UA25917U - Digital self-compensator - Google Patents

Abstract

The proposed digital self-compensator contains a unit for processing an in-phase signal component, a unit for processing a quadrature signal component, a timing unit, an adder with three inputs, and additionally, for the purpose to enhance efficiency in suppressing interferences, multipliers and a unit for generating a control signal for an automatic gain control unit. Each signal processing unit contains an automatic gain control unit, a multiplier, and a correlation feedback unit. Each correlation feedback unit contains a digital switching unit, a code analyzer, and a unit for generating a quadrature component of the control signal for the automatic gain control unit.

Description

Description of the invention

The useful model belongs to the field of radio engineering and is intended for automatic compensation of active or 2 passive interference generated by radar stations and other radio engineering devices, for example, radio relay communication lines.

A well-known jamming device | (US patent Mo3786509 according to class (3015 9/42 of 1974). The effectiveness of this device is limited by the small dynamic range of analog delay lines and the instability of their parameters.

Of the known jamming devices, the closest in terms of technical essence and schematic solution is the 70 digital auto jamming compensator | see book Lykharev VA Digital methods and devices in radar. M. Sov. radio., p. 131). This autocompensator contains in-phase and quadrature auxiliary channels, each of which consists of first and second weight multipliers, a three-input adder, and a correlation feedback (CFF) circuit containing two multipliers, an adder, an averaging device, a bit grid overflow analysis circuit, a digital switch and two sources of reference signals. The output of the first weighting amplifier of the first channel, the output of the second weighting amplifier of the second channel and the input of the same name of the main channel are connected to the inputs of the adder in 19 in each orthogonal channel. The output of the adder is connected to the second inputs of the KZZ multipliers. The first inputs of the first KZZ multipliers of both channels are connected to the first inputs of both weight multipliers and to the input of the first auxiliary channel. The first inputs of the second KZZ multipliers of both channels are connected to the first inputs of both weight multipliers and to the input of the second auxiliary channel. The output of the first multiplier of the short circuit of this channel and the output of the second multiplier of the short circuit of the other channel are connected to the inputs of the short circuit adders in both channels, and the output of the short circuit adder in each channel is connected to the first input of the averaging device, the second input of which is connected to the output of the digital switch. The output of the averaging device is connected to the overflow analysis circuit of the discharge network and to the input of the digital switch, to the second and third input of which reference signal sources are connected. Digital switch 29 is controlled by the output signals of the bit grid overflow analysis circuit. The output of the switch of the first channel -o is connected to the second inputs of the first weight multipliers of both channels, and the output of the switch of the second channel is connected to the second inputs of the weight multipliers of both channels.

The disadvantage of the described digital auto-compensator is the low effectiveness of interference suppression.

The basis of a useful model is the task of increasing the efficiency of interference suppression. in

The task is solved by the fact that in a digital autocompensator containing in-phase and quadrature auxiliary channels, each of which consists of a series-connected first weighting multiplier, a three-input adder, the second input of which is connected to the output of the second weighting multiplier, o connected the first input with the input of another auxiliary channel, and the third input is the input of the same name of the main MU channel and the correlation feedback circuit (CFC), which contains two multipliers, an adder, a 3o averaging device, a bit grid overflow analysis circuit, a digital switch and two sources reference signals, and the first inputs of the first multipliers are connected to the first inputs of the weight multipliers and to the input of the first auxiliary channel, the first inputs of the second multipliers are connected to the first inputs of the weight multipliers and to the input of the second auxiliary channel, the second inputs of the multipliers of each of the orthogonal channel are connected to the output of the corresponding three-input adder, to of the inputs of the KZZ adder, the output C 50 of the first KZZ multiplier of this channel and the output of the second KZZ multiplier of another channel are connected, and the output of the KZZ adder s is connected to the first input of the averaging device, the second input of which is connected to the output of the digital switch, the output of the averaging device in each the auxiliary channel is connected to the discharge network overflow analysis circuit and to the input of the digital switch, to the second and third inputs of which separate sources of reference signals are connected, and the output of the discharge network overflow analysis circuit is connected to the control input of the switch, while the outputs of the first and second digital switches auxiliary channels o are connected, respectively, to the second inputs of the first and second weight multipliers of both channels, which differs 4! by the fact that it additionally contains the first and second multipliers connected, respectively, between the inputs of the in-phase and quadrature main channels and the third input of the three-input adders, and a device for forming the control ee, the AGC signal, the output of which is connected to the second inputs of the multipliers of the main channels, and additionally - 20 contains, in each circuit of the circuit breaker, a serially connected numerical analyzer connected to the output of the digital -h switch, and a device for forming the quadrature components of the AGC control signal, to the second and third input of which is connected a synchronization device and the output of the circuit for analyzing the overflow of the bit grid, while the outputs of the devices for forming the quadrature components of the AGC control signal of both channels are connected to the inputs of the devices for forming the AGC control signal. 29 The cause-and-effect relationship between the set of features of the invention and the technical result is as follows. c Due to the fact that the device additionally contains the first and second multipliers connected, respectively, between the inputs of the in-phase and quadrature main channels and the third input of the three-input adders, and the device for generating the AGC control signal, the output of which is connected to the second inputs of the multipliers of the main channels, and additionally contains in each circuit of the circuit breaker a serially connected numerical analyzer connected to output 60 of the digital switch and a device for forming the quadrature components of the AGC control signal, to the second and third input of which is connected a synchronization device and the output of the overflow analysis scheme of the bit grid, while the outputs of the forming devices quadrature components of the AGC control signal of both channels are connected to the inputs of the AGC control signal generation device - the effectiveness of noise suppression is increased. Because the essence of the useful model is explained by the drawings, where Fig. 1 shows the structural diagram of the digital autocompensator; Fig. 2 shows one of the options for building a numerical analyzer and a device for forming the quadrature components of the AGC control signal; Fig. 3 shows the dependence of the interference suppression coefficients Kp of the proposed device on the power ratio in the main and auxiliary Channels 2 at the intensity of the interference arriving at the input of the main channel, normalized by n - god in the level of internal reception noise, which is equal to bpobsm? - ?2odB (curve 1).

The jamming device (see Fig. 1) has in-phase 1 and quadrature 2 inputs of the auxiliary channel, 70 in-phase C and quadrature 4 inputs of the main channel. The device contains in-phase and quadrature auxiliary channels, each of which consists of a series-connected first weighting multiplier 5, a three-input adder 6 and a short-circuit circuit 7. The second input of the adder 6 of the in-phase 1 (quadrature 2) channel is connected to the quadrature 2 via the second weighting multiplier 8 (in-phase 1) input of the auxiliary channel. The third inputs of the three-input adders of the in-phase and quadrature auxiliary channel, respectively, through multipliers 9 and 10 72 are connected to the inputs of the same name of the main channel C and 4. The second inputs of the multipliers 9 and 10 of the main channel are connected to the output of the device for generating the control signal of the AGC 11. The KZZ circuit 7 contains the first and the second multipliers 12 and 13, adder 14, averaging device 15, discharge network overflow analysis circuit 16, digital switch 17, reference voltage sources 18 and 19; numerical analyzer 20 and a device for forming the quadrature components of the AGC control signal 21. The first inputs of the first multipliers 12 KZZ of both channels are connected to the inputs of the first and second weight multipliers 5 and 8 and to the input of the first auxiliary channel. The first inputs of the second multipliers 13 KZZ of both channels are connected to the first inputs of the first and second weight multipliers 5 and 8 and to the inputs of the second auxiliary channel. The second inputs of the multipliers 12 and 13 of each orthogonal channel are connected to the output of the adder 6 of this channel. The output of the first multiplier KZZ 12 of this channel and the output of the second multiplier 13 of the KZZ of another channel are connected to the inputs of the adder KZZ 14, and the output of the adder 14 KZZ is connected to the first input of the averaging device 15, to the second input of which the output of the digital switch 17 and the input of the numerical of the analyzer 20. The outputs of the averaging devices 15 in each orthogonal channel are connected to the overflow analysis circuit of the bit grid 16 and to the input of the digital switch 17, separate sources of reference signals 18 and 19 are connected to the second and third inputs of the digital switch, and the control input of the switch 17 connected to the output of the overflow analysis circuit of the bit grid 16. The outputs of the digital switches 17 of the first and second auxiliary channels are connected, respectively, to the second inputs of the first and second weight multipliers 5 and 8 of both channels. The output of the numerical analyzer 20 is connected to the first input of the device for forming the quadrature components of the AGC control signal 21, to the second and third inputs of which the synchronization device 22 and the output of the circuit for analyzing the overflow of the discharge grid 16 are connected. The output of the device for forming the quadrature components of the AGC control signal 21 of each orthogonal channel are connected to the device for generating the AGC control signal 11. p

In order to simplify the practical implementation of the proposed device, multipliers to the whole power of 2 can be used as weight multipliers of the main channel, which implement the operation of shifting the codes of the input signals. "

One of the possible options for building a numerical analyzer and a device for forming the quadrature components of the AGC control signal, intended for controlling multipliers that implement the operation of shifting codes from input signals, is presented in Fig.2. "» The device for generating the AGC control signal 11 can be implemented by using the schemes of "squaring the quadrature components of the AGC control signal with subsequent addition and extraction of the square root of the obtained sum. It is also possible to use simpler known schemes of transition from quadrature components to the control signal module. o A digital jamming device works as follows. Inputs 1, 2 of the auxiliary channel (see Fig. 1) and c inputs C and 4 of the main channel receive signals after analog-to-digital conversion of signal interference received by different antennas (with compensation of active interference) or by one antenna, but in this case signals, and arriving at the input of the main channel, are initially delayed for the period of passage of sounding pulses - 20 radar systems (with compensation for passive interference). If the intensity of interfering signals arriving at the input of the main channel is less than or equal to the intensity of the signals of the auxiliary channel, then after a time that "M is equal to the self-tuning time, some optimal control signal codes appear in digital form at the output of averaging devices 15 KZZ. Control signals through digital switches 17 are sent to the second inputs of weight multipliers 5 and 8 and change the complex transmission coefficient of the auxiliary channel. At the same time, 22 ensures the minimum value of the output signals of adders 6, i.e. interference compensation occurs. If the intensity of interference signals in the main channel is greater than in auxiliary, then in the process of self-tuning there is an overflow of the bit grid of the averaging devices 15. In this case, the moment of overflow of the bit grid is fixed by the circuit of the analysis of the overflow of the bit grid 16. This is carried out by analyzing the lower and higher sign digits of the averaging results, 60 represented by a modified code, for example, using the "extractive OR" scheme. In case of overflow, depending on the logical state of the most significant bit (1 or 0), the overflow analysis circuit of the bit grid 16 forms a signal, according to which the digital switch 17 connects to the second inputs of the weighting multipliers one or another source of reference voltages (18 or 19). The output signal of the discharge network overflow analysis circuit 16 is also supplied to one of the inputs of the device for forming the quadrature components of the AGC control signal 21. When the clock pulses TI AGC are received from the synchronization device 22 to the second input of the device for forming the quadrature components of the control signal AGC 21 at the direct counting input of the reversible of the counter (see Fig. 2 - microcircuit 133 MIE7) there is a pulse that is recorded in the counter.

The output signal of the counter is fed to the input of the AGC control signal generation circuit 11 and further to the multiplier of the main channel 9 and 10. The AGC TI clock pulses are received from the synchronization device 22 with an interval approximately equal to the time of self-adjustment of the jamming device. Thus, if after multiplying the signals of the main channel by the control signal of the AGC (shift to the right) and after the self-tuning time has expired, the intensity of the interference signal in the main channel still exceeds the signal of the auxiliary channel (there is an overflow of the bit grid of averaging devices 15), then to the direct counter input of the counter /o the next pulse arrives, and the AGC control signal increases. This leads to a further reduction in the gain of the interfering signal in the main channel. The reduction of the interference signal in the main channel occurs until the overflow of the discharge grid disappears in the averaging devices 15 (that is, until the jamming device switches to linear mode of operation).

In the event that the interference situation has changed significantly, that is, the intensity of the interference signal in the main channel has significantly decreased, then the control signals arriving at the weight multipliers of the auxiliary channel 8 from the outputs of the averaging devices 15 become much less than one (the analysis is carried out using a numerical analyzer (microcircuit 133 LR З3(1). If at the same time the output signals of the device for forming the quadrature components of the AGC control signal 21 are different from zero, that is, the gain in the main channel has previously been reduced (the analysis is carried out using the microcircuit 133 LR 3(2), then at the moment of the appearance of clock pulses Pulses are sent to the reverse counting input of the reversing counter, that is, they increase the gain in the main channel. The use of two or three higher digits in the codes of the control signals of the weight multipliers of the main channel and in numerical analyzers makes it possible to exclude the possibility of relaxation oscillations, due to by multiplying the signals of the main channel by a whole power of 2.

Thus, in the proposed digital autocompensator, jamming of interference due to the use of additional devices: numerical analyzers, devices for forming the quadrature components of the control signal o,

The AGC, the AGC control signal generation device and two multipliers provide a linear mode of compensation of interfering signals even in the case of exceeding the intensity of the interfering signals of the main channel over the signals of the auxiliary channel. At the same time, effective compensation of interfering signals is ensured.

Fig. 3 shows the calculated dependence of the interference suppression coefficient of the proposed device on the ratio of power in the main and auxiliary channels p- in 5 2 at the intensity of interference of two types entering the input of the main channel, normalized by the level of internal reception noise, which is equal to a - Curve 1 characterizes the effectiveness of the proposed digital noise suppression device. For comparison, Fig. 3 presents curves 2 and 3, characterizing, respectively, the efficiency of the device with the limitation of the control signals of the weight multipliers of the auxiliary channels and the device without the use of special measures for the effectiveness of interference.

The use of a useful model in radar and other radio technical devices will improve their tactical and technical characteristics from the point of view of immunity from active and passive interference. At the same time, the technical requirements imposed on other systems and devices of radio-electronic means are increased. p

Claims (1)

The formula of the invention is) sl Digital autocompensator containing in-phase and quadrature auxiliary channels, each of which consists of a series-connected first weighting multiplier, a three-input adder, the second input of which is connected to the output of the second weighting multiplier, connected by the first input to the input of another auxiliary noise 20 channel, and the third input is the input of the same name of the main channel and the correlation feedback circuit (K33), which contains two multipliers, an adder, an averaging device, a bit grid overflow analysis circuit, "And a digital switch and two sources of reference signals, and the first inputs of the first multipliers KZZ are connected to the first inputs of the weight multipliers and to the input of the first auxiliary channel, the first inputs of the second multipliers KZZ are connected to the first inputs of the weight multipliers and to the input of the second auxiliary channel , the second inputs of the KZZ multipliers of each orthogonal channel are connected to the output of the corresponding three-input adder, the output of the first KZZ multiplier of this channel and the output of the second KZZ multiplier of another channel are connected to the inputs of the KZZ adder, and the output of the KZZ adder is connected to the first input of the averaging device, the second the input of which is connected to the output of the digital switch, the output of the averaging device in each auxiliary channel is connected to the overflow analysis circuit of the bit grid and to the input of the digital switch, because separate sources of reference signals are connected to the second and third inputs of which, and the output of the bit grid overflow analysis circuit is connected to the control input of the switch, while the outputs of the digital switches of the first and second auxiliary channels are connected, respectively, to the second inputs of the first and second weight multipliers of both channels , which differs in that it additionally contains the first and second multipliers connected, respectively, between the inputs of the in-phase and quadrature main channels and the third input of the three-input 65 adders, and a device for generating a control signal for automatic gain control, the output of which is connected to the second inputs of the multipliers of the main channels, and also additionally contains in each chain of KZZ a serially connected numerical analyzer connected to the output of a digital switch, and a device for generating quadrature components of the control signal of automatic gain control, to the second and third input of which is connected the synchronization device and the output of the discharge network overflow analysis circuit, while the outputs of the devices for forming the quadrature components of the control signal of automatic gain control of both channels are connected to the inputs of the control signal formation devices of automatic gain control. that 2 cha «- (o) iv) s - with . and? ime) 1 se) - 70 that s 60 b5