JPH041584A - Method and device for suppressing disturbance wave on radar equipment - Google Patents

Abstract

PURPOSE:To reduce the time for selecting a disturbance wave suppressing device by discriminating with an auxiliary antenna whether the distrubance wave is one coming from a main lobe or from a side lobe. CONSTITUTION:A signal received by the antenna 11 is mixed with the output of local oscillator 15 by a mixer 13. The auxiliary antenna 12 covers the side lobe level of main antenna. The output of a logarithmic amplifier 20 and output of a logarithmic amplifier 21 are compared by a comparator 22. The disturbance wave, in the case it is a barrage disturbance, is passed through a bandpass filter 26 passing the signal and amplified by a logarithmic amplifier 27 and outputted to a comparator 28. Since the disturbance wave is thus automatically suppressed, the time to attain the selection of disturbance wave suppressing device is saved, and also the most suitable disturbance wave suppressing device can be selected.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field j] The present invention relates to a suppression method and apparatus for automatically suppressing interference waves in a radar device according to the type of interference waves.

[Prior Art] Figure 8 shows a functional block diagram of a radar device equipped with a typical conventional interference wave suppression device.
1) is an antenna, (13) is a mixer, (15) is a local oscillator, (16) is a receiver, (17) is an interference wave tracking receiver, (23) is a switching device 1. (24) is a transmission/reception switching device, (25) is a transmitter, (32) is a sidelobe blanking device, (33) is a sidelobe canceller device, (40) is a console, (
41) is the switching device 2.

The conventional interference wave suppression device is configured as described above, and when the antenna (11) receives interference waves, the operator transmits P P I (Pian P I) on the console (40).
.

5ition Indicator) to judge the effectiveness of the interference wave suppression device,
ic 5upport Measure) device by knowing the type of interference wave.

Manually switching device 1 (23) to receiver (16)
and the interference wave tracking receiver (17) are switched, and the sidelobe blanking device (32) and sidelobe canceller device (33) are switched by the switching device 2 (41).
can be switched.

[Problems to be Solved by the Invention] Conventional interference wave suppression devices are configured as described above, and with the increase in types of interference waves in recent years, operators can identify the types of interference waves and eliminate interference waves. It takes a very long time to select a suppression device, and it has become difficult to select an optimal interference wave suppression device.

In particular, it has become extremely difficult for operators to manually select interference wave suppression devices for radar systems that require short reaction times due to faster targets, and for radar systems that are required to deal with multiple targets. .

(Means for Solving the Problems) The interference wave suppression device according to the present invention uses an auxiliary antenna that covers the side lobe level of the antenna to determine whether the interference waves are from the main lobe of the antenna or from the side lobes. If the interference is from a sidelobe, it will automatically track the interference by identifying whether it is spot interference, sweep interference, barrage interference (noise interference), or repeater interference. This selects canceller and sidelobe blanking.

1 Effect 1 The interference wave suppression device according to the present invention automatically suppresses interference waves, so it does not take time to select a interference wave suppression device, and it is possible to select an optimal interference wave suppression device. Become.

[Embodiment 1] FIG. 1 shows a processing procedure of an embodiment of a method for suppressing interference waves in a radar apparatus according to the present invention. In Figure 1, (
1) to (10) are processing procedures of an embodiment of the interference wave suppression method. This will be explained below with reference to FIG. Compare whether the interference waves are from the main lobe or the side lobes of the antenna (step 1). If the interference waves are from the main lobe, track the interference waves (step 2), and check whether the interference waves are from the side lobes. In the case of i-wave, it is necessary to detect whether it is spot interference or not (step 3), and in the case of spot interference, it is necessary to detect the frequency ho
．． Select the ping (Step 4), and if it is not a spot disturbance, detect whether it is a sweep disturbance (Step 5).
In the case of sweep interference, further detect the duty of the interference wave, and if the duty is high, select a sidelobe canceller (Step 9), if the duty is low, select sidelobe blanking (Step 10), Sweep interference If not, large disturbance (noise disturbance)
Step 7) If it is barrage interference, select a sidelobe canceller Step 9) If it is not barrage interference, check whether it is repeater interference Step 8). If it is repeater interference, select sidelobe blanking. Optionally, in step 10), if there is no repeater interference, repeat this series of steps.

FIG. 2 shows an embodiment of the interference wave suppression device in a radar device according to the present invention, and in FIG. 1, (11)
is the antenna, (12) is the sub-antenna, (+3) and (14) are the mixers, (15) is the local oscillator, (16)
) is the receiver, (17) is the interference wave tracking receiver, (1
g) is bandpass filter 1, (19) is bandpass filter 2, (20) is logarithmic amplifier 1, (2
1) is the logarithmic amplifier 2, (22) is the comparator, (2
3) is a switching device. Further, FIG. 5 is a diagram showing the antenna pattern of the auxiliary antenna, and FIG. 6 is a diagram showing the frequency characteristics of the bandpass filter.

The operating principle of the interference wave suppression device configured as described above will be explained with reference to FIG. In Figure 2, the antenna (11
The signal received at the local oscillator (
+5) and input to the receiver.

If there is an interference wave at the receiver input, it passes through bandpass filter 2 (19) that passes the interference wave band.

It is amplified by logarithmic amplifier 2 (21). FIG. 6 shows the frequency characteristics of bandpass filter 2 (19). In the figure, f (39) indicates the difference from the center frequency of the receiver.

f is determined by the frequency hopping width.

Generally, a frequency of about several tens of MHz is selected. Auxiliary antenna (I
The signal received at 2) is passed through a mixer (14) to a local oscillator (
15). If there is a disturbance wave in the output of the auxiliary antenna, it passes through a bandpass filter 1 (1g) that passes the band of the disturbance wave, and is amplified by a logarithmic amplifier 1 (20). Figure 5 shows the antenna pattern of the auxiliary antenna (3
6) is shown. In the figure, the auxiliary antenna covers the sidelobe level of the main antenna. The output of the logarithmic amplifier and the output of the logarithmic amplifier 2 are compared by a comparator. From the above, if the interference wave input to the receiver is main lobe interference, the output of the above logarithmic amplifier 2 is the logarithmic amplifier 1.
The switching device switches between the receiver and the interference wave tracking receiver.

FIG. 3 shows an embodiment of the interference wave suppressing device in a radar device according to the present invention, and in FIG. 1, (II)
is an antenna, (12) is an auxiliary antenna, (13) and (14) are mixers, (15) is a local oscillator, (16) is a receiving fi, (18) is a bandpass filter 1. (19
) LL band pass filter 2. (20) is the logarithmic amplifier 1. (21) is the logarithmic amplifier 2. (22) is comparator 1.
(23) is a switching device (24) is a transmission/reception switching device, (25) is a transmitter, (26) is a bandpass filter 3, (27) is a logarithmic amplifier 3, (28) is a comparator 2. (29) is an AND circuit.

The operating principle of the interference wave suppression device configured as described above will be explained using FIG. 3. In Figure 3, the antenna (11
) The signal received at the transmitter/receiver switcher (24) is mixed with the local oscillator (15) at the microphone (13) and input to the receiver. If there is spot interference, which is an interference wave whose frequency is the same as the signal frequency, at the receiver input, the signal passes through bandpass filter 2 (19), which passes the signal band, and is amplified by logarithmic amplifier 2 (21). The signal received by the auxiliary antenna (12) is mixed with a local oscillator (15) in a mixer (14). If there is spot interference in the output of the auxiliary antenna, the signal is passed through the bandpass filter I (18) that passes the signal band, and the signal is passed through the logarithmic amplifier 1 (20
) is amplified. FIG. 5 shows the antenna pattern (36) of the auxiliary antenna.

In the figure, the auxiliary antenna covers the sidelobe level of the main antenna. The output of the logarithmic amplifier 1 and the output of the logarithmic amplifier 2 are determined by a comparator.

be compared. If the interference wave input to the receiver is sidelobe interference, the output of the logarithmic amplifier 1 will be larger than the output of the logarithmic amplifier 2. In addition, in the case of spot interference, which is an interference wave with the same frequency as the signal frequency, the bandpass filter 3 (26) and logarithmic amplifier 3 (26) that pass the signal
Since there is no interference wave in the output of comparator 2 (
2g) is not output.

FIG. 6 shows the frequency characteristics of bandpass filter 3 (26). In the figure, f (39) indicates the difference from the center frequency of the receiver. f is determined by the width of frequency hopping, and is generally selected to be about several tens of MHz. As described above, when the interference wave input to the receiver is spot interference from side lobes, the frequency of the transmitter is switched by the switching device (23) based on the outputs of the comparators 1 and 2.

FIG. 4 shows an embodiment of the interference wave suppression device in a radar device according to the present invention, and in FIG. 1, (II)
is the antenna, (12) is the auxiliary antenna, (13) and (14) are the mixers, (+5) is the local oscillator, (16)
is the reception L(1,8) is the bandpass filter 91, (1
9) ft bandpass filter 2. (20) is a logarithmic amplifier L. (21) is a logarithmic amplifier 2. (22) is comparator 1
．． (23) is a switching device (26) that is a bandpass filter 3. (27) is the logarithmic amplifier 3, (2g) is the comparator 2. (30) is comparator 3. (31) is a pulse width detection circuit, (32) is sidelobe blanking,
(33) is a sidelobe canceller, and (34) is a logic circuit. Moreover, FIG. 7 is a diagram for explaining the logic circuit (34).

The operating principle of the interference wave suppression device configured as described above will be explained using FIG. 4. In Figure 4, the antenna (11
The signal received at the local oscillator (
15) and input to the receiver.

If there is sidelobe interference at the receiver input, it passes through a bandpass filter 92 (19) that passes the band of the interference wave, is amplified by logarithmic amplifier 2 (21), and is amplified by comparator 2 (
2g). The signal received by the auxiliary antenna (12) is mixed with a local oscillator (I5) in a mixer (I4). If there is sidelobe interference in the output of the auxiliary antenna, bandpass filter 1 passes the band of interference waves.
(1g) and is amplified by logarithmic amplifier 1 (20). Figure 5 shows the antenna pattern of the auxiliary antenna (36
) is shown. In the figure, the auxiliary antenna covers the sidelobe level of the main antenna, and the output of the logarithmic amplifier 1 and the output of the logarithmic amplifier 2 are compared by a comparator 1. If the interference wave input to the receiver is sidelobe interference, the output of the logarithmic amplifier 1 will be larger than the output of the logarithmic amplifier 2. In addition, if the interference wave is barrage interference (noise interference), bandpass filter 3 (
26) and is amplified by logarithmic amplifier 3 (27),
It is output to comparator 3 (30). FIG. 6 shows the frequency characteristics of bandpass filter 3 (26). In the figure, f(39) indicates the difference between the center frequency of the bandpass filter 3 and the center frequency of the receiver. f is determined by the width of frequency hopping, and is generally selected to be about several tens of MHz. From the above, if the interference wave input to the receiver is barrage interference (noise interference) from side lobes, the comparator 2
The outputs of comparators 2 and 3 are output simultaneously, and the sidelobe canceller is selected by the switching device (23). In addition, if the interference wave is a sweep interference, it passes through the bandpass filter 3 (26) that passes the signal,
Amplified by logarithmic amplifier 3 (27) and comparator 3 (30)
is output to. However, unlike in the case of barrage interference (noise interference), the outputs of the comparators 2 and 3 are not output simultaneously, but only one of them is output. From the above, if the receiver manually generated interference wave is identified as sweep interference from side lobes, 7 In addition, the pulse width detection circuit (31
), the duty is detected by high duty (
Generally, when the duty is 30% or more, a sidelobe canceller is selected, and when the duty is low, sidelobe blanking is selected. In addition, if the interference wave input to the receiver is repeater interference from side lobes, the pulse width detection circuit (31)
is detected and sidelobe blanking is selected. The above selection is performed by the logic circuit (34), the logic of which is shown in FIG.

[Effects of the Invention] As described above, according to the present invention, interference wave suppression is performed dynamically every 9 days, so it does not take much time to select an interference wave suppression device, and it is possible to select an optimal interference wave suppression device. This has the effect of

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a processing procedure of an embodiment of a method for suppressing interference waves in a radar apparatus according to the present invention, and FIGS. FIG. 5 is a diagram showing an example of the antenna pattern of the auxiliary antenna, FIG. 6 is a diagram showing the frequency characteristics of the bandpass filter, and FIG. 7 is a diagram explaining the logic circuit.
FIG. 8 shows a functional block diagram of a radar device equipped with a typical conventional interference wave suppression device. In Figure 1, (1) to (10) are the processing steps of an embodiment of the interference wave suppression method, (If) is the antenna, and (12)
is the sub-antenna, (1, 3) and (14) are the mixers,
(15) is the local oscillator, (+6) is the receiver, (17
) is an interference wave tracking receiver, (18) is a bandpass filter], (+9) is a bandpass filter 2. (20) is the logarithmic amplifier 1. (21) Logarithmic amplifier 2 (22) is connected to comparator 1. (23) is a switching device, (24) is a transmission/reception switching device, (25) is a transmitter, (26) is a bandpass filter 3. (27) is the logarithmic amplifier 3. C28
) is comparator 2. (29) is an AND circuit, (30) is a comparator 3. (31) Ha pulse width detection circuit, (32)
is a sidelobe blanking device ft, (33) is a sidelobe canceller device (34) is a logic circuit, (3
5) is the antenna pattern of the main antenna, (36) is the antenna pattern of the auxiliary antenna (37) is the signal frequency L (
38) is the center frequency of the bandpass filter, (39)
is the frequency difference, (40) is the console (4I) is the switching device 2. a-d are inputs of the logic circuit. In addition, in FIG. 2, the same reference numerals indicate the same or equivalent parts. mI diagram national diagram diagram

Claims (4)

[Claims] (1) The radar equipment compares whether the interference waves are from the main lobe or the side lobes of the antenna, and if the interference waves are from the main lobe, the interference waves are tracked, and the interference waves from the side lobes are detected. In the case of , it compares spot interference, sweep interference, barrage interference (noise interference), and repeater interference, selects frequency hopping in the case of spot interference, and further detects the duty of the interference wave in the case of sweep interference. , select sidelobe canceller for high duty, select sidelobe blanking for low duty, select sidelobe canceller for barrage disturbance, select sidelobe blanking for repeater disturbance A method of suppressing interference waves in a radar device characterized by repeating this series of steps. (2) an auxiliary antenna that covers the sidelobe level of the antenna, a bandpass filter 1 that passes the interference wave band among the outputs of the auxiliary antenna, and a logarithmic amplifier 1 that amplifies the output of the bandpass filter 1; A bandpass filter 2 that passes a band of interference waves among the outputs of the antenna, a logarithmic amplifier 2 that amplifies the output of the bandpass filter 2, and a comparator that compares the output of the logarithmic amplifier 1 and the output of the logarithmic amplifier 2. An interference wave suppression device for a radar device, comprising: a switching device for switching between a receiver and an interference wave tracking receiver. (3) an auxiliary antenna that covers the sidelobe level of the antenna; a bandpass filter 1 that passes a signal band among the outputs of the auxiliary antenna; a logarithmic amplifier 1 that amplifies the output of the bandpass filter 1; and an antenna. A bandpass filter 2 that passes a signal band out of the output of the bandpass filter 2, a logarithmic amplifier 2 that amplifies the output of the bandpass filter 2, and an output of the logarithmic amplifier 1 and the logarithmic amplifier 2.
a comparator 1 that compares the output of the antenna, a bandpass filter 3 that passes the interference wave band among the outputs of the antenna, a logarithmic amplifier 3 that amplifies the output of the bandpass filter 3, and an output of the logarithmic amplifier 3. 1. An interference wave suppression device for a radar device, comprising a comparator 2 for comparing thresholds, and a switching device for switching a transmission frequency from the outputs of the comparators 1 and 2. (4) an auxiliary antenna that covers the sidelobe level of the antenna, a bandpass filter 1 that passes the interference wave band among the outputs of the auxiliary antenna, and a logarithmic amplifier 1 that amplifies the output of the bandpass filter 1; A bandpass filter 2 that passes a band of interference waves among the outputs of the antenna, a logarithmic amplifier 2 that amplifies the output of the bandpass filter 2, and a comparator that compares the output of the logarithmic amplifier 1 and the output of the logarithmic amplifier 2. , a bandpass filter 3 that passes a signal band of the output of the antenna, a logarithmic amplifier 3 that amplifies the output of the bandpass filter 3, and a pulse width detection circuit that detects the pulse width of the output of the logarithmic amplifier 3. and a switching device for switching between a sidelobe canceller device and a sidelobe blanking device from the outputs of the comparator, the logarithmic amplifier 2, the logarithmic amplifier 3, and the pulse width detection circuit. Device.