JP2572057B2 - Radar transponder - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radar transponder, and more particularly to a radar transponder having a minimum receiving sensitivity of -50 dBm or less and an effective radiation power of +26 dBm or more.

[Conventional technology]

FIG. 2 is a block diagram showing a conventional radar transponder for search and rescue. In the figure, 1 is a receiving antenna, 2 is a FET amplifier connected to the receiving antenna 1, and 3 is a FET amplifier 2 connected to the receiving antenna. The connected diode direct detector, 4 is a video amplifier connected to the diode direct detector 3, 5 is a video auxiliary amplifier connected to the video amplifier 4, and 6 is a control circuit connected to the video auxiliary amplifier 5. , 7 are a transmission gate circuit connected to the control circuit 6, 8 is a sweep signal generator connected to the transmission gate circuit 7, and 9 is a microcontroller connected to the sweep signal generator 8 and the transmission gate circuit 7. A wave oscillator 10 is a transmitting antenna connected to the microwave oscillator 9, and a receiving open / close switch 11 is connected to the transmission gate circuit 7 and outputs a signal to the FET amplifier 2. You.

Next, the operation will be described. The signal from the search radar received by the receiving antenna 1 is amplified by the FET amplifier 2 and sent to the diode direct detector 3.
The detection output of the diode direct detector 3 is amplified by about 60 dB by the video amplifier 4 and further amplified by the video auxiliary amplifier 5 to a level necessary to trigger the control circuit 6. When triggered by the output of the video auxiliary amplifier 5, the control circuit 6 generates a pulse for generating the transmission time of the radar transponder and outputs it to the transmission gate circuit 7.

The transmission gate circuit 7 generates a transmission gate pulse based on the pulse output from the control circuit 6, and generates the transmission gate pulse by using a sweep signal generator 8, a microwave oscillator 9, and a reception open / close switch.
Send to 11. The sweep signal generator 8 generates a required number of sawtooth signals by the transmission gate pulse from the transmission gate circuit 7 and outputs the signal to the microwave oscillator 9. The microwave oscillator 9 oscillates a microwave for a certain period of time by the transmission gate pulse from the transmission gate circuit 7 and sets the oscillation frequency within a specified frequency range to the voltage of the sawtooth signal from the sweep signal generator 8. Sweeps frequency according to the value. The transmission output whose frequency has been swept from the microwave oscillator 9 is radiated from the transmission antenna 10 to space.

When a transmission gate pulse is given from the transmission gate circuit 7, the reception opening / closing switch 11 turns on the FET amplifier 2.
And the operation of the FET amplifier 2 is stopped by the width of the transmission gate pulse. As a result, the input of the diode direct detector 3 is attenuated, and the inputs of the video amplifier 4 and the video auxiliary amplifier 5 are also attenuated so as not to be affected by the own transmission power.

[Problems to be solved by the invention]

Since the conventional search and rescue radar transponder is configured as described above, the operation of the FET amplifier 2 is stopped only during the transmission period and the input to the video amplifier 4 is attenuated, but the input is completely cut off. Therefore, even if the transmission output circulated to the FET amplifier 2 at the time of transmission is attenuated by the stop of the operation of the FET amplifier 2, it is amplified by about 60 dB in the video amplifier 4, so that the transmission output is substantially considerably high. An input signal is input to the video auxiliary amplifier 5, and the video auxiliary amplifier 5 is over-input, causing excessive saturation. As a result, even after the transmission is stopped, the video auxiliary amplifier 5 cannot operate normally for a long time, and there is a problem that the signal from the search radar cannot be received.

The present invention has been made in order to solve the above-described problems, and reliably prevents an adverse effect caused by its own transmission power, and immediately returns to a normal operation state after the transmission is stopped, so that a search radar can be used. An object of the present invention is to obtain a radar transponder capable of receiving a signal.

[Means for solving the problem]

The radar transponder according to the present invention, when a transmission gate pulse is generated from the transmission gate circuit,
A video switch is provided between the video amplifier and the video auxiliary amplifier. The video switch includes reception switching means for stopping the operation of the T amplifier and is opened and closed by an output signal of the control circuit.

[Action]

The video switch according to the present invention is closed when the output signal of the control circuit is at a high level and shuts off the output signal of the video amplifier, and is opened when the output signal of the control circuit is at a low level to normally output the output signal of the video amplifier. By transmitting to the video auxiliary amplifier, the F
Input signals leaked through the ET amplifier are reliably cut,
After the transmission is stopped, the reception processing is immediately performed by the video amplifier through the FET amplifier, and the reception can be quickly performed without a time delay until the video switch is closed.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings. In FIG. 1, 1 is a receiving antenna, 2 is an FET amplifier, 3
Is a diode direct detector, 4 is a video amplifier, 5 is a video auxiliary amplifier, 6 is a control circuit, 7 is a transmission gate circuit, 8
Is a sweep signal generator, 9 is a microwave oscillator, 10 is a transmitting antenna, and 11 is a reception open / close switch. Is omitted. Reference numeral 12 denotes a video switch which is disposed between the video amplifier 4 and the video auxiliary amplifier 5 and whose opening and closing are controlled by an output signal of the control circuit 6.

Next, the operation will be described. The signal from the search radar received by the receiving antenna 1 is amplified by the FET amplifier 2 and sent to the diode direct detector 3.
The detection output of the diode direct detector 3 is amplified by about 60 dB by the video amplifier 4, and when the video switch 12 is open, is further amplified by the video auxiliary amplifier 5 to a level necessary to trigger the control circuit 6. Is done. When triggered by the output of the video auxiliary amplifier 5, the control circuit 6 generates a pulse for producing the transmission time of the radar transponder and generates a transmission gate circuit 7.
Output to Further, the control circuit 6 inputs a positive voltage pulse signal different from the pulse to the transmission gate circuit 7 to the video switch 12. When the control circuit 6 is triggered, the positive voltage pulse goes high only during the transmission period to close the video switch 12 and to output the signal from the video amplifier 4 to the video auxiliary amplifier 5. Cut off. During a period other than the transmission period, the positive voltage pulse is at a low level, the video switch 12 is opened, and the signal output from the video amplifier 4 is directly input to the video auxiliary amplifier 5 as described above.

Further, the transmission gate circuit 7 generates a transmission gate pulse based on the pulse output from the control circuit 6, and sends it to the sweep signal generator 8, the microwave oscillator 9, and the reception open / close switch 11. When a transmission gate pulse is given from the transmission gate circuit 7, the reception opening / closing switch 11 sets the output level to the FET amplifier 2 to 0 V, stops the operation of the FET amplifier 2 by the width of the transmission gate pulse, and directly switches the diode. The input of the detector 3 and the video amplifier 4
To attenuate the input. Here, the attenuated signal is amplified by about 60 dB in the video amplifier 4 to become a very high level signal. At this time, since the video switch 12 is closed as described above, this signal is There is no input to the video auxiliary amplifier 5.

In addition, the sweep signal generator 8 generates a required number of sawtooth signals based on the transmission gate pulse from the transmission gate circuit 7 and outputs the signal to the microwave oscillator 9. The microwave oscillator 9 oscillates a microwave for a certain period of time by the transmission gate pulse from the transmission gate circuit 7 and sets the oscillation frequency within a specified frequency range to the voltage of the sawtooth signal from the sweep signal generator 8. Sweeps frequency according to the value. The transmission output whose frequency has been swept from the microwave oscillator 9 is radiated from the transmission antenna 10 into space.

As described above, during the transmission period, the FET amplifier 2 stops operating, and further, the video switch 12 is closed, and immediately after the transmission is stopped, the FET amplifier 2 returns to the normal operation state, and the video switch 12 stops operating. Is also opened.

In the above embodiment, the case of a search and rescue radar transponder has been described. However, another radar transponder may be used, and the same effects as those of the above embodiment can be obtained.

〔The invention's effect〕

As described above, according to the present invention, when the transmission gate pulse is generated, the reception opening / closing means for stopping the operation of the FET amplifier is provided, and the output signal of the control circuit is provided between the video amplifier and the video auxiliary amplifier. The video switch which is opened and closed by the switch is arranged so that the video switch is closed during its own transmission period so that a high level input signal is not applied to the video auxiliary amplifier,
When the operation of the T amplifier is stopped, the input signal leaked through the FET amplifier is surely cut, and immediately after the transmission is stopped, the video amplifier returns to a normal operation state in which reception processing is performed through the FET amplifier. There is an effect that a radar transponder which can quickly receive a signal of a search radar without a time delay until closing is obtained.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a search and rescue radar transponder according to an embodiment of the present invention, and FIG. 2 is a block diagram showing a conventional search and rescue radar transponder. 1 is a receiving antenna, 2 is an FET amplifier, 3 is a diode direct detector, 4 is a video amplifier, 5 is a video auxiliary amplifier,
6 is a control circuit, 7 is a transmission gate circuit, 8 is a sweep signal generator, 9 is a microwave oscillator, 10 is a transmitting antenna, 11 is a reception open / close switch, and 12 is a video switch. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (1)

(57) [Claims] An antenna for receiving a microwave signal from a radar, an FET amplifier for amplifying a microwave signal received by the antenna, a detector for detecting an output of the FET amplifier, and an output of the detector Auxiliary amplifier for amplifying a signal, a control circuit for generating a pulse signal as a trigger for determining a transmission time of a microwave signal to which a video amplified signal from the video auxiliary amplifier is input and transmitted, and the control circuit A transmission gate circuit for generating a transmission gate pulse corresponding to the transmission time by the pulse signal, and a sweep signal generation for generating a required number of sawtooth voltage when the transmission gate pulse is input from the transmission gate circuit. And when the transmission gate pulse from the transmission gate circuit is input, based on the sawtooth voltage from the sweep signal generator. A microwave oscillator that sweeps a frequency within a prescribed frequency range, an antenna that emits a frequency signal swept by the microwave oscillator, and a transmission gate pulse generated from the transmission gate circuit. Reception opening / closing means for driving to stop the operation of the FET amplifier, provided between the video amplifier and the video auxiliary amplifier, when the transmission gate pulse is generated from the transmission gate circuit, the video amplifier from the video amplifier Video transponder means for interrupting a signal to the video auxiliary amplifier.