DE10112816A1 - Signal transmission method using transceivers has adaption parameters for useful signal transmission obtained from measurement of interference along transmission channel in off-line mode - Google Patents

Abstract

The transmission method has an initial interference measurement provided in the off-line mode with the transmitters of the transceivers connected to the transmission channel deactivated and used for provision of adaption parameters, for subsequent useful signal transmission,via a given adaption parameter algorithm.

Description

The invention relates to a method for transmitting sig using transceivers on a channel, such as on Kup cable, especially based on xDSL transmission technology, in which the channel before the useful signal transmission is measured and from the measurement result adaptation pair meters can be obtained for the useful signal transmission.

When transmitting signals, in particular by means of the ak current xDSL transmission technology (DSL stands for digital Subscriber Line) make considerable range differences on the one hand and strongly differing crosstalk behavior on the other hand, extremely different bit requirements rate, the minimum transmission power and the like. For one efficient use of channel capacity is the use of adaptive transceivers that focus on the transmission area Setting the conditions of the channel is essential. Appropriate Adaptation procedure that takes place during the connection establishment or after a connection break on the property adapting the channel have so far been used. Such calibration methods are usually referred to as sta table. In contrast to the dynamic adaptation, which also works The bit rate varies during transmission. In connection with the addressed xDSL technology, according to the State of the art uses static calibration methods that work only actively, d. that is, to measure the Channel for the transmission of a test signal or a test signal pattern are instructed and usually in particular which are extremely ineffective with regard to the adaptation times are cient. Currently xDSL transceivers are generating for calibration on their transmission medium or on their channel as a rule Test signals or test sequences. Iterative procedures solve it the adaptation problem by testing different ones  Transceiver configurations on the channel. Mo is also known dems that generate well-defined patterns that the end measure individual parts of the transmission belt, see V.34 and V.90 analog modem, or measuring the whole Frequency bands, such as B. at DMT (Discrete Multi Tone) Technology, allow. All previous procedures are common sam that they work actively, d. that is, every new calibration feeding a test signal or a test signal pattern on the channel as mandatory.

The invention has for its object a method for Transmitting signals on a channel using transceivers to create the kind mentioned at the beginning, which with short Adap passive adaptation to the ge used channel guaranteed.

This task is solved by the characteristic features of claim 1. Advantageous further developments of the invention are specified in the subclaims.

The invention therefore provides that the measurement on egg ner interference signal measurement in offline mode with deactivated Transceiver transmitters based, and that the adaptation pair meters from the measured interference signals based on A- Priori knowledge of the channel and one of the adaptation parameters descriptive adaptation algorithm or an estimate be obtained via adaptation parameter limits (bounds).

In other words, the invention proposes a static adap tion method for transmitting signals of the type that works purely passively, so it does not stop Exchange of defined measurement sequences and / or measurement signals between sender and receiver. requirement for the procedure is knowledge of the transfer behavior of the channel (prior knowledge) at the time of measurement corresponding to a static or quasi-static channel. in the In the case of a duct formed by copper cables, this is the condition  always sufficiently fulfilled, because a one-time ver measurement of the copper cable or a two-wire cable for everyone further measuring processes is completely sufficient, as long as no significant modification of the cable installation follows.

To the example of a copper twin wire (two-wire cable or Twisted Pair Line) is used because for this channel variant the use of the Ver driving is particularly promising. The invention However, the method is readily applicable to other systems from the wired or wireless transmission technology transmission bar that have similar requirements.

Since the method according to the invention is a purely passive measure solution, it is with the crosstalk at the stand technical problems, ty typically one that measures at full transmit power Transceiver provides. In addition, the purely passive affects Measurement favorable on the adaptation times, like after is explained in more detail below.

The method according to the invention sees a static adaptation in two phases, one in itself in practice known third phase that connects booting the channel. The The first phase therefore sees an offline measurement of the sturgeon signals before. The second phase sees an adaptation to the Ka based on the interference signal measurement in the first phase and based on prior knowledge of the channel. This is followed by the third phase mentioned, the Provides booting the channel under parameter set exchange.

The interference signal measurement is advantageously carried out at on ma ximal bandwidth set reception filter of the Receiving state of the transceiver receiving part. here through an optimal transmission of the useful signal he enough. A selection of the optimal location and  Bandwidth and thus the baud rate of the transmission band be guaranteed.

Furthermore, multiple detection is advantageously carried out partly in the form of random samples from the Stör signal measurement provided. A distinction must be made between a short-term recording of several samples for the Er Increasing the static safety of the measured values and long-term detection via the one profile of the jammer can be derived in particular via the time axis. Out the random samples are preferred limit values / characteristic curves (Bounds) derived.

According to the invention is also a longer-term interference signal measurement Solution provided to decouple the so-called QoS crisis to achieve series of instantaneous values (QoS stands for Quality of service, inter alia, by the bit or frame error rate is described). This is an averaging the variance of the interferer reached. The longer-term sta tical examination supports a far better prediction tion of future disturbance behavior. That in the extraction of A priori knowledge that adapts to the parameters becomes advantageous obtained by separate measurement of the channel. As an alternative and in addition to this, the a priori knowledge can be obtained from a previous operating case of a useful signal transmission be preserved.

The adaptation parameters are advantageously made from Adap goals, such as a maximum baud rate / bit rate, minimum Transmission power at a given baud rate / bit rate and given QoS derived.

The above-mentioned third phase of the fiction procedure, booting the channel with a parameter set exchange, advantageously provides that the channel according to Er setting of a set of adaptation parameters by hand shake between NT (network termination)  and LT (line termination) side) is booted. The handshake is ent according to the invention neither in a start-up sequence of the useful signal transmission tegrates or takes place within the framework of a default connection between the transceivers of the channel.

The invention is illustrated below with reference to the drawing explained in detail; in this show:

Fig. 1 shows schematically in the manner of a flowchart the sequence of the method according to the invention, and

Fig. 2 is a diagram of the noise power spectral density as a function of the associated Bounds.

Fig. 1 shows the process schematic for transmitting signals by means of transceivers on a channel. The reference numeral 100 denotes an idle mode, while the reference numeral 101 denotes a useful signal transmission mode. Between the operating modes 100 and 101 , a calibration mode is connected, which is designated by the reference number 102 . This operating mode is also referred to as a transceiver start-up.

The calibration mode 102 comprises, as a first step without loading the channel with transmission signals, that is to say in the idle mode or in offline mode with deactivated transceiver transmission parts, an interference signal measurement, which is designated by the reference number 103 . Within the scope of this measurement, the noise lying on the channel is recorded to a certain extent. Measurement 103 is explained in more detail below.

The interference signal measurement 103 is followed by an adaptation algorithm, which is designated by the reference number 104, which is based on the measured interference signal and which also takes into account prior knowledge about the channel, which is generally designated by the reference number 105 . Before the transition to the useful signal operating mode 101 , step 104 is followed by booting of the line or the channel, as denoted by the reference number 106 .

The individual method steps 103 , 104 , 105 and 106 are explained in more detail below.

Phase 1 Offline measurement of the interference signal

As already mentioned, the interference signal is measured in offline mode with deactivated transceiver transmitters. In other words, this measurement is one Passive measurement, preferably with a broadband measurement solution of the transmission bandwidth.

The reception filter of the transceiver reception section, which is used for Interference signal measurement is used, is preferred for opti mation of the transmission to the bandwidth of the transmission signal, which is determined by the baud rate. The Off line measurement with deactivated transceiver transmitters leaves an opening of the reception filter on maximum band width. This allows a selection of the optimal location and Bandwidth and thus the baud rate of the transmission band be guaranteed.

The deactivation of the transcei provided according to the invention transmitting part on the opposite side as well as the one on the same Side transceiver transmitter for the opposite direction (optional only in case of equality) avoid falsifying the Measurement results. The passive measurement closes due to its Nature any self-interference. This measurement thus forms  an essential prerequisite for the measurement of channels with a strongly frequency-selective character, such as a copper pair that has a resolution of more than 30 dB over the frequency axis for most xDSL variants for changed.

The qualification of the channel or the adaptation to the channel takes place before the actual boot process. That is, before the transceiver starts up its transmitter section, they are essential transmission parameters already known. Insbeson the calibration of the transceiver with maximum transmission performance, as with current procedures of the Kind of usual, not applicable. Multiple measurements with usually extremely high bandwidth, as in previous methods with i terative approach is also unnecessary. The egg the usual measuring procedure used in conventional methods usually the most significant system malfunctions Causing neighboring cables is passive and therefore has none Influence on the environment.

The interference signal measurement is preferably carried out in the form of a stitch rehearse. A distinction is made between a short timely collection of several samples to increase the sta statistical security of the measured values, as with for example of mean values or (worst case) bounds, and a long-term recording, which enables the creation of profiles nes troublemaker, especially over the timeline. In this connection is, for example, a division of Canal operation in the morning, afternoon, evening and night operation conceivable.

Through long-term observation of interference signals on the Ka nal is also a decoupling of the QoS criteria from instantaneous values  possible. So a longer-term observation leads device for averaging the variance of the interferers. Only they will takes into account the current properties of the interferers, this inevitably leads to an unstable QoS criterion. That he Process according to the invention opens up the possibility of one here longer-term statistical investigation, which is a far cry guarantee better prediction of future disturbance behavior achieves than was previously possible with the prior art, at which transmission characteristics typically only be measured during the actual boot process.

The generation of the profiles mentioned above is permitted a prediction of the availability of bandwidth or bit rate and associated QoS with the aim of different Classify services. The operator of the channel will do so given the opportunity to measure his customers to offer tailor-made offers, namely when and which Service with what quality, how quickly and at what cost can get. In addition, the operator receives information about even necessary extensions or modifications of his Network.

Phase 2 adaptation algorithm

The information obtained in phase 1 or in step 103 about the interferer of the channel and the a priori knowledge about the transmission properties of the channel according to step 105 fully qualify the channel.

The a priori knowledge of the channel can vary Way to be attained. For example, this knowledge about a separate channel measurement can be obtained. To this end For example, the transceiver itself can be used.  

Alternatively, the a priori knowledge can be obtained from a previous operating case. In principle, however, the channel must remain invariant at least approximately between its last measurement and the booting of the transceiver in step 106 (time invariance or quasi-time invariance). This is a necessary condition. The same applies to the stochastic description of the interference signal (stationarity or quasi-stationarity).

The adaptation parameters or coefficients are derived from Adap objectives derived. These goals include maximum Baud rate or bit rate, minimum transmission power if specified ner baud rate and bit rate and given QoS and minimization of Adaptation time. The adap tion parameters derived: QoS as a function of baud rate / bit rate, system reserve (in dB) for defined baud rate and fixed QoS and equalizer coefficients for the fixed baud rate.

Accordingly, the task of the adaptation algorithm according to step 104 is to create a functional connection between the function parameters on the one hand and the description of the channel on the other.

The adaptation parameters, for example the QoS or the Equalizer coefficients can be measured with sufficient accuracy using a suitable algorithm from the channel parameters conduct. This procedure, the adaptation parameters using The skilled worker is able to describe the algorithm on this Ge offers the technology familiar, but usually very expensive dig. It is therefore preferred at least for certain Adap tion parameters in practice on the following less complex variant used.  

The adaptation parameters can thus be obtained from an estimate using bounds, that is to say limit values / characteristic curves, as shown for example with reference to FIG. 2. Fig. 2 shows the noise power spectrum and its Bounds in comparison equal to the detected measured values. The corresponding values for the bounds are preferably stored in a table as estimated values.

Both the noise power density spectrum and the transmission function of the channel as a form of representation of the respective channel parameter can be estimated using the bounds. This is shown in FIG. 2 for a noise power density spectrum. For example, Bound 3 forms a worst-case estimate. For a more detailed description, the spectrum can also be segmented via the frequency axis. The bounds for the transmission function of the channel, on the one hand, for the noise (measured values), on the other hand, provide an estimate for the respective channel parameters, such as the bit error rate as a representative of the QoS.

Phase 3 Booting the canal

The method explained in more detail above with the aid of steps 103 to 105 initially only allows the downstream to be measured on the NT side or on the LT side of the upstream. For the transition to the useful signal mode 101 during booting of the transceiver, the agreement of a coherent parameter set between LT and NT is therefore a basic requirement. This can be done in different ways. The following two variants are preferred: on the one hand the integration of a handshake in the actual start-up sequence and on the other hand the establishment of a default connection with a defined data rate, via which the handshake is then carried out.

Claims (12)

1. A method for transmitting signals by means of transceivers on a channel, such as on copper cables, in particular based on the xDSL transmission technology, in which the channel is measured before the useful signal transmission and adaptation parameters for the useful signal transmission are obtained from the measurement result that the measurement provides for an interference signal measurement in offline mode with deactivated transceiver transmitters, and that the adaptation parameters from the measured interference signals based on a priori knowledge of the channel and an adaptation algorithm describing the adaptation parameters or an estimate be obtained via adaptation parameter limits (bounds). 2. The method according to claim 1, characterized, that the interference signal measurement is turned on at maximum bandwidth the receive filter that is in the receive state Chen transceiver receiving part takes place. 3. The method according to claim 1 or 2, characterized, that the interference signal measurement is a short-term detection of Samples to increase the statistical security of the Readings. 4. The method according to claim 3, characterized, that limit values / characteristic curves (bounds) are be directed.   5. The method according to any one of claims 1 to 4, characterized, that the interference signal measurement for interference profile detection and / or decoupling of the QoS criteria (QoS = Quality of Ser vice) of instantaneous values in the long term. 6. The method according to any one of claims 1 to 5, characterized, that from the interference signal measurement profiles of properties of the Channel, in particular availability of bandwidth and associated riger QoS (QoS = Quality of Service) can be generated. 7. The method according to any one of claims 1 to 6, characterized, that the flowing in the acquisition of the adaptation parameters A priori knowledge through a separate measurement of the channel is obtained. 8. The method according to any one of claims 1 to 7, characterized, that the flowing in the acquisition of the adaptation parameters A priori knowledge from a previous operating case Useful signal transmission is obtained. 9. The method according to any one of claims 1 to 8, characterized, that the adaptation parameters from adaptation targets, as with for example, maximum baud rate / bit rate, minimum transmission power at a given baud rate / bit rate and given QoS (QoS = Quality of Service).   10. The method according to any one of claims 1 to 9, characterized, that the channel after creating a set of adaptation pa parameters by handshake between those copied over the channel pelt transceivers is booted. 11. The method according to claim 10, characterized, that the handshake into a start-up sequence of the useful signal transmission is integrated. 12. The method according to claim 10, characterized, that the handshake within a default connection between between the channel's transceivers.