DE10226329A1 - Mobile telephone with distance, angle or speed measuring functions has evaluation unit for measuring propagation time of received laser beam and calculates associated distance - Google Patents

Abstract

In addition to the modules required for telecommunication, the mobile telephone includes a laser transmitter-receiver with a laser source, and a lens for focussing the emitted radiation. Measurement data from an evaluation unit are supplied to a unit for transmitting the data via a mobile radio network (12) to a remote station, e.g. a personal computer (10). The evaluation unit measures the propagation time of a received laser beam (7), and calculates the associated distance.

Description

The invention relates to a mobile telecommunications terminal, which Measurement of lengths, angles and / or speeds enables. This is preferably a mobile phone, which if necessary in addition to the measurement of the aforementioned variables, their verification with regard to allows a comparison of the sizes with predetermined target values.

As part of civil engineering projects are involved in construction sites Different local conditions mostly extensive surveying work perform. On the one hand, this concerns the measurement of lengths and angles during the actual construction phase and on the other hand their review or their comparison with the construction plans during and after the construction phase. The Even today, measurements are still partially carried out using classic tools such as for example the ruler or the tape measure. But already in extensive dimensions of electronic aids are used for measurement. At the Laser measuring devices, so-called theodolites or Tachymeter used. With these measuring devices you can both Measure directional angles and distances, as well as height differences. The Measurement is based on determining the running time of one of the theodolites emitted and by him after reflection on an object again received laser beam and the possible derivation of the distance from the Running time.

The devices enable very precise measurements. However, the captured As a rule, data is usually recorded by hand and then into the Transfer architectural drawings or manually into a computer for adoption entered further processing software. When transferring the Measured data, errors occur more frequently. This does not result in part insignificant additional costs in eliminating these errors. To make matters worse in addition, measurements more often in places that are very difficult to access are required, for which the currently available devices are often only conditional suitable and where the devices are difficult to read, so that this with a manual transfer of the measured values on paper or in one Computer the risk of errors continues to increase.

The object of the invention is to provide a handy device which a simple measurement of lengths, angles and / or possibly also of Speeds and in particular a manual transmission of the Measured values recorded with the device can be dispensed with for further processing makes.

The task is carried out by a mobile communication device with the features of the main claim solved. Advantageous training and development of Invention are given by the subclaims.

The device according to the invention is a mobile device Telecommunications terminal, preferably a mobile phone, which in addition to the Functional groups for telecommunications at least via a transmission and Receiver unit for laser radiation (LSE), via an evaluation unit and via a function group coupled to the evaluation unit for transferring the in the evaluation unit processed measurement data to a unit for transmission the measurement data has a mobile network to a remote site. there the LSE comprises a laser radiation source, an optical system for decoupling the from the laser radiation source emitted laser radiation and a receiver for Laser radiation. The evaluation unit includes means for measuring the transit time one emitted by the LSE and by it after reflection on one Object received laser beam again, and means for calculating it Time corresponding distance to the reflecting object.

To use the measurement functions of the mobile telecommunications terminal there may be separate controls on this. However it is also with mobile phones of conventional design so that their buttons Have multiple functions. Intelligent control prevents the user unnecessarily many to access the different functions Must press keys. In spite of the functional expansion of the To be able to maintain compact dimensions according to the invention, this is According to an advantageous embodiment, designed to trigger the measurement functions of its usual, also for actual telecommunications serving controls with a designed for this purpose Multiple functions can be used.

A further improvement is provided by a for the practical use particularly preferred development of the invention achieved. The mobile telecommunications terminal is in accordance with this development equipped with a voice control, by means of which the operation of the Measuring functions and possibly also the telecommunications functions can be voice controlled.

With regard to the most versatile possible use, mobile telecommunications terminal according to the invention according to another Design via means for mounting on a leveling device. That at the Device-mounted device can be used in this way as a kind of electronic Spirit level used for testing over long distances become.

In a further development of the invention, there are still some advantageous additional functions provided by which the device can optionally be expanded. One of these Continuing education concerns the possibility of two devices with comparable Use functionality for high-speed data transmission. This is possible, if both devices with a Laser transmitter / receiver unit (LSE) are equipped and beyond a modulation and demodulation unit that interacts with the LSE Have modulation of the laser beam, part of which are circuit parts for the Coding or decoding of data for their transmission according to one of the common transmission standards. Are from the prior art Mobile phones or cell phones with an infrared interface for data transmission already known. In this respect, the circuits used here or circuit elements only to the use of a laser instead to adapt to a conventional IR radiation source. The result is Advantage that with such a trained mobile Telecommunications terminal a high-speed data transmission even over large Distances can be made. As a further advantageous embodiment, the Arrangement of an additional lamp provided on the device. This can be used are often difficult to access measurement locations and so far to illuminate poorly lit measuring locations.

As is usually the case with theodolites, the laser radiation source preferably a source emitting in the infrared range is used. According to one embodiment variant, however, a laser is used, which is in the range of visible light, preferably at a wavelength emitted between 620 nm and 690 nm. Because light of this wavelength, in In contrast to infrared radiation, almost every object is more or less good is reflected when using a device designed in this way when measuring the distance to the use of an otherwise often required additional reflector are mostly dispensed with. The positive results Side effect that that with a laser emitting in the visible range equipped device can be used as a laser pointer for presentations.

In the following, the invention is intended to be repeated using an exemplary embodiment are explained in more detail. In the accompanying drawing:

Fig. 1 shows a schematic diagram of the device designed according to the invention in its application for length measurement

Fig. 2 shows the device of FIG. 1 in a somewhat more detailed representation

FIGS. 3 and 4 further possible applications of the device correspondingly provided embodiments or further developments.

In Fig. 1 the principle of length measurement or distance measurement (in the further MTEG) reproduced by means of the inventively embodied mobile telecommunications terminal 1 in a principle representation. The measuring process is triggered by a person 11 operating the device by means of an operating element 8 provided on the MTEG 1 . The optics of the laser transmitter / receiver unit (LSE) 2 are directed at the object 6 or, if applicable, at a reflector attached to it, to which the distance is to be determined. The reflected laser radiation 7 is received by the LSE 2 of the mobile telecommunications terminal 1 and the transit time of the laser beam 7 is measured by means of an evaluation unit 3 arranged therein. From this, the distance, ie the distance, is determined in a known manner. The distance measurement data are preferably temporarily stored in the mobile telecommunications terminal 1 and finally transmitted to a remote station 10 , in the example a computer or PC, via the mobile radio network. For example, construction drawing software runs on the PC 10 , in which the incoming data can be further processed immediately. According to the drawing, the system can also be designed bidirectionally. This makes it possible, for example, to transmit data stored in a database or in the memory of the PC 10 to the MTEG 1 for the construction plan. Using the MTEG 1, the user 11 can now check directly on site whether the specifications of the construction plan are being met. He can measure the corresponding dimensions with the MTEG 1 , determine the difference to the data according to the construction plan, and use an evaluation function to determine whether the measured actual data is within the tolerance range.

The MTEG 1 used by the measuring force 11 is shown again in somewhat more detailed form in FIG. 2. However, this is only a basic illustration. The MTEG 1 , in the example a mobile phone, has, in addition to the functional groups for telecommunications typical of these devices, according to the invention a transmitting and receiving unit for laser radiation 2 . This LSE 2 comprises a laser radiation source, optics for coupling out the radiation emitted by this radiation source and a receiver for receiving reflected laser radiation (not shown in detail in the drawing). Furthermore, components of the device are an evaluation unit 3 with an arithmetic part and a function group 4 coupled to this unit, which makes it possible to transfer measured data or data that has already been prepared in a suitable form to the telecommunications units in order to transmit them to the remote station 10 via a mobile radio network 12 (here the PC 10 ) to transfer. In addition to these units 2 , 3 , 4 , the device shown in the example also has an additional lighting source or lamp 9 , ie a flashlight function. This makes it possible to carry out measurements even in places that are difficult to access and which are not illuminated by daylight. The laser radiation source can be a source emitting in the infrared range. However, it is also conceivable to use a laser operating in a wavelength range from 620 nm to 690 nm. This has the advantage that light of this wavelength is reflected on almost every object 6 . It is therefore possible to carry out a distance measurement without additional reflectors.

Of course, the possibility of distance measurement when using the corresponding software in MTEG 1 also opens up the possibility of speed measurement. For this purpose, it is known that, for a moving object only, the distance has to be determined twice in succession and the resulting difference divided by the time span between the measurements. The first measured distance value is temporarily stored in a memory unit which is preferably to be provided or which is present anyway in connection with the telecommunication functions.

The use of a laser that emits in the visible light range makes it possible to use the device as a laser pointer in presentations. It is also conceivable, regardless of the wavelength of the laser, to bring two devices designed according to the invention into contact with one another and to use them for high-speed data transmission by means of the laser. The last two options are outlined by FIGS. 3 and 4. List of reference numerals used 1 Mobile telecommunications terminal (MTEG)
2 laser transmitter / receiver unit (LSE)
3 evaluation unit
4 functional group
5 unit for radio transmission
6 object
7 laser beam
8 control element (s)
9 lamp
10 remote station, PC
11 user or measuring force, person
12 cellular network

Claims (7)

1.Mobile telecommunications terminal ( 1 ), preferably a mobile phone, with functions which can be activated via corresponding control elements for measuring lengths, angles and / or speeds and which, in addition to the function groups for telecommunications, has at least one transmitter and receiver unit for laser radiation (LSE) ( 2 ) with a laser radiation source, optics for decoupling the laser radiation emitted by the laser radiation source and a receiver for laser radiation, via an evaluation unit ( 3 ) and via a function group ( 4 ) coupled to the evaluation unit for transferring the measurement data prepared in the evaluation unit to a unit ( 5 ) for transmitting the data via a mobile radio network ( 12 ) to a remote station, the evaluation unit ( 3 ) having means for measuring the transit time of one transmitted by the LSE ( 2 ) and received again by it after reflection on an object ( 6 ) Laser beam ( 7 ) and means for Calculation of the distance to the reflecting object ( 6 ) corresponding to this transit time and, if appropriate, for further computational processing of the measurement data. 2. A mobile telecommunication terminal (1) according to claim 1, characterized in that provided as control elements for triggering the measurement functions with multiple function occupied operating elements (8) which simultaneously serve for use of the telecommunications functions. 3. Mobile telecommunications terminal ( 1 ) according to claim 1, characterized in that the operation of the measurement functions and / or the telecommunications functions is voice-controlled. 4. Mobile telecommunications terminal ( 1 ) according to claim 1 or 3, characterized in that it has means for mounting on a leveling device and after mounting on such a device can be used as an electronic spirit level. 5. Mobile telecommunications terminal ( 1 ) according to claim 1 or 4, characterized in that its LSE ( 2 ) is designed for high-speed data transmission with a device of comparable functionality. 6. A mobile telecommunications terminal ( 1 ) according to claim 1 or 3, characterized in that it has an additional lamp ( 9 ) which can be used as a flashlight. 7. Mobile telecommunications terminal ( 1 ) according to claim 1 or 2, characterized in that its laser source emits laser radiation with a wavelength in the range of visible light, preferably with a wavelength between 620 nm and 690 nm, so that the device as a laser pointer is usable.