DE2756888C2 - Jamming and eavesdropping device - Google Patents

Description

The invention relates to an interfering and listening device, consisting of an interfering signal via a first antenna emitting transmitter and receiving devices connected to a second antenna.

In such a jamming and eavesdropping device, the direct coupling leads between the first or transmitting antenna and the second or receiving antenna as well as spurious reflections from a short distance this means that the interfering signals get into the receiving devices, that is, into the eavesdropping receiver.

The invention is based on the object, in a device according to the preamble of claim 1, the To improve the decoupling between the sending side and the receiving side, in particular for the purpose of to be able to operate the jamming device and the eavesdropping device at the same time.

The solution to this problem is given in the characterizing part of claim 1.

According to the invention, the interfering signals are before the transmission of a with a certain period Γ subjected to periodically repeating modulation, the period duration Γ being relatively large in proportion is selected for the duration of the signals expected to be recorded by the receiving devices. Delay devices are provided on the receiving side, which the received by the receiving antenna Delay signals by duration Γ; furthermore there are subtraction devices with the input and with connected to the output of the delay devices and in this way make it possible for the output of the To eliminate interfering signals originating from the transmitter.

The delay devices and the subtraction devices make it possible, by subtracting the received signals with a time shift of T, to mask out the interference signals which repeat themselves identically with the period Γ. Any received signals are not changed, however, and are separated and (in terms of time) doubled by the delay devices

By adding further delay devices with the delay duration T and further subtraction devices, it is also possible to eliminate the first-order derivatives or harmonics of the interference signal. The received signals are therefore tripled

The decoupling achieved according to the invention is permitted an improvement in the sensitivity of the eavesdropping device or its receiving devices.

In the drawing, the device according to the invention is shown in a schematically simplified manner on the basis of an embodiment selected as an example
Fig. 1 is a block diagram of a jamming and eavesdropping device,

F i g. 2 shows a modified embodiment of the decoupling devices and

F i g. 3 an advantageous further development of the jamming and listening device.

The jamming and eavesdropping device shown in FIG. 1 is used to transmit broadband interference signals (for example ± 200 MHz at a center frequency Fo), but at the same time it is possible to send any signals from other broadcasting stations (for example communications links or radar devices) in the same frequency band or in a wider frequency band that supports the the disturbed frequency band or part of it contains to intercept transmitted signals.
In detail, the device consists of a transmitter 1, which generates a sine wave with the frequency Fo. This signal is fed to a modulator 2, which converts it according to known methods into interference signals with the center frequency Fo and a bandwidth 2AF. These signals are then amplified in an amplifier 3 and transmitted via a transmitting antenna 4. The listening device assigned to the jamming transmitter comprises a receiving antenna 5 which picks up the signals transmitted by known or unknown transmitting stations and is connected to a receiver 9 via filter circuits 7 and 8.

Since the transmitting antenna 4 and the receiving antenna 5 inevitably only have a small distance from one another and because part of the energy radiated by the transmitting antenna 4 is reflected on nearby obstacles the receiving antenna takes up a very small part of the interfering signal energy. It exists hence a wireless connection between the jammer and the eavesdropping device, resulting in a sizeable one May lead to deterioration in sensitivity of the latter. The interference coupling between the transmitter and the recipient is now remedied according to the present proposal.

The coupling is reduced with the aid of the filter circuits 7 and 8 which are specially adapted to the properties of the modulator 2 generating the interference signals. Each of these filter circuits includes devices which subtract the signal previously received from the signal received at a specific instant, with a specific time shift T.

The first filter circuit 7 comprises a delay line 11 and a subtraction circuit 12, whose Inputs with the input and the output of the

Delay line 11 are connected. The received signals are fed to the input of the delay line At the output of the subtraction circuit , the signals received at a time t are subtracted from the signals received at time / - T , where T is the delay time of the delay line 11. The useful signals have consequently doubled, i.e. they become Delivered twice with a time shift Γ in between. The interference signals, however, are suppressed because they repeat themselves identically with the period T.

A second filter circuit 8, which corresponds to the first filter circuit 7, comprises a delay line 13 and a subtracting circuit 14 connected to each other like the filter 7. As a result this second filtering is the derivative or first harmonic of the modulation of the interfering signals also hidden.

Of course, the filter circuits can also be implemented using analog or digital technology; them coding and decoding circuits can be assigned. At the inputs of the subtraction circuits setting means are provided for the respective gain in order to completely cancel out the interfering signals to achieve. These devices are not shown in the drawing in order not to unnecessary the figures complicated to make.

Various types of interference can be implemented on the transmission side. However, they are all known and are therefore only mentioned briefly below. They always have a repetition duration with the period T. so that they can be suppressed on the interception side.

An interference signal in the form of phase noise is achieved by phase modulation of the signal from transmitter 1 by means of a noise signal of complex amplitude. Filtering in a filter with the bandwidth AF and an equal amplitude distribution over the entire frequency band allow this interference signal to be achieved. The amplitude noise signal repeats itself identically with the period T.

Instead of random values, the phase of the interfering signal can possibly only assume a certain number of fixed values. It is then a phase code modulation. The signal phase can, for example, only assume two states shifted by 180 ° with respect to one another. The code can be pseudo-random and repeats itself with the period T. The spectral width of the phase-coded signal is equal to the reciprocal of the duration of a code element.

Instead of a phase modulation, the interference signal can also be a linear or non-linear, a triangular or sawtooth frequency modulation or by frequency modulation and phase encoding can be obtained. The only condition is that the modulators are as accurate as at least possible with the period Twrepeated

F i g. Fig. 2 shows an embodiment of the filter circuits in connection with a switch.

The purpose of this is to provide a radar device which, when receiving, performs the same signal processing as in Fig. 1, to prevent suppressing the interfering signal.

For this purpose, the transmitted signal is phase-coded with the frequency 1 / Trn with the help of a random code of phases 0 and ^ r or any other code.

Since the radar does not "know" this code, it cannot suppress the interfering signal all the time.

In contrast, the receiving devices that

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50 are assigned to the jammer, suppress the jamming signal because it "knows" the code used. For this purpose, the phase of the signal fed directly to the subtraction circuit is changed or changed accordingly

The in F i g. The filter circuit 10 shown in FIG. 2 consequently comprises a subtraction circuit 19 and a delay line 16, which is connected to an input of the subtraction circuit and in turn at the input receives the signals picked up by the antenna 5 The other input of the subtraction circuit is with connected to the other end of the delay line by circuits that allow the phase of the Either leave signals unchanged or reverse them. These circuits include, for example, a Changeover switch 18, the movable contact of which is connected to the subtraction circuit and whose fixed contact Contacts are connected to the delay line, one directly and the other through one 180 ° phase shifter 17.

The phase change in the filter 10 is synchronous with the phase code that is used in the transmission circuits, of which only the bait 21 is shown, which codes the entire signal transmitted during the period Γ with 0 or with .τ.

A breaker called a receive switch

20 is located between the receiving antenna 5 and the filter circuit 10; it is necessary to suppress the settling signals at the moment of the change of state of the phase code (transition from 0 to π or from π to 0). These settling signals cannot be suppressed by the filter circuit. The reception switch 20 is also controlled by the bait 21. The opening or interruption duration of the interrupter 20 is short in relation to the duration 7 and is, for example, 1 με.

The entire block diagram of a jamming and listening device is shown in FIG. 3 shown. This device includes the Combination of the assemblies described above.

The transmitting part comprises an oscillator 30, followed by a phase encoder 22, from a code generator

21 is controlled.

The previously coded signals are fed to the modulator 2, then to the amplifier 3 and finally the antenna 4.

The modulator 2 takes a phase modulation, a frequency modulation or a phase and frequency modulation as previously described, the period duration being T. The bait 22 takes the phase inversion after a preferably non-repeating random code.

On the receiving side, the signals picked up by the receiving antenna 5 are transmitted via the interrupter 20 on two demodulators 41 and 42. The demodulator 42 also has a sinusoidal shape Signal from an oscillator 40. The same signal is applied to the demodulator after a phase shift of 90 ° 41 at.

The output signals of the demodulator 41 pass through two filters 31 and 33 one after the other, as well as one via a 90 ° phase shifter 44 fed by the same oscillator 40 modulator 45.

The output signals of the demodulator 42 are two successive filters 32 in the same way and 34 and then fed to a modulator 46 which is fed directly by the oscillator 40. The outputs of the modulators 45 and 44 are brought together at the input of the receiver 9.

A connection 50 shown in dashed lines symbolizes a guide of the oscillator 40 from the

j oscillator 30 or vice versa, to ensure the stability of the overall circuit to ensure.

The reception switch 20 is controlled via the code generator 21.

The filters 31 and 32 have the same structure as the filter 10 of FIG. Filters 33 and 34 are correct the structure corresponds to the filter 8 of FIG. 1. “The received signals are thus divided into two over

_t j matching channels in quadrature to each other, ie

with a phase shift of πΙ2, processed.

In each of the channels between the demodulator and the modulator analog / digital converter and Digital / analog converter can be inserted in order to take advantage of the 15 advantages of digital signal processing to be able to.

The circuits described are particularly suitable for radar monitoring stations and for ECM devices. 20th

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Claims (4)

Patent claims: 1. Interfering and listening device, consisting of a transmitter emitting interfering signals via a first antenna and receiving devices connected to a second antenna, characterized in that the interfering signals repeat themselves identically with a period T and that the receiving devices have filter circuits (7, 8, 10 ) which subtract the signals received at time ί from the signals received at time f-Tempf to prevent interference coupling between the first and second antenna. 2. Apparatus according to claim 1, characterized in that the filter circuits (7, 8, 10) at least a delay circuit (11,13,16) and at least a subtraction circuit (12,14,19), whose first input to the output and whose second input is connected to the input of the delay circuit 3. Apparatus according to claim 2, characterized in that the filter circuits are phase reversing circuits (17, 18) for the signal fed to one input of a subtraction circuit and at the same time operating phase reversal circuits (21,22) comprise for the interference signal to be transmitted. 4. Apparatus according to claim 3, characterized in that a switch (20) for brief interruption the received signals is provided synchronously with each phase reversal of the interfering signals.