens, it is then sufficient to move a bolt, e.g. via a measuring spindle or pneumatically through the inlet opening of the corrugated tube, which presses on the closed end of the corrugated tube and which extends with its threaded flange into a corresponding device , A corresponding length measuring system is provided for the bolt displacement. For example, one working according to the principle of the invention, in which a conical bolt is pushed through a sensor coil. (This length measuring system was then also calibrated with a precision spindle). Since the measuring principle also allows a very high measuring frequency due to its evaporation due to a negative resistance or conductance, very rapid pressure fluctuations can also be simulated by pneumatically actuating the bolt. Such a pressure sensor can, for example, be screwed into the cylinder head of an internal combustion engine similarly to a spark plug, in order to monitor the play of the valves in relation to the crankshaft rotation by means of rapid pressure recording, or to read further engine parameters resulting from the pressure distribution of the various clock phases, such as efficiency, Burning time of the fuel, etc

For the sake of completeness, the manufacture of the corrugated tube should also be briefly described: the tube is clamped in a rotation device (for example a clamping device of a lathe), a mandrel engaging on the front of the tube, cf. Fig.lδc. This mandrel consists (seen in cross section) of three identical segments (a 120 ° division), with a gap (ZWI) being provided with respect to the segments (sym_120 °) of the segments, which means that the mandrel has a corresponding diameter when the gap is pressed together can be reduced. The mandrel is held at its maximum diameter, with appropriate gaps (ZWI), by a central bore into which a centering bolt (ZB) is inserted, which, for example, still presses the central bore apart at its ends according to the principle of a collet, whereby the cylinder outer wall of the dome divided into three segments is firmly pressed apart on the inner wall of the tube to be provided with beads. The outer wall of the dome of the dome has grooves of the shape (waviness) of the beads, which fit into the outer wall of the sock tube to be processed with a corresponding device with a corresponding Device to be printed. This device attacks from the outside with three (in relation to the cross section) staggered by 120 ° rows of rollers (ADRL), which impress the tube wall from the outside during the rotation of the tube. The rollers are arranged exactly congruent to the grooves of the outer wall of the Zyhnder of the dome inserted into the tube, so that the beads can be rolled in precisely. It can be cold rolled, or hot rolled in a microwave oven, for example. Subsequently, the tube provided with beads is correspondingly further processed (thread attachment, etc.) and hard-sealed and sealed. It is provided that the closure side is closed by pressing in or via a threaded cap provided with a seal.

Fig. 19 shows the exemplary embodiment of a torque sensor, consisting of a shaft and a sleeve pushed over the shaft, rotatably mounted against the shaft with inserted ball bearings, the shaft being the first connection shaft end and the sleeve the second connection shaft end of the torque sensor forms. The torque is transmitted between the shaft and sleeve by means of a plate spring inserted into the shaft, which engages in a guide slot in the sleeve and is held in the slot by ball bearings centered by spring force. For a cheaper version, instead of the flat spring, a hard steel pin can engage in a rubber-covered guide slot. The rotation of the shaft against the spring force is measured, based on the sleeve that also rotates with the shaft. The sleeve itself is e.g. Ball is stabilized in a corresponding housing, the housing must be fastened accordingly when installing the torque sensor (e.g. flange-mounting on a motor or a gearbox). The housing then has the HF transmitter, which feeds the HF signal as the feed signal of the transputer sensor accommodated in the sleeve, the HF reception winding of which is placed on the sleeve (at a corresponding distance from the sleeve wall). The reception winding runs within the HF transmission winding, which is housed inside the front cover of the housing. The data exchange between the transputer sensor and the HF transmitter of the housing can also take place via the HF reception winding on the shaft. The attachment of the sensor coil LM for the measurement of the loss corresponding to the sleeve rotation can be seen from the sectional drawing (Fig. 19): The shaft has a protruding narrow segment (pin ZPF), which within the play provided between the shaft and sleeve, corresponds to the Shaft rotation is moved concentrically and its surface projected to the end face of a sensor coil (LM) accommodated in the wall of the sleeve generates a loss in the sensor coil (LM). The magnitude of the loss depends in each case on the correspondence between the end face area of the coil LM and the projection cross section of the gripping area of the narrow journal (ZPF) given in accordance with the rotation of the shaft. The temperature dependency is measured in the same way, but the shaft (ZPFT) provided for this purpose is designed to be wider, and so wide that when the sleeve is rotated (relative to the shaft), the projected area of the temperature measuring coil (LT ) constantly couples the same loss via the pin (ZPFT). The pin is designed as a correspondingly projecting circular segment of the shaft with a concentric course of motion directed toward the measuring coil LT. The synchronism of the coils (LM, LT) operated with different resonance frequencies is carried out by selecting the appropriate distance between the end face of the measuring coils (LM, LT) which are respectively embedded on the inside of the sleeve so that the coupled loss values are the same for both coils (LM, LT). See the explanations given in Fig. 8 in the chapter "Static Relative Measurement" for temperature compensation. The LM and LT can be wired in such a way that both coils are connected to the same transputer sensor chip. For example, the housing for Fig. 43 , Fιg.36d and Fιg.37 described variant can be attached for networking the sensors by means of an induction cable, the HF transmitter housed in the housing of the torque sensor then being provided with such an interface.

20 shows the example of a clutch play sensor, which is designed electrically according to the principle of FIG. 19. However, since we not only want to measure the clutch play, we also want to monitor whether the clutch actuators are actually exactly flat we use three sensors (LMl, LM2, LM3), which are arranged at an angle of 120 ° to the shaft. On one side of the coupling, the mounting plate of the clutch plate cover has a small hole for each sensor, which is covered by the electrically non-conductive coupling surfaces and through which the sensor can measure to the other mounting plate of the clutch, so we get a distance measurement in which the sensors located behind the mounting plate on one side can measure the distance to the other mounting plate (through the clutch disc lining) by measuring their loss A sensor coil or sensor for temperature measurement (LT2) is attached behind the mounting plate, the loss of which is measured, and behind the mounting plate, on which the loss measurement sensors (LM1, LM2, LM3) each measure through corresponding holes, is also a sensor coil , or sensor for temperature measurement ng (LT1) attached. With this coil LT1, the deviation of the operating point of the loss measurement sensors attached to the same mounting plate is determined by the loss measurement result BD = (-1 / RVMJIEG) obtained by maintaining the loss (at LT1, CT1), see also the chapter relative static measurement to Fig. 8 (LMl, LM2, LM3 each with Cp *) balanced [(1 / RVM_Q = l / RVMJ3ffset + (-1 / RVMJMEGVJ, and so that the resonant circuits of the measuring sensors (with LM1, LM2, LM3) each synchronize for identical loss coupling by the offset value l / RVMJ3ffset corresponding to the loss of the mounting plate to which the sensors are each fastened. On the other hand, the loss value corresponding to the temperature dependence of the other mounting plate (measured via sensor coil LT2 with CT2) is used as the correction value for the table correction of the measured value ( See also text for Fig. 8. Another application based on this principle is the testing of the connection strength of two units screwed sheets, or a part mounted on a sheet, etc. A hole is provided in one of the sheets in question, through which the sensor measures the loss (to the part located behind the hole).

Fig. 21 shows an example of an angular scan, e.g. on a railway wheel. For this purpose, a ring gear is inserted into a standard wheel, which has a slightly wider tooth gap at one point, via which the time gap of the measurement of all adjacent tooth gaps when a value threshold is exceeded, the wider tooth gap is recognized as a reset signal for paying off the tooth gaps. The number of pays for the gaps paid off corresponds to the angle of rotation. It is also provided to interpolate the temporal course of the loss measurement result corresponding to the geometrical shape of a tooth in order to obtain corresponding further values between the teeth. These values are then calibrated by learning. In the railway sector, this sensor has the advantage of simple retrofitting. The braking properties of a wagon can be improved in such a way that during blocking (or even slight blocking), or especially when partially blocking (sliding the wheels on the rails) via the uneven speed (or . Angle of rotation) can be shot at brakes that act differently, and thus the symmetry can be better regulated. Of course, this angle scan is also suitable for the most general use, e.g. as a replacement for the optical disc in ABS systems, etc. The fault signal safe loss measurement is not only absolutely insensitive to dirt, but also much cheaper than the use of optical discs and especially in light accidents, the sensor is absolutely safe to test and for a few $ inexpensive to change quickly, while the optical discs are often not replaced and so often result in an uncontrolled failure of the ABS system. In a motor vehicle application, the tooth profile can e.g. be arranged directly on the inside of the brake rim of a brake disc, this addition then being possible for the embodiment described at the beginning of FIG. 21 (cf. also DE 42 40 739 C2). Here too, the interference signal-insensitive measurement is a great advantage

Fig. 22 shows another component that is already urgently needed in automotive engineering. The absolutely interference-proof measurement of the sensor makes it possible. Fig. 22 relates to the use of the sensor as a wheel attachment detector. The sensor is embedded in the wheel divider, or as an alternative on the holding arm that carries the wheel bearing with the wheel bearing. The direct attachment to the wheel plate has the advantage that the fields on the wheel plate are always at the same points (e.g. 120 ° offset) Using three sensors), on the other hand, when attached to the holding arm, the inside of the fig is constantly rotated past the sensor in the case of unprecise manufacture, a distinction must therefore be made between hitting the rim and inadequate fastening with the wheel bolts. If both variants are provided, then there is good information as to whether the wheel must be specified in the workshop, for example if it was printed on a curb, in order to rule out a later possibility of serious accidents. Respectively. a statement about the wheel bearing can be made via the sensor on the holding arm (if the wheel hits, for example). A further advantage is that the sensor can also immediately trigger an alarm if an illegitimate rim or wheel change takes place, which cannot be detected, for example, by the vehicle's position detectors (when the tire air is removed and deflated). The RF transmitter for the transponder supply is then housed above the shock absorber, for example, which supplies the following sensors or exchanges the data, shock absorber spring motion sensing, temperature compensation of the shock absorber spring measurement, the sensors for the wheel attachment detector, and if necessary, is networked with other monitoring sensors

Fig. 23 illustrates a further interesting field of application of the sensor, which was of particular interest to the large group of customers in the automotive industry, the car rental company. When returning vehicles, it often happens that small parts that are only recognized by the expert as damage are returned upon return of the vehicles are either not recognized or the vehicle renter denies the cause of the damage. The dent sensor built up with the help of the sensor, which is located directly on the inside of the body and from the inside scans the outer wall of the body with a distance measurement or loss measurement) and makes absolute remedies Disturbance signal measures safely (an important argument, so that there are no excuses in court) With such a dent sensor, accident damage that was no longer visible after being installed can also be logged, but a potential buyer can do so via the vehicle's on-board computer Viewing outside of an accident damage, for example, a dent damage that has occurred in the side impact protection, which is not visible to the buyer inside the body. Through these measures, the resale value of a vehicle can be maintained with proof of quality. The proposed measure is therefore also very interesting for leasing companies if a fixed surrender value has been agreed. Furthermore, the proposed measure is able to completely record the course of an accident in order to save, in which time intervals, which body parts were deformed accordingly. The precondition is again absolutely safe to measure, regardless of the possibility of interference (so that there are no excuses in court). The data stored in the event of an accident (for this purpose the sensor according to the invention can also be used to query the steering wheel movement, for example, or the spin behavior by means of a seismographic sensor) are then stored in a tachograph controlled by a welded-in microprocessor inside the bodywork Manipulation can be secured in such a way that the measures proposed in the previous chapter "safety-coded loss measurement sensors" can be applied. The tachograph memory center welded into the body contains a corresponding safety-coded loss measurement sensor which scans the body wall (for example at a relatively safe location on the underbody in the middle). If it is removed from the body wall, this state is also written into the stored data, the data within the tachograph memory are stored in encrypted form, the On Coupling takes place via an RF circuit based on the transputer principle, the RF receiving circuit being protected against overvoltage by diodes connected in parallel on the anti-parallel side. For networking the sensors on the inside of the body, there is again the option of supplying the sensors designed as transputers exclusively with central HF transmitters housed on the inside of the body, furthermore to use a protocol which was described in the previous chapter "Additions to the variant of transputer application" under " Ping signal "method is described, or to provide a variant with an induction cable as a supply and data communication line (cf. also connection component according to FIG. 43 in both cases, a failed sensor can be automatically located immediately via the" ping signal "protocol and via the Central microprocessor are reported as service information. This applies not only to the data communication area, but also to the 100% self-test capability of the sensors, which can also be carried out mutually by neighboring sensors. In this connection, a preferred method should also be used for programming the reception / Send address of the sensors are briefly described by a learning process.For this purpose, all sensors to be coded with a local address are first installed and then switched to the address assignment mode via the protocol.This checks whether all sensors are within their measuring range, which is the preferred one Measuring method dynamic relative measurement and static relative measurement is anyway the case because of the automatic setting of the working point. Thereafter, a direct approach with a corresponding electrically conductive object (for example inserting a sheet into the measuring shoe or measuring distance of the coil LM) causes a loss in the overdrive or saturation area, which is detected in the status of the address assignment mode as a detection signal (strobe signal). This detection signal takes over In the protocol of the address assignment mode, an address received by all sensors at the same time, e.g. through the direct RF source of the sensors to be provided with an address.After the corresponding sensors are provided with a receive address, data communication switches back to one of the operating protocols.The address assignment mode is for each sensor repeatable, if necessary secured by encryption for the protocol opening. Furthermore, the address assignment can be equipped with a mode for an auto decrementation / incrementation, or the acceptance of a complete one constantly entered address The structure of Verbeulungssensors is very simple: in each Karosseπeteil, ditto behind the bumper. ect, a sensor housed in a corresponding sheet metal housing is welded on the inside of the inner wall, or plugged on (or alternatively fastened) and scans the inside wall side of the outside wall of the body with its sensor coil.A dynamic relative measurement (see text for Fig. 8) is carried out, which for this application is also possible without a negative resistance component, then the frequency response defined by the adjustment behavior of the operating point, a dynamic event, namely the spontaneous denting of the body or bumper, etc. is simply detected and recorded accordingly in the accident recorder

- ^c yr--? illustrates an accelerometer to determine skidding behavior in an accident. A pendulum is used, e.g. a ball suspended from a thread that floats in an oil fluid. The movement of the ball is sensed by a polygon (triangle, or square, or hexagon, etc.) enclosing the ball (as the center), the sides of which sensor coil (LM1, LM2, LM3) provided for each side boundary is formed. The sensor coils form a measurement of all losses that occur in the sensor coils at different resonance frequencies

Fig. 25 illustrates a highly sensitive seismograph using a known experiment. It is known to levitate a ball between two electromagnetic poles, one above the ball and one below the ball. In this case, measuring coils can be arranged around the poles, which are evaporated according to the invention in order to improve the control so that the distances of the ball from the poles remain stable in fractions of a µm (fractions of a micrometer). A sensor measuring coil arrangement according to Fig. 24, which forms a massive stationary unit with the device of the electromagnetic poles, this device being anchored in the ground of a mine, for example via an iron rod, probes the ball, which is in the center of the boundary of the polygon formed by the measuring coils is constantly off. The vibrations of the soil are transferred to the device. Since the ball is also centered by the magnetic field, the vibration is also transferred to the control of the ball, namely as a change (differentiation) of the control size, provided that the ball is protected from air flow by a sight glass, for example Furthermore, the control can be resolved down to the nm range by the particularly precise sensor, and in addition to the deviation of the controlled variable, we can measure the deviation from the center by measuring the measuring coils from the side, a slow pulse of a very slight earth movement can also be a one-off Signal pulse recognized and quantized precisely in the measurement amplitude. If a large number of such inexpensive devices are now set up and networked in a mine, then the source (the source of the unrest) of the earth's movement can be located by measuring the transit time between the measuring points.

FIG. 26 shows the example of a liquid level meter using a measuring coil (LM with Cp) which is evaporated with the preferably used negative loss Reference coil (LT) not only measures the temperature response, but above all a reference value for the conductance of the liquid (windshield wiper water, brake fluid, etc.) The reference coil (LZ) is located in the lower area of the container and thus its field center is constantly in the Liquid, on the other hand, the measuring coil placed in the upper area of the container and thus measures the liquid level. Both coils can be wound directly onto the container's cylinder body

Fig. 27 Another example is to wind a temperature measuring coil directly on the exhaust pipe (on the engine block) on the exhaust pipe, possibly by a ceramic cylinder at a short distance from the outer wall of the pipe flange. The coil measures the temperature of the exhaust gases via the loss resistance of the pipe flange heated by the exhaust gases, e.g. for efficiency determination and control engineering measures.

Fig. 28 relates to the scanning of sheet metal, such as landing flaps on airplanes, determination of the position of the reversing slide valve, etc., whereby one coil always measures the influence of temperature and the other coil measures the angular position by measuring the distance, ie the determination of the landing gear readiness, etc.

Fig. 29 relates to the relative measurement of a rotary armature (angle measurement with difference measurement of the coils Lma, LMb) which consists of laminated sheets of two or more materials slightly compressed in a vacuum and glued together at the edge (MAT1 MAT2) .The two materials have opposite temperature coefficients of their specific conductivities and are in their cross-section is adjusted so that the temperature influence of the conductance values is compensated for the loss measurement (distance measurement). This variant is an alternative to the use of manganin as the core material, since the alloy manganine loses its property of a compensated temperature coefficient of the specific conductance during mechanical processing (e.g. stamping) and furthermore, when using laminated sheets, even the smallest thin sheets together with one thin but hardened steel sheet can be used to avoid deformation due to acceleration.

Fig. 30 relates to the application for temperature measurement on a standard hotplate which has been modified only slightly for the expanded purpose. The temperature of the cooking vessel is measured directly. The evaporation, preferably according to the invention, by means of a negative conductance value makes it possible, firstly, to sink the sensor in the center, into a hole in the hotplate, and to measure the loss through the hole. The hole is. eg closed with ceramics or glass. The large leakage loss of the hotplate is compensated for. Furthermore, the measuring range of the sensor coil can be set automatically over a wide range (cf. automatic setting of the operating point in text for Fig. 8, in particular the use of an enable signal), the dynamic relative measurement described for the triggering of this automatic Kahbπervvores is used. A differential detection is provided for the spontaneous change of the measured loss as an event measurement. Such an event occurs when the cooking vessel is placed on the hob or removed again. Special cooking vessels are used, the bottom plate of which is directly in the temperature unit (e.g. ° C or Fahrenheit) is calibrated, which is displayed on the stove at a above each Reguher rotary knob of a relevant hob.If such an event is detected, the adjustment process for setting the working point is triggered to set the loss measurement at a working point in which the temperature of the The material to be scanned can be measured accordingly. The static relative measurement described in FIG. 8 is also used, which compensates for the undesired temperature response of the offset value (which in this case is given by the immediate hotplate) by means of a further sensor coil (LT with CT) Therefore we measure with the sensor coil (LM) measuring the temperature of the cooking vessel through the hole in the hotplate and with the sensor coil (LT) for recording the temperature response of the offset value we measure the loss of the hotplate directly away from the center. Both coils (LM, LT) are housed below the hob. The manganin version already described is particularly suitable as measuring coils because the inherent temperature response is very low for such a coil. The example described can also be used for Adapt ceramic plate cookers if, instead of the hotplate, the heating coil is scanned directly with the coil LT or measured with the coil LM in the center through the hole in the heating coil. A further variant is provided for the design of the cooking vessels In addition to the direct usability of metal vessels, ceramics or glass vessels are provided which have a metal insert (for example a perforated sheet support) on which the cookware can be placed, for example the thinnest of vegetables. The sensor coil (LM) measures the loss of the metal batch in order to infer the temperature of the food to be cooked and thus regulates the temperature of the food to be cooked. The principle of measuring through an electrically conductive plate through holes, with a correspondingly adjusted offset value 1 / RVMJ3 = 1 / RVMJDffset + (-1 / RVMJ ^ .EG), cf. the text for Fig. 8, by the way, can be used multiple times in a wide variety of applications, as has already been described for Fig. 20 using the example of a clutch play sensor.

FIG. 31 shows another example that is also suitable as an extension for the application described for FIG. 30. Use is made of the transputer sensor design. The transputer sensor (chip) is located in the handle of a longer metal needle (similar to a knitting needle, but with a handle). These needles can be inserted into fried or baked goods, (meat, cake) or cooked goods (eggs, etc.), the sensor measuring the electrical loss of the needles. It is unproblematic to use non-conductive cookware (glass, ceramic). The offset loss given by the environment (e.g. sheet metal of the oven) is compensated for by the evaporation possibility according to the invention until a desired material to be measured is reached. A relevant enable signal can be used to trigger the automatic calibration process (i.e. setting -l / RVMJ ^ JEG according to a dynamic relative measurement explained in relation to Fig. 8, e.g. by clocking an appropriate counter to set the measurement amplitude according to a loss result obtained) e.g. are triggered by opening the oven, the last measured temperature value being used as the initial value for the measurement after calibration of the offset value 1 / RVM_Q = 1 / RVMJDffset + (-1 / RVMJMEG). The initial value for the temperature measurement is reset to an initial value corresponding to the ambient temperature of the oven, for example when the oven is switched on by an additional function key, the status of which is indicated by a lamp (temperature measurement switched on via Nadein). The ambient temperature of the oven is then measured by a temperature sensor embedded in the oven (e.g. which, for example, also measures the tin temperature of the oven as a loss sensor).

32a relates to the securing of a packaging box in one example in accordance with the explanations given in the chapter "safety-coded loss measurement sensors". For example, a standard solid cardboard box can be used, which can be closed via a divided lid. The dividing line of the lid is on both sides A sheet of metal is inserted into the cardboard of the lid or glued on the inside.On the outside, a flat piece of plastic or metal is covered with a safety piece that is permanently attached to one side of the lid or riveted and protrudes beyond the other side of the lid, this protruding part being a release liner to expose After removing this film, when the lid is closed, the security closure piece can lie on the seam like a seal. It is evident that such a chip seal, for example, also for closing documents, booklet or ring binders (via a fold at the open end) etc. can be used, the self-adhesive layer by means of a re-opening closure, for example a snap fastener. Velcro fastener, etc. can be replaced (Fig.32b). Two measuring coils (LM, LT) are then arranged in the chip seal or safety closure piece as part of a transputer sensor, which scan the metal sheet inserted on the underside of the box. The relative change in loss in each coil is measured in accordance with a dynamic relative measurement and the difference in loss between the sensor coil (LT) attached to the riveted side and the sensor coil (LM) attached to the side to be sealed during packaging is measured in accordance with a static relative measurement ( see text on Fig. 8). The battery-packed HF transmitter, which supplies the chip seal, which is designed as a transputer sensor, with its HF receiving circuit, is also packed in the box. This transmitter can also be operated in a duty cycle to save electricity, but the breaks must be short enough for The transputer sensor of the chip seal does not respond to the exposure detection (the watch dog function) (see chapter "Safety-coded loss measurement sensors"). It makes sense to synchronize the transmit / pause function of the RF transmitter with the data transmitter of the chip seal, e.g. the HF transmitter transmits its HF carrier frequency for the voltage supply of the chip seal for a certain period, in which, for example, a small gold capacitor accommodated in the chip seal charges up and the sensor coil circuits (LM and Cp, LT and CT) carry out the loss measurement At the end of each measurement, the Chip Siegel sends a short termination signal to the RF transmitter, which then generates a pause internally and after this pause transmits the RF carrier signal again until it is interrupted by the Chip Siegel, etc. When used as a seal for one Document folder, the power supply then takes place via RF transmitters, which are installed in the office space accordingly for example via a chip card of a reader networked accordingly with the communication transmitter.

Fig. 32c and Fig. 32e relate to the modification of a chip seal for a document folder, wherein Fig. 32c is an example of a ring closure; Fιg.32d an example of a folder lock; and Example Fιg.32e shows an example of a quick-release (clip) closure. In all three variants, the chip seal detects whether a document has been removed from the document folder and saves this information, or sends a corresponding message to the monitoring station, which also provides the HF supply to the transputer sensor, depending on whether there is an additional one If the temperature measuring coil (LT) is provided for metal scanning or not, a static or dynamic relative measurement is carried out

Fig. 33 relate to the use of the transputer sensor principle for a file monitoring system, it being equally possible to equip every type of file, folder, book, magazine, document, etc. with a chip seal. The transputer sensor housed in the chip seal can measure larger distances even at a relatively low frequency by using the preferred evaporation. The use of a lower frequency has the advantage that the design is not affected by hand movements. In this case, the chip seal to be formed on the file cover, book cover, etc., which is also very flat (with meandering coils for the HF reception circuit and loss of measuring coil LM), is glued and measures the loss of the surroundings. This loss consists of conductor loops, for example conductor loops wrapped around the positioning board of a shelf at appropriate intervals, which can also be arranged in a star shape, for example with tower rotating shelves. The conductor loops then have a corresponding cladding within the shelf. In a particularly preferred embodiment, these conductor loops are printed directly onto the shelf coating or a film used as a shelf coating, etc. as a carbon track, which has its possibility of contacting on the rear narrow side of the respective shelf board. This high-resistance design of the loss measurement (1 / RVMJDffset) over relatively long distances is achieved by evaporation of the loss measurement via a preferred negative loss resistance component (-1 / RVMJMEG), which means that in the operating point 1 / RVMJ2 = 1 / RVMJDffset + (-1 / RVMJMEG) can be measured sensitively. The measurement itself is carried out by measuring the distance between the transputer sensor or chip seal stuck in the file and the subsequent conductor track loop or coal track, which each mark a spacing, whereby the following conductor track loop is found in each case by scanning in the following manner. Each chip seal provided in a file has an address coding (cf. the example already described for the “Pmg method” already explained in the section on supplements to the variant on transputer application), this address using, for example, the method described in FIG. 23 using a password This address can be used by the central control to communicate via the RF transmitters installed in the rooms, or to address each individual chip seal, for example by continuously querying the files, books, or any other object , etc., attached chip seal, in such a way that the transputer sensor contained in a chip seal is activated in its measurement, all files, books, etc., being queried in order for their position via the chip seal, by so-called scanning, a scanning process of this kind takes place with the participation of those on the rear narrow side ite of the respective shelf interconnected interconnect loops, so that the otherwise high-resistance open interconnect loops (Lextl Lextn), via a corresponding Decoder control controlled, each one individually closed in turn independently of the other conductor track loops. The loss is continuously measured for the chip seal (or the transputer sensor) initialized by the control center, and for one of the two maximum maximum values obtained within the run of all conductor track loops, this is reported to the control center, which the addresses of the relevant conductor loop loops as the Conductor loop loops store the appropriate technical designation. The spaces between the conductor loop loops or carbon tracks on the control board (e.g. on the front narrow side) are labeled with the appropriate characters or numbers. This is indicated by one or more displays provided near the shelf or on a computer screen. the positioning of the objects, files, or books, etc. provided with the chip seal can be viewed exactly. The scanning of all shelf positions is called an inventory cycle, which can be interrupted at any time by a search cycle of a direct request. In the event of a direct request, the head office directly addresses the receiving address of the relevant chip seal Transputer Seal and starts the search of all specialist positions marked by conductor loops.This conductor loop can not only be provided on shelves, but also in a desk top, also in drawers, etc. A subject position does not necessarily have to be a physical subject, but simply denotes the search area given as the space between two adjacent conductor track loops. In the transputer sensor circuit used for Fιg.32b to Fιg.34, the coil can also be as large as possible directly on the format of the file or the book appropriate sheet or printed directly on the files in carbon tracks in order to obtain the highest possible inductance even without iron (so that the measurement performance remains small due to the lack of iron losses). The losses at the tunnel diode then amount to about 0.35 mW, with a keyed measurement of 1:10, 35 nW (nano watts), with any adjustable good for the coil made from the thinnest carbon paste track. The principle described in the chapter "Variant of evaporated sensor, basics" can also be used for the compensation of the temperature response of the coil resistance (rs) if, for example, next to each carbon paste sheet (which has a negative temperature coefficient) a silver paste sheet (which has a positive temperature coefficient) is printed on, with appropriate cross-section selection (conductor track width, printing thickness) to compensate for the temperature response of the conductor track coil.At the ends, the track pair is connected in parallel by appropriate printing (e.g. with silver paste). An alternative would be to print carbon paste and silver paste tracks directly one above the other When dimensioning, it should be noted that we compensate for the missing length of the path, not resistance values but guide values, ie if one material has a temperature coefficient 10 times greater than the other material (the adjacent path), then the material with the 10-fa ch Larger temperature coefficients, to which the length must only be 1/10 of the conductance (according to the cross-sectional relationship regarding the web width and web thickness of the webs). The transputer sensor module (or chip seal) can also be contacted using conductive adhesive or conductive plastic in order to connect the coil printed on paper (LM). Furthermore, the chip seal can be used both as a security lock for a box and as a location sensor for the position detection can be used. The RF coil for feeding the tramsputer sensor can be printed with silver paste, for example, or can be designed as a flexible printed circuit (on film). The example described is also very suitable for improving general warehousing, for example if we stick an appropriate chip seal on each box for identification, e.g. in a supermarket. The system is then able to determine the exact location even when the position is changed to locate the goods, to feed them into the Internet via a central computer, so that the customer can put together a shopping list beforehand, using which the shelf numbers can be used to quickly search for the items. The RF transmitters for power supply and communication are located at appropriate points in the store and communicate with the central computer. The number plates can be supported, for example, by guide numbers (street numbers) or letters printed on the floor.Another variant for the position detection would be to make use of the coding of a loss made by filters or resonance circuits. The scanning or measurement then takes place from the conductor track loops forming the shelving (as successively activated measuring spools LM connected in a series resonant circuit), the loss only in the transputer sensor (chip seal) of the coded Object is activated, the position of which is currently to be determined. The measurement frequency required for the loss measurement can be fed in from the sensor or from the conductor track loops

Fig. 34 shows an example of an application of a switch. The evaporation of the measuring coil enables the smallest design for the scanning coil (LM), which scans the tips of the tips of a metallized plastic star. (A sheet metal star could of course also be used) and so the switch setting was deducted. The points are not the same length. Each point has a somewhat different distance from the measuring coil LM. The likewise very small temperature measuring coil LT is attached with its holder directly to the star, or the winding body for the temperature measuring coil LT can also be flanged into the star. Another variant is to provide the plastic star in multiple layers with corresponding sheets for temperature compensation, cf. also Fig. 29

Fig. 35 relates to an example that also benefits from the reduction of the self-loss of the measuring coil by adding a negative loss portion. The winding of the measuring coil (LM) carries a conical steel core (K), which does not have to be made of highly permeable, loss-free material, but can also be a temperature-resistant steel core. The loss of the coil, which is essentially given by the steel core (K), is correspondingly compensated for setting a desired good. The steel tip can then spot a corresponding loss (e.g. of a grooved profile or toothing) even for high temperatures

Fig. 36 to Fig. 39 relates to a further application in which the loss sensor, which is insensitive to the interference signal, for a signal transmission which is completely insensitive to interference

Signal extraction is used; Consists of a large number of participants connected to a cable harness with the corresponding signal or decoupling points. The signal is coupled in via a controlled change in loss of a resistance value modulated by the signal to be transmitted and the signal decoupling or signal sampling by measuring the loss value corresponding to an amplitude value of the signal to be transmitted. A similar principle has been known since the telephone came into existence, the loss change takes place on the transmission side through coal grains, which generate a change in resistance in the rhythm of the sound waves, which is tapped at the other end of the line via a constant current supply. However, in such a method, the loss modulated on the transmitting side on the receiving side is not measured independently of the signal amplitude prevailing on the line, as the loss sensor according to the invention makes possible, but the interference signal given by interference and line reflection is also included in the received signal. Thus, the preferred application for signal transmission is inventive and new. In a further development, the method also uses the proposed correlation of a given Hull curve influence, so that there is a good utilization of the bandwidth used. Likewise, the configuration which is already preferred in a further development for the loss sensor can be adopted with a parallel resonant circuit (or also band filter, comparable filter, etc.). The parallel resonant circuit is not absolutely necessary; all circuits can be used with which the preferred measuring method of the sensor can be carried out. However, the direct use of a parallel resonant circuit (or equivalent filter, band filter, etc.) for carrying out the procedure of signal transmission by means of coding by loss modulation (RpJVlOD) and decoding by means of loss measurement independent of reflection and interference signal brings great advantages if several frequencies are used in the manner of a carrier frequency technique In contrast to the state of the art, these frequencies do not have to be fed in from the actual transmission stations, but unmodulated carrier frequencies can be fed in at any point on the pipe, which, in order to compensate for the steaming of the pipe, is also offset over several sections of the pipe The frequencies fed in thus do not contain a message, whereas for the first time an immediate frequency-coded modulation of a loss is used for coding the message (measured using the state of the art) r on the transmitter side (SVS) modulating the loss (variable by means of manipulated variable BDJ5) loss resistance RpJVlOD a resonance circuit Ls, Cs (or alternative filter, etc.) matched to the carrier frequency used, which has the same resonance frequency is coordinated, just as the loss sensor used on the receiving side (EVS) uses it as a parallel resonance circuit (LM, Cp). Depending on the circuit, a series or (via series resistor) coupled parallel floating circuit LM. Cp can be used. The interesting thing about this new type of carrier frequency technology is that the modulation of the loss for each resonance frequency or carrier frequency corresponding to a resonant circuit can be carried out independently of the respective loss values of the other resonance or carrier frequencies. Physically, we can simply make this plausible : Each resonant circuit only transforms the loss RpJVlOD connected to it via its resonance frequency in series connection of its coupling resistor Rk, Ck into the line, since only at this frequency does the voltage required for current flow occur in the loss connected to the resonant circuit. On the transmission side (where the loss is modulated) and the reception side (where the loss frequency is measured specifically, i.e. demodulated again, oscillation circuits LM, Cp which are completely identical on the reception side and on the transmission side) may have different Hull curve and amphtudic voltage curves, which, however, are caused by the measuring method according to the invention have no influence on the measurement result, decoding takes place regardless of absolute values of the amplitude values prevailing on the transmission link, such as loss of steaming, interference, reflections, etc. Thus, every freely available open telephone wire line, every power line, or even every piece of garden fence , can be used for interference-proof, and also radiation-proof signal transmission up to the Giga Herz area. It is sufficient to work with the smallest signals on the line, eg with the smallest signal voltages (e.g. 0.1V) on relatively high-impedance resistors (e.g. 10 kOhm total resonance resistance for a few thousand participants). This means that only minimal power (uW, microwatt) occurs on the line. The signal can be fed into the line not only at one point, but also at several points, offset at regular intervals. In a further development, the phase positions of the oscillators provided at the feed points can also be synchronized, for example, by a clock radio signal or by the line signal itself, in order to avoid feeding in phase opposition. The parallel resonant circuits are connected both for the transmitter circuits and for the receive circuits via a decoupling resistor Rk and / or, if necessary, via a decoupling capacitance Ck.This means that the good of a connected parallel resonant circuit is due to its own good (this is the good thing if the parallel resonant circuit would not be switched on) and the decoupling resistor Rk, which is almost parallel to the resonance circuit, is determined. The decoupling resistor Rk is not directly parallel to the base point of the parallel resonant circuit coupled via it, but rather via the loss resistance RVJine of the line used for the signal transmission. This consists of the parallel connection of all resonant circuits coupled via a resistor Rk, part of which is in resonance with a respective resonant circuit and the other part is not in resonance (i.e. has an inductive or capacitive impedance component). Ie the loss resistance of the line RVJine represents a very low-resistance or very high loss (1 / RVJine) for all resonant circuits coupled to the line via a decoupling resistor Rk, so that the change in one via a relevant parallel resonant circuit LM, Cp is a transmitting one Participant (SVS) of varying loss (each via RpJVlOD) would have a minimal impact on the (or the) parallel oscillation circuit (s) of one or the receiving participant (EVS). In order to make the portion l / d ~ RVM of the loss RpJVlOD coupled in via a relevant parallel resonant circuit LM, Cp relative to the static loss resistance RVJine of the line relatively large, the line loss RVJine is evaporated by a corresponding parallel connection of a negative conductance (NIC, negative impedance controller, or negative impedance controller), which is set so that there is a reduction in the offset value of the loss, as already described for FIG. 8 for the example for the evaporation of a loss measuring sensor: 1 / RVM_Q = 1 / RVMJDffset + (-l / RVMJJEG), where 1 / RVMJ3 corresponds to the remaining line loss for a desired evaporation and 1 / RVMJDffset corresponds to the loss 1 / RVJine to be evaporation. 1 / RVMJ2 thus sets the operating point by which the loss magnitude l / d ~ RVM (see FIG. 11) changes. L / d ~ RVM is the loss varied at a particular resonance circuit or for a particular resonance frequency of a transmitter, the The message to be transmitted contains, if necessary, the individual goods of the individual resonant circuits through direct ones Connection of an additional negative resistance or conductivity can be improved in each case. The evaporation units (NICs), which are connected to different line sections, also feed in the unmodulated carrier frequencies. The loss value division 1 / RVMJ5 of the operating point is carried out in such a way that the desired operating bandwidth is set for the carrier frequency in question. The automatic readjustment of 1 / RVMJ3 is carried out in such a way that the evaporation devices (NICs) also carry out a loss measurement on the line via a correspondingly coupled parallel resonant circuit, using the method according to the invention, furthermore also using this method to determine the negative conductance to be coupled in for a given loss resistance (arithmetically or using a table) and according to the preferred method, create the negative conductance accordingly; here, as with positive conductance values, the negative conductance value can also be composed by connecting several such negative conductance values in parallel on different line sections (each at a carrier frequency supply point), whereby, since each individual conductance can be switched off using a switching element (cf. in FIG.), each individual negative conductance can be set precisely. The implementation of an evaporation element (NICs) can be carried out exactly using a tunnel diode circuit thus take place, as already stated for the evaporation of the preferred loss measuring sensor. The modulation of the loss change l / d ~ RVM used for the transmission of the message is small compared to the loss of the operating point 1 / RVMJ2 (small signal modulation of the loss), so that the variations of the add individual losses l / (l + x) + l / (ly) as well as with the known superimposition of signals (1-x) + (1 + y). etc (with x «1, y« l) Hence the Losses, even without using multiple carrier frequencies, can be used for a carrier frequency-like band division (with direct filtering by processor, or via signal conversion, etc.) Furthermore, if necessary, a linearization function is provided in a table, via which the relationship between loss value and linear signal sampling is recorded is

Furthermore, the described method can also be implemented in a wide variety of simplification variants. For example, using only one carrier frequency, i.e. All parallel resonant circuits of all participants (transmitters and receivers) are constantly in resonance, depending on the carrier frequency used (feed-in frequency) .For example, for use for computer networking via the existing electrical installation. The use of multiple carrier frequencies, with a corresponding number of parallel resonant circuits intended for transmitting and receiving participants however, enables the simultaneous transmission of several parallel bits of a data stream, with a different carrier frequency being fed in for each track (or each weight of a data word). For digital transmission, certain threshold values of the respectively varied or measured losses are the digital levels (log. l , log.O) assigned

Multi-frequency technology also has advantages in partyline mode (this means any protocol, which can optionally switch a data block to be sent from one participant alternately to the other participants, while the other participants are all listening or listening), for example If the line connection is poor, work with a large Hamming distance, in order to repeat blocks with error-correcting codes if necessary, while newly built connection blocks are sent by other stations with a different carrier frequency.This way, very fast and data-safe Internet connections can be implemented old telephone lines can be used to transmit the calls with the new method and additionally to transmit a broadband internet channel and several digital television channels. This versatility offers enormous cost savings of bandwidth, in some cases not always fully used fiber optic cables, or the process offers the ideal addition to connect broadband data networks to offices and households directly

Fig. 36a to Fig. 36d and Fig. 37 (on sheet 15) show an example: The parallel resonance circuits (LM, Cp for E0,

El En) are each via a decoupling resistor Rk and / or

Decoupling capacity Ck fed The execution of the variable by means of the actuating variable BDJ5 Loss resistance RpJVlOD depends on the application. Switching RpJVlOD between two resistance values is sufficient for the transmission of a digital level; for analog quantization, for example, the master value network of a D / A converter controlled by the microcontroller or signal processor can be used, or a field plate, field effect transistor, etc., i.e. all of the state Alternatives known in the art for realizing a controllable value change

In addition to the given general applicability, a preferred main area of application is the use of power lines as a data line for internal networking of computer systems in buildings (via the existing electrical installation) or also the transmission of data, television or telephone signals via existing power line overhead lines or power lines of everyone Kind including underground cable

36a to Fig. 36d and Fig. 37: SVS (sending station) with +/- G for creating the required offset value, EVS (receiving station) with +/- G for creating the required offset value TFE (carrier signal coupling station) ), which contains the following components: +/- G for the possibility of producing the cable, a sensor response (f-measurement) for measuring the influence of a slight change in the frequency fed in as a constant alternating current (ι ~ const.) in order to use a capacitance cascade (or also capacitance diode) to compensate for a detuning caused by the resonance circuits not in each case at the resonance frequency, so that the relevant resonance circuits are still in resonance SNCR. Means a synchronous line, either as a line or via the protocol of the already existing signal line, to synchronize the switching of the loss side Rpl, Rp2 in adaptation to the measurement cycles on the receiving side (usl, us2). The changeover for the corresponding influencing at the measuring point takes place here exclusively on the loss feed side, ie on the transmission side SVS, so that several loss sensors hearing at the same time on the receiving side (EVS) do not interfere with one another. Fig. 36b illustrates the loss connection of all sensors on the line, seen from the (active) transmission side SVS. The line evaporation -G (or comparable +/- g in Fig.36a) compensates for the loss of the series resistors Rk, which exist almost as a parallel connection. Z ^'is the impedance which results from the resonance circuits which do not correspond to the carrier frequency (of a specific frequency-coded loss): The resulting detuning of the resonance circuits is compensated for by the capacitance cascade in Fig. 36a, which may also be inductive via corresponding circuits if necessary, the line can be stressed (leveling out), based in each case on an average share of TFE, around which is regulated Fιg.36c ... like Fιg.36b, but the total loss of a receiving side is seen as shown in Fιg.36a the components on the resonant circuit of the transmitter side (SVS) and the receiving side (EVS) are combined accordingly, so that the transmitting side as well as the receiving side can be realized with an oscillating circuit LM, Cp (the separate illustration was chosen only for better understanding). Fιg.36d relates to the application of this principle to a serial feed via the preferred variant of an induction cable when the sensors are designed as transputer sensors. Therefore, the evaporation (-G) takes place via units supplied by the NT power supply unit. The equivalent circuit diagram for this shows Fig. 37 (on sheet 15): where -rL mean the negative conductance (-G) transformed via the oscillation circuit coupling (-G), which evaporates the line as series resistance -rL. RMOD correspond to the modulation conductance values transformed into the line as series resistors. The example corresponds to the example described for Fig. 44, Fig. 45 for a grid road wiring using ribbon cable.

Fig. 38 illustrates an example of using an electrical installation as a data line. Each consumer is HF-decoupled from the supply line by a serial RF blocking choke (HFS). The HF blocking choke (HFS) is integrated in the sockets for internal use in buildings. If the method is used for data transmission on overhead contact lines, a corresponding HF blocking choke (HFS) is provided on each pantograph of the railcars. With an internal application of buildings, the inductance of the electricity meter is usually sufficient around the To adequately block losses of the electrical consumers in front of the electricity meter, if not, then a corresponding blocking choke must be switched on. Furthermore, if necessary, the variant is also provided to subdivide an existing power distribution network for the HF transmission into several subnetworks. The HF wiring harness is separated into several pieces. For this purpose, in building-internal installations, a serial HF blocking choke (HFS) is connected to the switch sockets, where the installation of the line provides a suitable interruption terminal anyway, which has practically no appreciable impedance for the high-voltage current, i.e. which connects the networks , on the other hand, HF separates the networks. The separated networks are then connected by a coupling device accommodated in the relevant switching socket, which can be referred to as an active directional coupler which can be switched over in its transmission. However, this new directional coupler is not designed for distortion-free signal transmission, but for the distortion-free transmission of losses with permissible signal distortion (regarding interference, interference signal scattering in the lines, u sw). The ones on both sides that are separated via the RF blocking choke (HFS) synchronize Networks provided for each transmission device (via loss modulator RpJVlOD or the loss vanation l / d ~ RVM generated thereby) transmit the protocol in such a way that one side transmits to each of the network sides connected by the directional coupler and the other side receives it at the same time, with alternating switching of transmission and reception on each side, with a synchronous switching of the directional coupler transmission. The directional coupler then has, in addition to the existing transmission devices (each RpJVlOD) with which it transmits the loss modulation of a relevant (straight) transmitting side to the other (respectively straight) receiving side, the loss measuring sensors for reception on each side

Fig. 38 to Fig. 39 relate to further training for the configuration of the sockets with an additional data connection function. The sockets protrude slightly from the wall and have a data connection (e.g. BNC connector) on the protruding narrow edge 0. The preferred loss modulation demodulation device can be accommodated completely integrated in the socket so that any standard PC network card can be connected directly to the BNC socket, or the relevant additional functions are integrated in the network card or an additional device. The following special feature is still in training provided: Often it is desirable to extend the mains voltage cable as well as the data cable from the socket (e.g. also to connect a distribution strip) For this purpose, the plug of the extension cable or the distribution strip has an additional contact pin 0, which is inserted when the plug is inserted is inserted into the corresponding wall socket in a corresponding hole 0 in addition to the connection contacts 0 for the mains voltage and closes a contact bridge within the socket. Via this contact bridge, the pin bridges the HF blocking choke (HFS) interposed in the phase line of the mains voltage, so that the loss modulation of the HF carrier signal used as a data signal can be decoded in the connected distribution strip, which then includes the corresponding electronic components of the necessary RF blocking choke (HFS) for blocking the consumers connected to the distribution strip and the data connection, if necessary, two such bridging contact pins can also be provided if both phase and neutral have an interposed HF blocking choke (HFS) The connector of the distribution strip also prevents the wrong insertion of the connector, so that the base point of the parallel floating circuits used can always be switched to the neutral conductor

Fig. 40 relates to a variant in which the property of the sensor that even very small losses connected in series with the measuring coil can be measured precisely for line diagnosis, for example on power lines. The preferred loss measuring sensors with their measuring coil are in corresponding line sections (LMs) each connected in series in the line, whereby the measuring coil inductivity for the heavy current hardly represents any appreciable resistance. A corresponding resonant circuit capacitor (Cps) is connected in parallel with the measuring coil (LMs). The resonance frequency set for this sensor is far below that for data signal transmission, if applicable used carrier frequencies set, so that possibly used for a data signal transmission Carrier frequencies are not hindered by the series-connected parallel circuit inductances. If necessary, these resonant circuits are made bridgeable by means of a protective contact (which is correspondingly higher-resistance than the measuring coil inductivity in order to avoid a current-related overload) in order not to impede an RF signal transmitted via the power line for data transmission. Furthermore, between the individual lines (phases, Neutral conductors, etc.) of the power line by means of contactors cross-capacitors can be provided in order to be able to optionally short-circuit the measuring frequency and in this way to be able to measure a line interruption via the serial resonant circuits between the plug sections

Fig. 41 shows the example described for a packet band chip seal

Fig.42ze \ g \ the example for the security pull-through slot of the package tape.

Fig. 43 shows the example described for the coupling of the induction cable. The pull-off cap is kept closed by a compression spring (prints on the pulling bolt of the telescopic guide); if necessary, a securing thread, bayonet lock, is also provided.

Fig. 44 and Fig. 45 illustrate the contacting and connection of the preferred vehicle detector sensor coil (LM) designed as asphalt cable

Fig. 46 relates to a variant in which the loss of a particularly thin measuring needle is sensed by the sensor coil LM. The needle measures the temperature, the other structure being the same as the pressure gauge described for Fig.lδa, and the sensor is also designed as a combination sensor and can be screwed into the cylinder head of an engine like a spark plug

Fig. 47 illustrates how a network line (with e.g. different carrier frequencies) separated by RF blocking chokes in several RF data lines can be networked in the bidirectional data direction by means of corresponding loss transmission and loss reception stages.

Fig. 48 relates to the variant in which the measuring coil (LM) is connected outside the filter or resonant circuit by means of a series circuit in the resonant circuit coil (LM ^' ).

Fig. 49 concerns the illustration of the described envelope correlation.

Summary

The method is an improvement invention of DE 42 40 739 C2 for measuring a loss (1 / RVM) coupled into a measuring circuit (LM.Cp), the loss being coupled ohmic or inductively into a measuring coil (LM) or also via a capacitance and the circuit has the property of influencing the measurement with a loss (1 / RVL) controlled by the control signal (BD) by means of a resistance value (Rp) which can be controlled via the control signal (BD) when the measured value (1 / RVM) is constantly switched on , as if this influence had been made at the measuring point, the total loss (1 / RVM + 1 / RVL) being measured, and the evaluation (BW) from the value of the adjustable resistance (Rp) or its manipulated variable (BD), and an amphtudy measurement (us) is carried out on the measuring circuit, or possibly on the measuring coil (LM, or LM, Cp), with an improvement in the prior art specified by DE 42 40 739 C2 in that a measured value ( mp) of several (at least two) measuring steps (tl, t2) are determined, in which the adjustable resistance (Rp) is set differently and for these different resistance settings (Rpl, Rp2) the amphtudy measurement (usl, us2) is carried out on the measuring coil (LM) , In contrast to DE 42 40 739 C2, the loss measurement is carried out independently of the absolute value of the measuring voltage occurring at the sensor circuit (LM, Cp) over several measuring steps (tl, t2) in which the loss which can be influenced by the control signal (BD) Total loss is changed differently (cf. Rpl, Rp2) and each in the individual measuring steps (tl, t2) different Sum loss occurring, the corresponding corresponding voltage values (usl, us2) are measured on the sensor circuit (LM, Cp), whereby a relationship or correlation rule from the relationship between the voltage values measured in the individual measuring steps and the different sum loss each also generate , by the manipulated variable (BD) adjustable resistance or conductance values, the measured value (mp) of the loss actually to be measured (1 / RVM) is derived. In addition to the possibility of carrying out the loss measurement independently of the absolute value of the measuring voltage occurring at the sensor circuit (LM.Cp), use is made of a further training opportunity to add a precise negative resistance component to the total loss. These measures open up completely new areas of application for the loss measurement method, including a data or signal transmission method which offers completely new possibilities far beyond the usual sensor applications. Furthermore, it is possible for the first time to measure with such low power that the loss sensor is also excellent for Suitable for transputer applications. 1 shows an arrangement according to DE 42 40 739 C2. The process improvement is illustrated in FIG. 2. Fig. 2 is to be included in the summary. Fιg.8 is also essential for the precise connection of a negative resistance component.

Claims

claims

1. Method for loss measurement, in which a loss (1 / RVM) is measured with a sensor circuit (LM.Cp) by galvanic or capacitive connection, or by inductive coupling via a sensor coil (LM), or via a capacitance (Cp) , the circuit having the property of measuring the loss of a purely ohmic resistance (for example an oscillating circuit LM, Cp or equivalent filter at resonance frequency or a bridge circuit) for a measuring frequency used as resonance frequency and the circuit further has the property that the Loss measured at the measuring point can be influenced by a resistance (Rp) or loss (1 / RVL) that can be changed or switched via control signal (BD), as if this influence had been carried out at the measuring point, the loss to be measured (1st / RVM) is always switched on or coupled in and the total loss (1 / RVM + 1 / RVL) consists of the loss to be measured at the measuring point (1 / RVM) and the ü Loss (1 / RVL) influenced by control signal (BD) is measured and via an evaluation (BW) from the value of the adjustable resistance (Rp) or its manipulated variable (BD), and an amputation measurement (us) on the sensor circuit, or optionally measuring coil (LM or LM, Cp), the coupled loss is determined as a measured value (mp), characterized in that the loss measurement is independent of the absolute value of the measuring voltage occurring at the sensor circuit (LM, Cp) over several measuring steps (tl, t2) in which the total loss is changed differently via the loss which can be influenced by the control signal (BD) (cf. Rpl, Rp2) and to the sum loss occurring differently in the individual measuring steps (tl, t2), the corresponding corresponding voltage values (usl, us2) are measured on the sensor circuit (LM, Cp), with a relationship or correlation rule the relationship between the voltage values (usl, us2) measured in each of the individual measuring steps and the different total losses, each with generating resistance or resistance that can be set by means of the manipulated variable (BD). Guide values, the measured value (mp) of the loss actually to be measured (1 / RVM) is determined.

2. A method for measuring loss according to claim 1 or according to the preamble of claim 1, or for a general Meßvorπchtung, where the loss coupled by the measuring device interferes (so should not be measured), characterized in that a to be measured in the measuring point when pending Loss (1 / RVM) coupled additional loss has a precisely adjustable or precisely measurable negative component (- gT or -1 / RVMJ EG), which is added to the total loss as a measurement constant [1 / RVM -r (-1 / RVMJ4EG) or [1 / RVM + 1 / RVL + (-1 / RVMJ.EG)]

3. A method for measuring loss according to claim 2, characterized in that the negative portion (- gT or -1 / RVMJ EG) of the variable or switchable resistance, or conductance or loss by a positive portion (GTCOMP or GTCOMP - 1st / RVLo) can be compensated, this compensation being used for setting or measuring the value for the negative resistance component (- gT or -1 / RVMJ.EG)

4. The method according to claim 3, characterized in that the compensation for the setting or measurement of the value for the negative resistance component (- gT or -1 / RVMJMEG) takes place in two measuring steps (toff, and ton), in which in one Measuring step the negative resistance component (- gT or -1 / RVMJ EG) switched off (toff), and switched on in the other measuring step (ton) and for the balanced state in both measuring steps (toff, ton) respectively corresponding voltage values (maximum values, or Hull curve values uoff or uon with uoff = uon) for a change of the positive resistance component (GTCOMP, or GTCOMP = 0, or GTCOMP - 1 / RVLo) on the corresponding sensor circuit (eg resonant circuit LM, Cp; band filter signal line, etc.) corresponding to this match. ) are measured.

5. The method according to claim 4, characterized in that by comparing the positive resistance component (GTCOMP, or GTCOMP = 0, or GTCOMP - 1 / RVLo) the value of the negative resistance component (- gT or -1 / RVMJ.EG) is measured

6. The method according to claim 4, characterized in that the negative resistance component (- gT or -1 / RVMJJEG) by control size (for example by choosing the operating point of the component representing the negative resistance) is adjustable and by comparison according to a predetermined measurement constant that the for obtaining a comparison (uoff = uon) positive resistance component (GTCOMP, or GTCOMP = 0, or GTCOMP-1 / RVLo) to be changed

7. The method according to any one of claims 1 to 6, characterized in that the method corresponding to one of claims 2 to 6 in each case between the method steps of a loss measurement made according to claim 1 for constant Nachkahbπerung, or measurement of the negative resistance or Loss share (-gT or GTCOMP or -1 / RVM_NEG) is carried out

8. The method according to any one of claims 1 to 7, characterized in that the measurement (which occurs at the sensor circuit (LM, Cp)) of the resistance (Rp, or - gT) that can be changed or switched via a control signal (BD) Voltage values (usl, us2, or uon, uoff) are made at repetitive times of the measured voltage values (for example maximum values) corresponding to periodic, if applicable, envelope curves, two variants (modes) with a switchover between these variants (modes) being provided, if appropriate.

A mode in which the measurement of the voltage values is carried out in accordance with a change in the resistance changed or switched via control signal (BD), synchronized according to the voltage repetitive voltage values within a possibly existing Hull curve, and

• a mode in which the voltage values are measured for a corresponding change in the resistance changed or switched via control signal (BD), via a correlation of the measured values according to the Hull curve profile (eg interpolation according to the increase) of a possibly existing Hull curve, and the for the correlation (or interpolation) corresponding value pairs are measured in each case to identical sum losses (via Rp, or GTCOMP, or - gT) and the pecodicity is carried out by checking the correlation requirement of interpolated values, both modes being provided if necessary, and depending on the frequency the Hull curve and or depending on the result of the correlation of interpolated values, the modes have been switched, and if necessary in the mode in which usable measured values are obtained for one part of the Hull curve pepode, but not for another part (e.g. immediately he near the zero crossing of the Hull curve at 100% degree of modulation by a possibly present interference signal), the usable measurement values are used to derive (determine) the measurement result from the corresponding value relation (usl, us2), but the useless ones are not used without this (e.g. at low envelope frequency) is switched to the other mode (depending on the respective application of the sensor)

9. The method according to any one of claims 1 to 8, characterized in that the method is carried out on a high-resistance measuring filter (parallel resonant circuit LM, Cp, band filter, etc.) as a sensor circuit, with an inductive or capacitive or by galvanic contact connection via the measuring filter coupling of the loss to be measured (1 / RVM) and the loss in the area of the alternating field of a measuring coil (LM) existing electrical conductivity (a part or material, a liquid, also blood, etc., a gas, etc.) is measured, or a loss to the Measuring coil (LM) galvanically connected resistance value is measured, or as a loss the goodness of the capacitor used on the measuring filter (eg for moisture measurement) is measured, or as a loss at defined points via inductive coupling coils or antennas switching resistance values are measured.

10. The method according to any one of claims 1 to 9, characterized in that the method is carried out on a transmission line for the transmission of a signal, in which the signal coding is carried out by means of a loss value transformation carried out by means of adjustable resistance, and the decoding by a method according to one of the Claims 1 to 9 is made.

11. Method for loss measurement according to one of claims 1 to 10, or method for loss measurement in a measuring coil arrangement (LM), or a corresponding sensor, consisting of: an AC field coil (LM), the loss of an electrically conductive measuring part (K with loss 1 / RVM, Fig.l) co-determined in their electromagnetic field of an inductively coupled measuring point, or (as an alternative application) at a loss (Rx Fιg.6) connected ohmically via measuring contacts, and additionally by a controllably changeable further loss (1 / RVL ) is determined which corresponds to an ohmic resistance (Rp) or conductance which can be set by the control signal (BD), which is electrically connected to the alternating field coil (LM) and the total loss occurring in the coil (1 / RVM + 1 / RVL) according to the control signal varies, and an evaluation device (BW), the measured value (mp) from the known loss of the ohmic resistance set by the control signal (BD) standes (1 / RVL) and the sum loss (1 / RVL + 1 / RVM) corresponding amplitude value measurement (us), the measuring coil arrangement or the sensor has the property that said control signal influencing the adjustable resistance (Rp) , influences the total loss (1 / RVL + 1 / RVM) detected by the measuring coil (LM) or sensor as if this influence had been made at the measuring point itself (1 / RVM) and the loss of the measuring part to be measured ( 1 / RVM) corresponding measurement variable (mp) from the resistance value (1 / RVL or Rp) set by the control signal (BD), added to the loss to be measured (1 / RVM) and the total loss (1 / RVL + 1 / RVM) occurring amplitude value (us) corresponding to this setting is determined (ascertained), characterized in that said sum loss (1 / RVL + 1 / RVM) occurs in two or more successive measuring voltages independent of the absolute value an at the measuring coil arrangement (LM) Schr itt, or measuring times (tl, t2), when the loss to be measured (1 / RVM) is continuously switched on over these times and in each case in the individual times (tl, t2) via the control signal (BD) differently set values of the total loss (1 / RVL + 1 / RVM) is measured in such a way that the measurand (mp) of the loss value to be determined (1 / RVM) from the relation of the setting of the total loss made over the time intervals (tl, t2) (1 / RVL + 1 / RVM ) and the associated relation of the amphtudic values (usl, us2) occurring on or in the alternating field coil is determined or measured, the method being alternatively feasible in both directions as follows: a) to predetermined relations (Rpl , Rp2) of the total loss, the associated amplitude values (usl, us2) are measured and from the Relation between amplitude values and associated sum loss values set via manipulated variable (control signal), the measured quantity (mp) is determined, and / or b) the relation of the sum loss values changed by control signal (BD) is appropriately set and / or given predetermined relations of different amp value values (usl, us2) The measured variable (mp) is determined from the given relation between amplitudes and the associated total loss values set via manipulated variable (control signal)

12. The method according to claim 11, characterized in that the change made by the control signal (BD) of the total loss (1 / RVL + 1 / RVM) with corresponding measurement of associated amphtudic values (us) according to the following relations for the determination of the measured value (mp) The measured variable (mp) corresponding to the loss of the measuring part (1 / RVM) to be measured is determined over two or more steps (tl, t2), from the resistance values (1 / RVL or . Rpl, Rp2) and the amplitude values (us = usl, us = us2) that occur at the total loss (1 / RVL + 1 / RVM) in such a way that the ratio of the amplitude values (usl, us2 ) is formed and related to the ratio of the (these amplitude values usl us2) corresponding resistance values (1 / RVM1, 1 / RVM2 with Rpl or Rp2, or manipulated variable values (BD), whereby from the corresponding mathematical relationship de r unknown loss of the measuring part (1 / RVM) is determined and the switching of the resistance values by control signal (BD) with sampling of associated amphtudic values takes place so quickly that the loss of the measuring part (1 / RVM) to be measured does not change over the duration of these switches changes significantly

13. The method according to claim 11, characterized in that a defined amplitude ratio (usl / us2) of the measuring steps (tl, t2) by adjustment (stepwise or in successive approximation) of the adjustable resistance (Rp) over the measuring steps (tl, t2) relevant amphtudic values (usl, us2) is produced, the determination of the loss coupled in via the measuring coil at the measuring point being derived from the value adjustment of the adjustable resistance (Rp) and the switching of the resistance values by control signal (BD) with scanning of associated amphtudic values so quickly takes place that the loss of the measuring part (1 / RVM) to be measured does not change significantly over the duration of these switchovers

14. The method according to any one of claims 1 to 13, characterized in that the switching of the resistance values (Rpl, Rp2) by means of a control signal (BD) with sampling (usl us2) or comparison (us2) associated amplitude values in each case at stable phase positions of the measurement signal amp (in relation to pododicity) or that in each case a correlation of the relevant amphtudic values is carried out in relation to a given Hull curve

15. The method according to any one of claims 1 to 14, in particular method according to claim 12 or claim 13, characterized in that the loss to be measured (1 / RVM or mp) is determined in each case from two measuring steps (tl, t2), or is measured over two measuring steps, the measuring steps correspondingly having different resistance values (Rpl, Rp2) of the resistance value adjusted with the control signal (BD) and when using a Kahbπer method for setting or determining a negative resistance component according to one of Claims 2 to 8 and / or Use of a correlation method according to claim 8 or claim 14, the measuring steps required for the calibration of the negative resistance component, or for the correlation of measured values, are inserted appropriately within the measuring steps (tl, t2) for the loss measurement

16. The method according to any one of claims 12 or 13, characterized in that in one of the two measuring steps (tl, t2) via said control signal (BD) switching the resistance values by switching off the as an additional loss by means of the control signal (BD) switched on Resistance value (Rp = infinitely high) is carried out in the corresponding measuring step, resulting in the resistance values (Rpl, Rp2) mentioned differently in the individual measuring steps (tl, t2) (1 / RVM for Rp = infinitely high, or 1 / RVM + 1 / RVL for Rp = Rp)

17. The method according to any one of claims 1 to 16, characterized in that a high-resistance filter (eg parallel resonance circuit LM, Cp or band filter, etc.) is used to carry out the method, the inductance of the alternating field coil (LM) corresponds or at least part of the filter inductance (e.g. a simple parallel resonant circuit or a bandpass filter, etc.), whereby the negative resistance or conductance (- gT) that may be present is coupled into this filter (or oscillating circuit LM, Cp) and, if necessary, by means of a corresponding transmission ratio of the filter modulus (LM ) is adapted to the desired range of values by means of a transformer.

18. The method according to claim 17, characterized in that the point in time of stable phase positions, in particular the point in time to determine a voltage maximum corresponding to the filter or resonant circuit voltage by scanning the zero crossing of the current amplitude via a series measuring resistor RM which is in series with the measuring coil, whereby by the in Claims 2 to 8 mentioned negative resistance component (- gT or -1 / RVMJ ^ EG), the measuring resistor and possibly also the coil sense resistor (rs) are evaporated.

19. The method according to claim 17 or 18, characterized in that the feed amp tude of the filter or parallel resonant circuit alternating current over the duration of the sum loss values each set differently in different measuring steps (tl, t2) via different manipulated values (BD) of the adjustable resistor (Rp) (1 / RVL + 1 / RVM), constantly regulated

20.The method according to claim 19, characterized in that the regulation of the filter or parallel resonant circuit alternating current takes place via the supply voltage of the supply oscillator (OSZ).

20. The method according to claim 19, characterized in that an external supply of the filter or parallel resonance circuit is provided, wherein the external supply is made by feeding a constant current sources and constant current sinks alternately switched according to the resonance frequency

21. The method according to any one of claims 1 to 20, characterized in that the measuring coil arrangement (LM) is used for an electrically conductive measurement of a low-resistance, which is connected as a Seπen loss resistance (Rkontakt) in the Meßspuleπmduktivität (LM) or resonance coil inductance in galvanic connection

22. The method according to any one of claims 1 to 21 or method with a non-contact temperature measurement (by the measuring coil LM) on a brake disc, characterized in that an additional temperature sensor ~ standard) is provided for detecting the cooling effect of the wind, which is made heatable, with this sensor the cooling effect of the airstream is measured and, taking into account the airflow cooling and the braking force exerted by the brake, the function of the brake is deduced from the measured temperature of the brake

23. The method according to claim 22, characterized in that the heatable temperature sensor located in the airstream cooling of the brake disc is heated via control to a temperature which corresponds to the measured temperature of the brake disc, the heating power of the sensor being used to infer the braking power of the brake disc becomes.

24. The method according to claim 22 or 23, characterized in that the method or the arrangement is integrated in an ABS brake control system.

25. The method according to any one of claims 2 to 21 using a measuring coil (LM), characterized in that by the precisely adjustable or precisely measurable negative portion (- gT or -1 / RVMJ EG) of the measured total loss 1 / RVM + 1 / RVL + (- 1 / RVMJNEG), one of the desired good production of the measuring coil (LM), or a filter determined by the measuring coil (or Schwmkgreises LM, Cp) corresponding partial compensation of by the coil resistance of the measuring coil (LM) and / or by the physical structure of the lost value (K) specified via the measuring coil (LM) (the measured total loss 1 / RVM + 1 / RVL + [-1 / RVMJNI EG]) is carried out (whereby offset loss is included in 1 / RVM)

26. The method according to claim 25, characterized in that for the winding wire (or the windings, conductor tracks etc.) of the measuring coil (LM) and / or for the loss part (K) to be measured, a material (for example an alloy such as manganin, etc .) is selected which, compared to a standardized material (copper coil, or aluminum or steel sheet for the part to be measured, etc.) has a significantly higher specific resistance (by factor X), but a significantly lower resistance (corresponding to factor X ) Has temperature coefficients (due to materials involved in the alloy with correspondingly opposite temperature coefficients of the specific resistance or conductance)

27. The method according to claim 26, characterized in that the alloy for the temperature compensation of the measuring coil (LM), or for the temperature compensation of the loss part to be measured (K), does not affect a direct material connection in the physical sense, but the wire, or possibly the Conductor tracks of the measuring coil (LM) made of parallel (bundled) wires, or conductor tracks made of different materials, each with opposite temperature coefficients of their specific resistance, or for the loss part (K) to be measured, the measured loss part (K) from several layers different materials with opposite temperature coefficients of the specific conductance.

28. The method according to claim 25, characterized in that the setting of the negative loss portion contained in the total loss [1 / RVM + 1 / RVL + (-1 / RVMJNEG)] (- gT or -1 / RVMJ EG) by controlled change of a positive one Resistance or conductance component (Rp or 1 / RVL) with a constant negative loss component

29. The method according to claim 25, characterized in that the setting of the negative loss portion contained in the total loss [1 / RVM + 1 / RVL + (-1 / RVMJJEG)] (- gT or -1 / RVMJ EG) directly by controlled change in negative loss share via the selection of the respective operating point of the component representing the negative loss share - 1 / RVMJ ^ EG) (for example a tunnel diode) for setting the negative differential resistance or conductance of the component (- gT)

30. The method according to any one of claims 25, 28, or 29, characterized in that by readjusting the negative loss portion contained in the total loss 1 / RVM + 1 / RVL + (-1 / RVMJ.EG) in the loss measurement (- gT or - 1 / RVMJMEG) the measuring voltage (usl, us2) required for the loss measurement is kept in the measuring range (us *) corresponding to the respective application, the controlled variable for the readjustment of the negative loss component (- gT or -1 / RVMJ ^ EG) from the modulation range of the measurement voltage (e.g. via low-pass function or comparator) (see dynamic relative measurement in the description)

31. The method according to claim 30, characterized in that the readjustment of the negative loss portion contained in the total loss 1 / RVM + 1 / RVL + (-1 / RVMJMEG) (- gT or -1 / RVMJ ^ EG) by a to the respective Application coordinated event display signal (strobe signal, enable signal) is controlled, the event being the extraordinary change in the measured loss (differential or absolute) and for switching on or off the readjustment of the negative loss component (- gT or -1 / RVMJ. EG) is used, or if necessary also external switching signals (corresponding to a sequence control, etc.) can be evaluated as an event signal

32. The method according to claim 30, characterized in that the readjustment of the negative loss portion contained in the total loss 1 / RVM + 1 / RVL + (-1 / RVMJMEG) (- gT or -1 / RVMJJEG) by a forward payment of the the negative loss share corresponding resolution units is carried out, whereby the number direction, step size and step speed (or number cycle) according to the measured deviation of the measuring voltage (us *) from the amplitude parameters according to the definition of the permissible modulation range (REFHJVIIN or REFHJVIAX) are derived by the Maintain the measuring voltage against any drift of the offset value in the specified measuring range (us *)

33. The method according to any one of claims 25, 28 or 29, characterized in that by readjusting the negative loss portion contained in the total loss 1 / RVM + 1 / RVL + (-1 / RVMJ EG) in the loss measurement (- gT or - 1 / RVMjvLEG) the measuring voltage (usl, us2) required for the loss measurement is kept in the corresponding measuring range (us *) for the respective application, whereby the controlled variable for the readjustment of the negative loss component (- gT or -1 / RVMJJEG) by measurement a compensation variable is detected via an additional sensor coil (LT) for the adjustment of the negative loss component (- gT or -1 / RVMJMEG) (cf. static relative measurement in the description).

34. The method according to claim 33, wherein said further temperature sensor coil (LT) takes a temperature measurement on the loss part to be measured (K) in such a way that a loss of the measurement coil LM by the temperature for a movement detection of the loss part (K) to be measured Sensor coil (LT) does not change the measured loss (cf. DE 42 40 739 C2), characterized in that the total loss in the temperature measuring coil (LT), which also includes a resistance (Rp_T) that can be adjusted by the manipulated variable (BD_T) and is included in the total loss. as adjustable loss [1 / RVL_T, or possibly 1 / RVL T + (-1 / RVMJMEG)], is constantly regulated and the manipulated variable obtained with this regulation (BD_T) as the temperature response (or the drift) of the offset value in the loss of measuring coil LM compensating value by including the drift compensating inclusion of the total loss of measuring coil LM (by appropriate regulation, or by setting 1 / RVL to LM accordingly) is equalized, whereby the measuring signal voltage (us *) on the measuring coil (LM) is kept in the predetermined measuring range.

35. The method according to claim 34, characterized in that the manipulated variable BD_T obtained by keeping the loss measured by the temperature sensor coil (LT) constant is used as a correction value in a correction table of the sensor.

36. The method according to claim 10 using a method according to claim 9, characterized in that the adjustable resistor Rp used for the data coding its loss value variation (1 / RVM) via a corresponding measuring filter (for example resonant circuit LM, Cp with series resistance) on one Line performs correspondingly switched on transmission side, this loss value measurement is measured by a corresponding, loss-measuring sensor (LM, Cp) of a reception side correspondingly switched on the line and a plurality of such reception sides can be provided for listening to the signal transmitted by the transmission side.

37. The method according to claim 36, characterized in that the measurement frequency for the loss measurement or ditto for the loss value variation (-1 / RVM) is fed in by an unmodulated carrier frequency signal, with several such feed points being provided along the line can

38. The method according to claim 36 and claim 37, characterized in that a plurality of filters matched to different filter frequencies or resonance frequencies are provided, and several filters matched to the same filter frequency can also be provided that the loss-measuring sensors for loss measurement as well as the variable resistances that perform the loss value vanation (-1 / RVM), use appropriately matched filters (e.g. parallel resonant circuits LM, Cp), and that a number of non-modulated carrier frequencies corresponding to the filter frequencies of the filters is fed in, with several supply points along the line for the supply of different non-modulated carrier frequencies can be provided.

39. The method according to claim 38, characterized in that each of the communicating receiving or transmitting stages simultaneously uses a plurality of filters, each tuned to different filter frequencies or resonance frequencies, for signal transmission, each filter frequency or carrier frequency, a bit of one data word consisting of n bits, and the bits of a data word are thus transmitted simultaneously (simultaneously) by the different carrier frequencies corresponding to the filter frequencies.

40. The method according to claim 10 using a method according to one of claims 1 to 9, or 25, or 28 to 39, characterized in that a negative loss portion (-1 / RVMJMEG) is fed into the line used for the signal transmission, wherein along the line, several feed points can also be provided for feeding in different unmoduced carrier frequencies, or if necessary the loss measurement sensors measure the total loss with a corresponding negative loss component, a method according to claim 30 possibly being used (for the operating point setting).

41 Method according to one of claims 10 or 36 to 40, or method according to one of claims 30 to 33, characterized in that the method is used for a data transmission carried out on existing electrical installation lines (for example computer networking, machine networking, etc.), the consumer are blocked from the carrier frequency by blocking filters (eg blocking choke)

42 The method according to claim 41, characterized in that said blocking filter is housed in each of the sockets of the existing electrical installation, the socket in addition to the standard plug device still having the plug connection for connecting the data connection

43. The method according to claim 42, characterized in that said sockets have a modification of the standard plug device in such a way that in addition to the contact holes (with the corresponding contact springs) there is a further contact hole with corresponding contact springs and these contact springs (or pair of contact springs) a plug provided on the mains plug to be inserted into the socket, bridging the blocking choke (or blocking inductance) provided as a blocking filter, two variants of such mains plugs being provided, for the first variant, a standard mains plug without plug, thus without bridging the in the plug-in blocking filter (or blocking choke), and for the second variant, said modified mains plug has the plug-in pin provided for bridging the blocking filter (or blocking choke) in the socket

44. The method according to claim 43, characterized in that an extension cable or a distribution socket strip is connected via the modified power plug with the plug-in pin provided for bridging the blocking filter (or blocking choke) in the socket, the other one for plugging in of the consumer cable (or its standard power plug) provided end (or socket) of the extension cable, or the distributor socket strip, the mentioned blocking filter, or blocking choke and the plug connection for connecting the data connection, and if necessary a further insertion hole with a pair of contact springs for a possibly further one Bridging possibility of the blocking filter (or the blocking choke)

45. The method according to claim 44, characterized in that the device via which the data transmission is carried out via the power supply is connected directly via said modified mains plug with the plug-in pin provided for bridging the blocking filter (or blocking choke) present in the socket Should (e.g. networking of computers) and in this device the blocking filter, or the blocking choke and the data separation is carried out, the modified mains plug can optionally be plugged into the socket of the electrical installation or into an extension cable according to claim 44, and the device in question Replacing the power cord can be connected to any standard socket or to the socket with a blocking filter (or blocking choke) provided with the standard in accordance with the standard connector, when the data signal is supplied via an external it cable (via data network card, external decoder, etc)

46. The method according to any one of claims 41 to 45, characterized in that several, for the carrier frequency signal of said data transmission through a blocking filter (or a blocking choke) separate data networks are provided over the existing installation, the blocking filter (or the blocking choke) for the existing electrical installation represents a connection with negligible impedance or resistance, and that between the data networks separated by the blocking filter (or blocking choke) a bidirectional directional coupler circuit is provided as active signal bridging, which is separated at each end by the blocking filter (or by the blocking choke) the signal line, or data line, has a loss modulation device, embodied in accordance with claim 10 or one of claims 36 to 40, as a transmitter or loss measurement device (sensor) as a receiver

47 The method according to claim 46, characterized in that the data networks separated by blocking filter (or blocking choke) use different carrier frequencies, the blocking filter (or blocking choke) blocks all the carrier frequencies used and the bidirectional directional coupler circuit or active signal bridging is designed for the carrier frequencies used is

48. The method according to claim 46 or claim 47, characterized in that the blocking filter (or the blocking choke) for separating the data networks (in each case) is accommodated in the standard installation boxes or terminal boxes of the electrical installation

49. The method according to any one of claims 46 to 48, characterized in that the circuit for feeding the unmodulated carrier frequency (s) (each) is housed in the standard installation boxes or junction boxes of the electrical installation

50. The method according to any one of claims 40 to 49, characterized in that the (in claim 40) feed of a negative loss portion (-1 / RVMJ.EG) (each) is housed in the standard installation boxes or junction boxes of the electrical installation

51 Method according to one of claims 1 to 50, characterized in that for said loss measurement of the total loss [1 / RVM + 1 / RVL], or [1 / RVM + 1 / RVL + (-1 / RVMJ.EG)] one Transputer circuit is used, which contains the above-mentioned sensor with a further RF coil for the sensor coil (LM), which is fed by an external RF transmitter, a transmitter device for data output and a receiver device for data input being provided, which also via RF transmitters communicates

52. The method according to claim 51, characterized in that the external RF supply takes place via an induction cable which is wound around a winding body provided on the sensor housing, within which the RF coil of the transputer circuit which has an inductive coupling is provided for wrapping the induction cable

53. The method according to claim 52, characterized in that the data transmission is carried out according to one of claims 10, or 36 to 40, wherein via the RF coil of the transputer sensor is fed into the induction cable serial loss resistance Vaπation of the transmitter, with a corresponding Working point setting (for the loss) through the serial negative resistance possibly fed into the induction cable (e.g. via the feed of the unmodulated carrier frequency (s)) and a plurality of transmitters or transputer sensors coupled serially into the induction cable can be provided, which can also make a loss measurement of the loss for data reception modulated by the transmitter for data transmission via the RF coil, the unmodulated carrier frequency also being used to feed the transputer sensors networked via the induction cable

54. The method according to any one of claims 51 to 53, characterized in that the sensors communicate with one another in succession within a chain formed by the sensors and from sensor to sensor the data of a respective sensor via the sensors chain up to the ends of the chain forward each connected control center, whereby the data transmission is coded in the data protocol and in the event of an error for an interruption occurring at any point in the chain, the sensor in question changes the data transmission in the data protocol and thus changes a path still free in the data network within the networked chain to one at the end of the chain Chain used existing center for the further calibration of the data (data redirection), whereby the sensor in question is identified by the center via its address used in the data protocol

55. The method according to claim 54, characterized in that the operational reliability for the data transmission is tested by comparing the data between the centers provided at the end of the chain and directly networked with one another, and the data passed on to the centers via the sensors chain

56. The method according to claim 54 or 55, characterized in that the respective location of the sensors for their diagnosis display, as well as in the event of a data redirection in the event of a fault, or in the event of a negative self-test, is recorded in one or more central computers by appropriate assignment storage

57 Method according to one of claims 51 to 56, characterized in that the transputer sensors are used in one of the following applications: a) a field of transputer sensors for the Geländesicheruπg for the detection of

Movements, whereby the movements of one or more appropriately networked control centers are reported, b) sensors for monitoring the rails arranged along a rail section (e.g. in the railway area), c) iur alarm systems for triggering the alarm via distance measurement, the distance to a corresponding electrically conductive loss ( z. B. a sheet) is dedicated, d) for authenticity certification of objects marked with the sensors or locking of packaging, e) for networking sensor coils embedded in the road for the

Vehicle monitoring, f) for position coding for monitoring and finding the storage locations for objects coded with the sensors (files, files, books, boxes, etc.),

£ for general sensor networking, e.g. in vehicles (e.g. car body), h) for monitoring and measuring high-voltage networks for locating interruptions and short circuits. i) as a sensor for vibration absorption, in particular structure-borne noise sensor and vibration sensor.

58. The method according to any one of the preceding claims, characterized in that the method performs a safety coding at the measuring point via the resistor (or loss control 1 / RVL) which can be changed via the variable (BD) by appropriate variation of the loss values according to a code pattern the property of a loss measurement of the sensor is checked (that is, first each adjustment and then remeasurement) in order to prevent the loss measured by the sensor from being compensated by inductive external injection of a loss (positive and / or negative), the method for a relevant safety application is provided (eg corresponding to an application according to claim 57).

59. The method according to claim 57f or one of claims 1 to 56, characterized in that the relevant sensor is supplied by a central HF transmitter, and to neighboring by loss-controllable conductor loops (eg conductor loop open, or closed, or . closed via series resistance) measures the loss for all existing conductor loops in sequence, the maximum loss value obtained from all measurements for a conductor loop or a corresponding pair of conductor loops indicating that conductor loop or that pair of conductor loops which (or that) is closest to the sensor concerned, or where the sensor in question is located between the relevant conductor loops of a corresponding pair of conductor loops, and the conductor track loops (e.g. in a row in accordance with a partition on a shelf) selectively switch on their loss one after the other by closing the loop, with a corresponding send / receive communication of the near or between the conductor loops (or near the Conductor loops) located transputer sensors, which are attached to the stored objects (boxes, files, files, etc.).

60. The method according to claim 59, characterized in that the loss-controllable conductor track loops of the measuring frequency used have corresponding filter properties, and the measurement frequency can be fed in via the conductor loop loops or via the transputer sensors of the coded objects.

61. The method according to claim 57e, characterized in that the coils let into the lane carry out a target tracking with their scanning result, in which corresponding memory locations are provided in a computer memory for the raster positions detected by the coils, which are used for scanning the driving behavior of the vehicles tracked by the coil scan are used in such a way that the program used passes through the vehicles through the intended storage spaces in the same way that the scan of the vehicles, based on the time grid resulting from the coils at the grid positions, is carried out by the coils, the memory patches are addressed according to a virtual shift register or FIFO (first in first out) and a memory track of the virtual shift register is provided for each lane, and corresponding spontaneous misfires of the scanning pulses (the coil loss measurement) when leaving a lane or spontaneous Additional impulses (the coil loss measurement) are assigned to the reeving into a lane, and that corresponding detection measures are provided for the registration of the vehicles (camera or cameras).

62. Circuit for carrying out a method according to one of claims 2 to 60, characterized in that the circuit is designed as a transputer circuit which has a precisely adjustable or precisely measurable negative component (- gT or -1 / RVMJJEG) which leads to the Sum loss is added as a measurement constant [1 / RVM + 1 / RVL + (-1 / RVMJ> IEG)] and the negative part of the loss (- gT) is generated by a tunnel diode that regulates the voltage of the tunnel diode to adjust its operating point About the saturation of the RF transformer inductance of the RF receiver coil for the supply voltage generation (by Simmen) that after a respective setting or readjustment of the differential resistance or conductance of the tunnel diode (- gT) the relevant voltage value of the operating point is stored and via a corresponding one Readjustment is maintained during the loss measurement of the sensor and that one for data exchange required transmission or reception level is provided.

63. Circuit according to claim 62, characterized in that the circuit has a power management unit (power management unit) which optionally between the transmission mode of the transputer sensor (for sending its data) and the measurement mode (for measuring the loss resistance, or Calibration and setting of the negative resistance or conductance (- gT)) switches, and possibly also a pause synchronizable via data communication, in which the transputer sensor is switched to standby.

64. Circuit for the method according to one of claims 2 to 63, claim 9, characterized in that the negative resistance of the differential negative conductance (-gT) of an alternating current directly or transformer via a transmission ratio (Tu) in parallel to the high-resistance measuring filter (eg parallel resonant circuit LM, Cp) coupled tunnel diode, or similar component is used.

65. Circuit according to one of claims 61 to 64, for performing a method according to one of claims 3 to 8 and according to claim 12 or claim 13, characterized in that for determining the differential negative resistance or conductance (-gT) of the tunnel diode the voltage value (uon) used for the adjustment (uon = uoff) corresponds to the voltage value (usl or us2) occurring for the measurement of the total loss [1 / RVM + 1 / RVL + (-1 / RVM JEG)], whereby for each the measurement steps (tl, t2) respectively relevant to these voltage values (usl, us2) are compared in order to determine the differential negative resistance or conductance (-gT) of the tunnel diode.

66. Circuit according to claim 65, characterized in that for determining the differential negative resistance, or conductance (-gT) of the tunnel diode, or an equivalent replacement component, for the comparison (uon = uoff) in addition to the filter circuit (eg resonant circuit LM , Cp) for the loss measurement of the total loss [1 / RVM + 1 / RVL + (- 1 / RVMJMEG)] another filter circuit or oscillating circuit (Lneg, Cneg) for the compensation of the differential resistance or conductance (-gT) the tunnel diode is present, the amplitude (uoff) of which is adjusted to the voltage values (usl or us2) that occur during the measurement of the total loss [1 / RVM + 1 / RVL + (- 1 / RVMJMEG)], this regulation being carried out during the Determination of the differential negative resistance or conductance (-gT) is switched over to the adjustment made here (uon = uoff) and the component for the negative differential resistance (eg tunnel diode) is also switched between the be The resonant circuits (LM, Cp or Lneg, Cneg) are switched accordingly.

67. Circuit according to one of claims 41bιs 50, characterized in that the carrier frequency for the said signal transmission by means of loss galvanization and loss measurement uses the protective conductor of the electrical installation as reference potential

68. The method according to claim 12 or 13, characterized in that the method according to one of claims 1 to 10, is carried out according to this method.

69. The method according to any one of claims 10, or 36 to 40, or claim 53, or 68, characterized in that the change in the loss for the loss measurement (EVS, Fιg.36a to Fιg.37) required for the loss measurement to be carried out at the receiving end (EVS, Fιg.36a to Fιg.37) Rpl, Rp2) on the transmitter side (SVS), whereby a code value on the transmitter side (SVS) is assigned as many loss values (e.g. two corresponding to Rpl, Rp2) than on the receiver side (EVS) measuring steps (tl, t2 with usl , us2) are required for the decoding of the code value, synchronization between the transmitting side and receiving side being provided for switching over the corresponding measuring steps.

70. The method according to claim 69, characterized in that the synchronization (SYNCR. Fιg.36a) by an external, provided for the synchronization line, or by a corresponding protocol on the signal line used (eg start-stop principle with detection of the start step by Time query, or frequency coding or level value query, etc.) takes place.

71. Application (application) for a method or a circuit according to one of claims 9 to 21 to 40, or 51 to 56, or 61 to 64, characterized in that the measuring coil (LM), which in the filter circuit (eg Parallel resonant circuit LM, Cp) is connected, from the sensor circuit of a coil (LMU or LM ^' in Fig. 48), which may have the transmission ratio for the transformer coupling of the negative resistance or conductance and the actual measuring coil (LMM) ( which may be designed as a high-temperature coil, for example).

72. Application (application) for a method or a circuit according to one of claims 1 to 21, or 25 to 40, or 51 to 56, or 61 to 64 or 67, characterized in that the loss through a hole of an electrical is measured through conductive material, the sensor (eg coil center of the measuring coil LM) is arranged in the line of alignment of the hole

73. Application according to claim 72, characterized by the use of the sensor in one of the following applications: a) the sensor measures the temperature through the hole in a hotplate in order to determine the loss of the metallic cookware or the loss of a metal insert used in the non-metallic cookware to measure, b) the sensor measures through holes in a coupling plate (carrier plate of the lining) to determine the adhesion of the coupling, c) the sensor measures through the hole in a metallic conductive material to determine the adhesion of another material lying on this material.

74. Application (application) for a method or a circuit according to one of claims 1 to 21, or 25 to 40, or 51 to 56, or 61 to 64 or 67, characterized in that the sensor, in particular for a transputer application is used for strength-distance measurement of a screw or bolt connection via an approximation measurement of the deflection of a washer (regarding head and / or nut)

74. Application (application) for a method or a circuit according to one of claims 1 to 21, or 25 to 40, or 51 to 56, or 61 to 64 or 67, characterized in that the sensor, in particular for a transputer application is used for strength-distance measurement of a screw or bolt connection via an approximation measurement of the deflection of a washer (regarding head and / or nut).

75. Application (application) for a method or a circuit according to one of claims 1 to 21, or 25 to 40, or 51 to 56, or 61 to 64 or 67, characterized in that the sensor measures a temperature over a very high degree makes a thin needle, which is guided through the center of the measuring coil and held accordingly (e.g. by a ceramic holder).

76. Application (application) according to claim 75, characterized in that the sensor is still a pressure sensor is further arranged, this combination sensor is screwed into a pipe housing, similar to a spark plug in the engine compartment, and the data for recording the pressure diagram, or Temperature chart of the engine records.

77. Application (application) for a method or a circuit according to one of claims 1 to 21, or 25 to 40, or 51 to 56, or 61 to 64 or 67, characterized in that a (each) sensor coil Ribbon cable is used, and such sensor coils for waking the detection of vehicle movements in the lane are set in appropriate grid spacings

78. Kontaktierungsvornchtung for contacting an induction cable according to claim 53, characterized in that the device has a winding body (Fig. 43) around which the induction cable is wrapped in one or more loops, a cover cap being provided as a pull-off protection, which is pushed over the winding body and that the inductive contact is made via a coil (HF coil) fixedly arranged on the inside of the winding body (which is thus located in the center of the loop of the induction cable)

79. Application (application) according to claim 77, characterized in that the ribbon cables are contacted on both sides by press connectors, which also have the circuit board with the corresponding wiring of the ribbon cable (Fig. 44, Fig. 45) and that the connectors of all Cables, which are located on the outside of the road at the roadside, each have the circuit of the transputer sensor for loss measurement via the ribbon cable (LM) and have a contacting device for contacting according to claim 78 and are networked by a looped-through induction cable.

80. Application (application) for a method or a circuit according to one of claims 1 to 21, or 25 to 40, or 51 to 56, or 61 to 64 or 67, characterized in that the sensors are each arranged on the inside of a vehicle body are, and make a distance measurement to the inner wall, the sensors being networked with one another and connected to an accident recorder for the temporal recording of the measurement result, the recording beginning when a sensor indicates a corresponding event.

81. Application according to claim 80, characterized in that the sensors each have a contact connection according to claim 78, wherein the induction cable is looped through the sensors and is supplied to an appropriate control center with an RF signal, or communicates with the data exchange device of this control center accordingly ,