KR100936939B1 - Self-inspection apparatus of a transmitter-receiver for a radar with multi-receiving channels - Google Patents

Abstract

The present invention relates to a self-diagnostic apparatus for a multi-receive channel radar transceiver using a dual conversion method, and by branching an intermediate frequency signal whose frequency of a transmission signal is first up-converted by a primary up-converter. A feedback signal generator for generating a feedback signal, a reverse injection unit for inputting the generated feedback signal in a reverse direction of a reception path of a multiple reception channel, and a feedback signal upward for converting the feedback signal injected in the reverse direction into a final output frequency signal A conversion unit, a feedback signal input unit for applying a feedback signal upconverted to a final output frequency signal to an input terminal of a reception path of a multiple reception channel to be checked, and an applied feedback signal through a reception channel, thereby causing an error in the transceiver. Includes a self-inspection unit to check for presence.

According to the present invention, by using the feedback signal generated from the signal source of the existing transceiver and the existing receiving channel, it is possible to perform the self-test of the high power radar transceiver through a minimum additional circuit configuration.

Radar Transceiver

Description

Self-inspection apparatus of a transmitter-receiver for a radar with multi-receiving channels}

The present invention relates to a self-diagnostic apparatus for a transceiver for multiple reception channel radar requiring high power.

1 is a conceptual diagram of a self-diagnosis system of a conventional time division duplex transceiver, and self-diagnosis is performed using a transmission signal extracted from an intermediate frequency or a radio frequency band.

According to such a system, the transmission signal of the time division duplex transceiver can be extracted to the reception path to diagnose the characteristics of the transmission signal and the reception path during the transmission mode operation of the time division duplex transceiver. However, when the final output signal of the transmitter is used as a check signal, it is difficult to implement an available switch in a radar system requiring a transmission power of several kW. A check on the components located could not be performed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems in the prior art, and injects a feedback signal generated by a signal source mounted on a transceiver in a reverse direction of an existing reception channel reception path to provide a receiver for a multiple reception channel radar. The purpose is to carry out self-test.

In order to achieve the above object, a self-diagnostic apparatus for a transceiver for a multiple reception channel radar according to the present invention,

In the self-diagnostic apparatus of a transceiver for a multiple reception channel radar using a double conversion method having a primary and secondary up-converter and a primary and secondary down-converter, respectively, transmission by the primary up-converter. A feedback signal generator for generating a feedback signal by branching an intermediate frequency signal of which the frequency of the signal is first upconverted; A reverse injection unit configured to input a feedback signal generated by the feedback signal generator in a reverse direction of a reception path of a multiple reception channel; A feedback signal up-conversion unit configured to up-convert the feedback signal injected in the reverse direction by the reverse injection unit to a final output frequency signal; A feedback signal input unit for applying a feedback signal upconverted to a final output frequency signal by the feedback signal upconversion unit to an input terminal of a reception path of a multiple reception channel to be checked; It includes a self-check unit for receiving the feedback signal applied by the feedback signal input unit through a receiving channel, and checks the abnormality of the transceiver.

The self-checking unit determines whether there is an abnormality by comparing the signal characteristics of the input feedback signal with the transmission / reception signal characteristics of a normal state stored in advance.

The feedback signal generator includes a first combiner connected between the primary up-converter and the secondary up-converter, and a first divider connected to the first combiner to distribute the feedback signal to each channel of the multi-receive channel. And a first switch connected to each signal line distributed from the first distribution unit.

The reverse injector may include a second combiner connected between the secondary downconverter and the primary downconverter of each of the multiple reception channels to receive a branched feedback signal in a reverse direction, and input from the second combiner. The received feedback signal includes a second switch formed in each of the multiple reception channels to be applied to the feedback signal up-conversion unit from the reception path of each of the multiple reception channels. Here, the second switch is preferably a single pole double throw (SPDT) switch.

The feedback signal input unit may include a second distribution unit capable of distributing the feedback signal up-converted into the final output frequency signal to each channel of the multiple reception channel, and a third signal line connected to each signal line distributed from the second distribution unit. And a third combiner connected to each input terminal of the reception path of the multiple reception channel such that the uplinked feedback signal connected from each of the third switches can be input to the primary downconversion unit.

According to the present invention, by using the feedback signal generated from the signal source of the existing transceiver and the existing receiving channel, it is possible to perform the self-test of the high power radar transceiver through a minimum additional circuit configuration.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that the detailed description of related known functions or known configurations or obvious matters to those skilled in the art may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

2 is a block diagram of a self-diagnostic apparatus of a transceiver for multiple reception channel radar according to an embodiment of the present invention.

Referring to FIG. 2, a transceiver for a multiple reception channel radar generally includes a waveform generator 120 for generating a transmission waveform, a frequency synthesizer 110 for generating various frequencies using its own signal source, and a double conversion. A first up-converter 130 for firstly converting a frequency of a transmission signal into an intermediate frequency, and a second upconverter 140 for upconverting a transmission signal primarily converted to an intermediate frequency to a final output frequency; A high power transmitter 150 for generating a high power transmission signal output, an antenna unit 160 for transmitting a high power signal or receiving a target reception signal, and a primary for firstly converting the received target reception signal to an intermediate frequency Down-conversion unit 170, and the target down-conversion unit 180 and the target receiving signal converted to the secondary intermediate frequency signal to convert the target receiving signal first-converted to the intermediate frequency into a secondary intermediate frequency signal required for the signal processing unit Signal processing It is composed of a signal processing unit 190.

In the transceiver for a multiple reception channel radar using a double conversion method including the primary and secondary up-converters and the primary and secondary down-converters, respectively, the self-diagnosis apparatus for self-diagnosis includes: 1 A feedback signal generator 210 for generating a feedback signal by branching an intermediate frequency signal of which the frequency of the transmission signal is first up-converted by the difference up-converter, and a feedback signal generated by the feedback signal generator A reverse injection unit 220 for inputting the signal in the reverse direction of the reception path of the multiple reception channels, a feedback signal up conversion unit 230 for upconverting the feedback signal injected in the reverse direction by the reverse injection unit to the final output frequency signal, A feedback signal input unit 240 for applying the feedback signal up-converted to the final output frequency signal by the feedback signal up-conversion unit to an input terminal of the reception path of the multiple reception channel, and It includes a self-check unit 250 for receiving a feedback signal applied by the ring signal input unit through the receiving channel, and checks for abnormality of the transceiver.

At this time, the self-check unit 250 compares the signal characteristics of the input feedback signal with the transmission / reception signal characteristics in the normal state stored in advance to determine whether there is an abnormality.

The feedback signal generator 210 is connected to the first combiner 212 between the primary up-converter and the secondary up-converter, and the first combiner to connect the feedback signal to each channel of the multiple reception channel. And a first switch 216 which is connected to each signal line distributed from the first distribution part.

In addition, the reverse injection unit 220 may be connected between the secondary down-conversion unit 180 and the primary down-conversion unit 170 of each of the multiple reception channels to receive a branched feedback signal in a reverse direction. The second combiner 222 and the second switch 224 formed in each of the multiple reception channels so that the feedback signal input from the second combiner can be applied to the feedback signal up-conversion unit from the reception path of each of the multiple reception channels. Include.

In addition, the feedback signal input unit 240 may include a second distribution unit 242 capable of distributing the feedback signal up-converted into the final output frequency signal to each channel of the multiple reception channel, and the distribution signal from the second distribution unit. A third switch 244 connected to a signal line, and a third switch 244 connected to each of the third switches and connected to respective inputs of the reception paths of the multiple reception channels such that the up-converted feedback signal from the third switch can be input to the primary downconversion unit. Three coupler 246.

Looking at the self-diagnostic method through the self-diagnostic device configured as described above,

First, a transmission signal for use in actual radar transmission is branched by using the first combiner 212 and the first distribution unit 214 to generate a feedback signal for inspection. At this time, the first switch 216 is connected to only the switch corresponding to the receiving channel to which the generated feedback signal is to be injected. The branched feedback signal is injected in the opposite direction of the reception path of the multi-channel through the second combiner 222. At this time, the second switch 224 opens the path of the reception channel into which the feedback signal is injected, and connects the signal line connected to the feedback signal up-conversion unit 230, and short-circuits the path of the reception channel to be checked. At the same time, the signal line connected to the feedback signal up-conversion unit 230 is opened. For this purpose, the second switch 224 is preferably a single pole double throw (SPDT) switch. When the feedback signal is injected into the feedback signal up-conversion unit 230 through the second switch 224, the feedback signal passes through the feedback signal up-conversion unit 230, and the feedback signal of the final output frequency band corresponding to the input terminal of the receiving channel. Up-converted to a signal. The feedback signal up-converted to the final output frequency signal is distributed to each channel of the multiple reception channel through the second distribution unit 242 and the third switch 244, and each of the multiple reception channels through the third combiner 246. The first down converter 170 of the transceiver, which is an input terminal of the reception path, is input. At this time, the third switch 244 allows only the path of the receiving channel to be checked to be connected. The feedback signal applied to the receiving channel enters the self-checking unit 250 through the receiving channel, and compares the characteristics of the transmission / reception signal of the normal state stored in the self-checking unit 250 to determine It is possible to determine whether there is an abnormality. Here, it is preferable that the first and third switches are single pole single throw (SPST).

As described above, the present invention utilizes a feedback signal and a reception channel generated from a signal source installed in the transceiver, thereby performing a self-test (self-diagnosis) of the high output radar transceiver through a minimum of additional circuits without using a separate channel. Can be done.

Here, FIG. 3 is composed of only three reception channels for convenience, but is not limited thereto.

In the foregoing description, it should be understood that those skilled in the art can only make modifications and changes to the present invention without changing the gist of the present invention as it merely illustrates preferred embodiments of the present invention.

1 is a conceptual diagram of a self-diagnosis system of a conventional time division duplex transceiver.

2 is a block diagram of a self-diagnostic apparatus of a transceiver for multiple reception channel radar according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

110: frequency synthesizer 120: waveform generator

130: first up-converter 140: second up-converter

150: high power transmitter 160: antenna unit

170: first downconversion unit 180: second downconversion unit

190: signal processor 210: feedback signal generator

220: reverse injection unit 230: feedback signal up-conversion unit

240: feedback signal input unit 250: self-check unit

212: first coupler 214: first distribution part

216: first switch 222: second coupler

224: second switch 242: second distribution unit

244: third switch 246: third coupler

Claims (6)

In the self-diagnostic apparatus of a transceiver for a multiple reception channel radar using a double conversion method having a primary and secondary up-conversion unit and a primary and secondary down-conversion unit, respectively, A feedback signal generator for generating a feedback signal by branching an intermediate frequency signal whose frequency of a transmission signal is first up-converted by a primary up-converter; A reverse injection unit configured to input the generated feedback signal in a reverse direction of a reception path of multiple reception channels; A feedback signal up converter for upconverting the feedback signal injected in the reverse direction to a final output frequency signal; A feedback signal input unit for applying a feedback signal upconverted to the final output frequency signal to an input terminal of a reception path of a multiple reception channel to be checked; Self-checking unit for receiving an applied feedback signal through the receiving channel and checking whether the transceiver is abnormal Self-diagnostic apparatus of the transceiver for multiple reception channel radar comprising a. The method of claim 1, The self-checking unit is a self-diagnosis apparatus for a multiple reception channel radar transceiver, characterized in that for determining whether there is an abnormality by comparing the signal characteristics of the input feedback signal with the transmission and reception signal characteristics of the normal state stored in advance. The method of claim 1, The feedback signal generator, A first combiner connected between the primary up-converter and the secondary up-converter; A first distribution unit connected to the first combiner and capable of distributing a feedback signal to each channel of a multiple reception channel; And a first switch connected to each signal line distributed from the first distribution unit. The method of claim 1, The reverse injection unit, A second combiner connected between each of the secondary down-converters and the primary down-converter of the multiple reception channels to receive a branched feedback signal in a reverse direction; And a second switch formed on each of the multiple reception channels so that the feedback signal received from the second combiner can be applied to the feedback signal up-conversion unit from the reception path of each of the multiple reception channels. Self-diagnosis device for transceiver. The method of claim 4, wherein And the second switch is a single pole double throw (SPDT) switch. The method of claim 1, The feedback signal input unit, A second distribution unit capable of distributing the feedback signal up-converted into the final output frequency signal to each channel of a multiple reception channel; A third switch connected to each signal line distributed from the second distribution unit; And a third combiner connected to each input terminal of the reception path of the multiple reception channel such that the uplinked feedback signal connected from each of the third switches can be input to the primary downconversion unit. Self-diagnosis device for radar transceiver.

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