DE19744731A1 - Radar system, especially a FMCW system - Google Patents

Abstract

The radar system has a variable frequency oscillator (1), an evaluation and control unit (2) and at least one reception signal path (11-17,21-27,31-37) via which a received signal is fed to the evaluation and control unit, which receives an oscillator feedback signal (8) representative of the instantaneous oscillator output signal frequency via a separate path. A test signal can be generated (18,28,38) and fed into part of the reception signal path for testing the functionality of at least part of the reception signal path. The test signal is derived from the oscillator feedback signal.

Description

The present application relates to a radar system, in particular special according to the FMCW principle, according to the preamble of Main claim. It also concerns an order for a self-test of such a radar system.

State of the art

A generic radar system according to the preamble of The main claim is, for example, in DE 38 30 992 A1 described. This radar system is one Radar altimeter built on the FMCW principle and works in the C-band. According to this document, the device is in MMIC technology with completely digital evaluation and Fashion control designed. There is also an execution described as a self-test facility. In the self The VCO of the radar system sends testmode at a fixed frequency quenz by a high-frequency switching of a switch a switching frequency is superimposed in the receiving branch. This The switching frequency then appears in the digital evaluation of the microcomputer as a simulated height. So that's it possible to cover all occurring distances by varying the To simulate switching frequency. The one proposed here  Self-test device used, especially with the called switches, components that also for verbes improvement of an ECM strength with regard to military Applications. For a radar system, however, that on the Measures mentioned here to improve the ECM strength could do without, the realization of this would be described Self-test device an increased or additional wall mean.

From US 4,968,968 a system for measuring and is known Correction of waveform modulation errors in a radar system, which frequency-modulated signals and a digital controlled waveform generator used. To correct Amplitude and phase errors in linear frequency modulated The transmission signal becomes a small part in a calibration mode of the transmitter output signal into the receiver input pelt. That mixed down in the receiver during this mode te signal is a nominally constant intermediate frequency signal whose phase and amplitude fluctuations from Ver strains within the radar system. This one described device solves the problem, slowly ver changing amplitude and phase errors within the radar suppress systems. A real self test, especially the radar signal evaluation, using an injected, Simulated radar target is not possible with this.

Object, solution and advantages of the invention

The object of the present invention is a genus according to the radar system, which is an alternative and Self-test device that is particularly easy to implement owns.  

According to the invention, this object is achieved with a generic Radar system solved in that a test signal from a Oscillator feedback signal is derived. Especially easy to implement and therefore advantageous if the test signal and said oscillator feedback signal are approximately identical in shape and frequency. Another easy to implement and therefore advantageous design device of the invention is to provide signal lines Signal routing of the oscillator feedback signal at least at a point so close to the signal lines of the Receive signal path that an evaluable strong signal coupling of the oscillator feedback signal in the receive signal path. In this way, a simulated radar target for performing a self-test very simple and inexpensive in the received signal path of the Radar system are coupled. It is an advantage here liable if the oscillator feedback signal can be switched off or can be suppressed. Another embodiment of the invention is that the oscillator feedback signal by means of a circuit network in the received signal path can be coupled. It is also advantageous if the Oszil lator, from whose oscillator feedback signal the test signal is derived to generate the transmission signal of the Radar system serves. This implies that no additional Oscillator is needed to generate a test signal. Further preferred embodiments of the invention result itself from the further subordinate claims.

The advantage of the radar system according to the invention is that it is a Has self-test facility that is simple and cost is inexpensive to implement because it is largely or even is based solely on circuit components that in principle available with a generic radar system are. There are therefore no additional function blocks or  extensive new circuit measures required. About that is also the test signal, especially the one before preferred embodiment, over the entire relevant Frequency range variable. So you can also Simulate radar targets at any distance. Farther is the test signal with regard to its own properties very well known, as it is made exclusively in the radar system even existing and in the preferred case very high quality Circuit components is generated. Finally, the Invention an alternative to the self-test device of known from DE 38 30 992 A1 radar altimeter, the not on the presence of components for strengthening is dependent on an ECM strength.

Description of exemplary embodiments

Exemplary embodiments of the invention are described below a drawing explained. Show it

Fig. 1 is a block diagram of a first embodiment example and

Fig. 2 is a block diagram of a second embodiment example.

Fig. 1 shows a block diagram of an inventive, in this case three-beam radar system according to the FMCW principle. The output signal of a variable in frequency oscillator (VCO) 1 is three, parallel to each other arranged transceiver switches 12 , 22 and 32 leads leads. From there it arrives at three transmission-reception elements 11 , 21 and 31 arranged parallel to one another. A second output of the transmission-reception switches 12 , 22 , 32 is fed to three reception mixers 13 , 23 and 33 arranged parallel to one another. At a second input each of the receiving mixers receives the known structure of a homodyne FMCW radar system corresponding to a small portion of the output signal of the oscillator 1. This signal portion is the receiving mixers 13 , 23 , 33 via signal couplers 14 , 24 and 34 supplied. The output signals of the three receiving mixers 13 , 23 , 33 are each fed to a United 15 , 25 , 35 . The output signals of the United amplifiers 15 , 25 , 35 pass through filters 16 , 26 , 36 to an analog-to-digital converter 17 , 27 , 37. From there, digitized receive signals then reach an evaluation and control unit 2. The circuit components start from The transmit / receive elements 11 , 21 , 31 via the receive smischer 13 , 23 , 33 to the analog-digital converters 17 , 27 , 37 form three receive signal paths constructed in parallel to one another. In the exemplary embodiment preferred here, the frequency of the oscillator 1 is regulated by the evaluation and control unit 2 . For this purpose, an initially digital oscillator control signal is formed in the evaluation and control unit 2 , which is converted into an analog oscillator control signal via a digital-to-analog converter 3 and then supplied to the oscillator 1 . From the output signal of the oscillator 1 , a small signal component is coupled out via a signal coupler 10 . This is preferably implemented in a lower frequency range. In the embodiment shown here, this is done by mixing down the signal portion coupled out by the oscillator 1 in a mixer 4 . For this purpose, the mixer 4 is supplied with a reference signal stabilized via a dielectric resonator (DRO) 5 . The output signal of the mixer 4 is subjected to pulse shaping 6 and then fed to a frequency divider 7 . The output signal of the frequency divider 7 forms the oscillator feedback signal 8 , which the evaluation and Steuerein unit 2 is supplied. Via a control line 9 , the evaluation and control unit 2 can, for example, switch the frequency divider 7 to high impedance, as a result of which the oscillator feedback signal 8 is switched off or suppressed. The generation of the oscillator feedback signal 8 is shown here according to a preferred embodiment. Alternatively, a frequency divider chain alone could also be present, as shown for example in DE 38 30 992 A1. Depending on the frequency position used, that is to say if the evaluation and control unit 2 can directly process the frequency generated by the oscillator 1 , a reduction in the oscillator frequency can also be completely omitted. In this case, the oscillator feedback signal 8 would be identical to the output signal of the oscillator 1 that is coupled out via the signal coupler 10 .

The structure described so far is already known per se. However, According to the invention now means 18 before seen, through which the oscillator feedback signal 8 in at least part of is or signal paths in this case, the reception can be coupled. In a preferred exemplary embodiment, this is realized in that signal lines 50 , which carry the oscillator feedback signal 8 , are brought at least at one point so close to signal lines 51 of the reception signal path or paths that an evaluable strong signal coupling of the oscillator feedback signal into the reception signal path takes place . In the exemplary embodiment shown here, the coupling takes place between the receive mixers 13 , 23 , 33 and the amplifiers 15 , 25 , 35. This is appropriate in the exemplary embodiment shown here, since the frequency position of the oscillator feedback signal 8 corresponds to the frequency position of the downmixed received signals. If necessary, the frequency position of the oscillator feedback signal 8 must be set by a suitably selected downmixing in the mixer 4 or a suitable frequency division in the frequency divider 7 . During radar operation, that is to say when transmitting and receiving radar signals, the oscillator feedback signal 8 is advantageously switched off or suppressed via the control line 9 , so that it does not overlap the received signals and disturb them. The oscillator feedback signal 8 is released via the control line 9 when the transmission or reception branch of the radar system is inoperative, for example when received radar signals are evaluated. It can then be evaluated in the evaluation and control unit 2 in a manner known per se in order to regulate the frequency of the oscillator 1 . In parallel, the Oszilla gate feedback signal 8 is coupled into the received signal path of the radar system. As a result, the evaluation and control unit 2 simulates a radar target, the distance of which is determined by the frequency of the oscillator 1 . By changing the output frequency of the oscillator 1 , different simulated distances can be set. Since the Oszilla gate feedback signal 8 can be coupled in parallel into all existing received signal paths, in addition to evaluating and checking the basic functioning of the received path, symmetry between the received signal paths can also be checked. It is particularly important to check the characteristics of the amplifiers 15 , 25 , 35 and the filters 16 , 26 and 36.

Fig. 2 shows an alternative embodiment of the invention. It differs from the previously described embodiment in the way in which the oscillator feedback signal 8 is coupled into the received signal path or paths. The basic structure of the radar system corresponds to that of FIG. 1, so that the same reference numerals also identify the same circuit components. In the difference from FIG. 1, however, there is now a circuit network 40 via which the oscillator feedback signal 8 can be coupled into the received signal path or paths. Furthermore, a switch 41 is provided which is controlled via the control signal 9 and via which the coupling of the oscillator feedback signal 8 into the received signal path (s) can be switched on or suppressed. In this described embodiment, the Oszilla gate feedback signal 8 of the evaluation and control unit 2 is available for regulating the frequency independently of a coupling into the received signal path or paths.

In addition to the exemplary embodiments described here, the invention can also be used with any other radar system which has an oscillator feedback signal 8 . This can also be present, for example, in the case of a pulse radar, in particular if pulse compression is used here. In addition, the invention can in principle also be used in the case of a laser radar or an ultrasonic sensor.

Claims (8)

1. radar system, in particular according to the FMCW principle,

• - With an oscillator ( 1 ) whose frequency can be changed,
• - With an evaluation and control unit ( 2 ) and
• with at least one received signal path ( 11-17 , 21-27 , 31-37 ), via which a received signal can be fed to the evaluation and control unit ( 2 ),
• - The evaluation and control unit ( 2 ) separately from the received signal path an oscillator feedback signal ( 8 ) is fed, which is representative of the instantaneous frequency of the output signal of the oscillator ( 1 ) and
• with means for generating and feeding ( 18 , 40 ) a test signal into at least a part of the received signal path, with the function of this test signal being able to check at least part of the received signal path for its function,

characterized in that the test signal is derived from said oscillator feedback signal. 2. Radar system according to claim 1, characterized in that the test signal and said oscillator feedback signal ( 8 ) are approximately the same shape and frequency. 3. Radar system according to claim 1 or 2, characterized in that signal lines ( 50 ) for signaling the oscillator feedback signal at least at one point so close to signal lines ( 51 ) of the received signal paths that an evaluable strong signal coupling of the oscillator feedback signal ( 8 ) in the received signal path takes place. 4. Radar system according to claim 3, characterized in that means ( 9 ) are provided with which the oscillator feedback signal ( 8 ) can be switched off or suppressed. 5. Radar system according to claim 1, characterized in that a circuit network ( 40 ) is present, by means of which the oscillator feedback signal ( 8 ) can be coupled into the reception signal path. 6. Radar system according to claim 1, characterized in that means for frequency conversion ( 4 , 5 , 7 ) are available with which the oscillator feedback signal ( 8 ) and / or the test signal in a compared to the high-frequency output signal from the oscillator ( 1 ) lower frequency are feasible. 7. Radar system according to claim 1, characterized in that the high-frequency output signal of the oscillator ( 1 ) is used to generate the transmission signal. 8. Radar system according to claim 1, characterized in that the radar system has at least two received signal paths has and that the test signal in all reception signal paths can be coupled in simultaneously.