RU1841099C - Interference compensation device - Google Patents

Abstract

FIELD: physics, radio.

SUBSTANCE: invention relates to radar and can be used in radar receivers for protection from interference. The interference compensation device includes, connected in series, an adder, the first input of which is the main input of the device and the output is the output of the device, a detector, a low-pass filter, a sampling-storage unit, the clock input of which is connected to the clock-pulse input of the device, and a comparator, the second input of which is combined with the input of the sampling-storage unit, a first amplitude controller, the input of which is the compensation input of the device, and the output is connected to the second input of the adder, a phase changer, a second amplitude controller, two integrators and two switches. The device also includes a voltage-to-pulse duration converter, a first coincidence circuit, a pulse polarity inverter and a third switch, a pulse generator, a fourth switch, series-connected second coincidence circuit and T flip-flop, the uncomplemented and complemented inputs of which are connected to the control inputs of the third and fourth switches.

EFFECT: faster operation of the device.

1 dwg

Description

The proposed device relates to the field of radar. It can be used in radar receivers to protect against interference.

Known compensator side lobes containing a main channel, a compensation channel, a correlator, a generator, bandpass filters, a subtractor and multipliers [1].

In the subtractor of the known compensator, the interference of the main and compensation channels is subtracted by controlling the complex frequency characteristics of the compensation channel using modulators and a quadrature phase shifter.

One of the disadvantages of the known compensator is the correlation nature of the feedback circuit. This limits the possibility of using the known microwave compensator and makes it difficult to integrate it into the antenna arrays.

Known auto-compensator containing balanced devices, an amplifier, a subtractor, a phase shifter, a detector, multipliers, integrators, adders and a search oscillation generator [2].

In such an auto-compensator, instead of the coherent reference signal circuits, a search oscillation generator is introduced, which makes it possible to abandon the feedback correlation circuit at the carrier frequency. This simplifies the implementation of the device on the microwave and expands the possibilities of its application.

However, the well-known autocompensator has a drawback - it is necessary to extract and accumulate the spectral components of the search oscillations of a relatively small level from the error signal, which leads to low stability and low speed autocompensator. The low speed makes the auto-compensator ineffective in a complex jamming environment, especially when exposed to switching interference from several spatially separated sources.

Of the known interference compensation devices, the closest to the claimed device is an extreme auto-compensator comprising an adder, a phase shifter, amplitude regulators, integrators, keys, a detector, a delay device and a subtractor [3; (p. 71, fig. 3)].

In such a device, the regulation by the compensation channel, which includes two amplitude controllers and a phase shifter, is carried out by a relay feedback circuit according to an extreme algorithm. This simplifies the device and increases its stability and the degree of suppression of interference.

However, in the known device due to the constancy of the step of controlling the compensation channel inherent in relay circuits, the low noise suppression performance is maintained. This prolongs the duration of the ineffective operation of the auto-compensator in the transition mode and limits the use of the well-known auto-compensator in difficult jamming conditions, especially in the conditions of short-term interference emitted sequentially by several synchronized jammers from different spatial directions, the so-called “switching” or “flickering” interference, the most probable in modern conditions.

Thus, a disadvantage of the known interference suppression devices is the low speed.

The aim of the invention is to increase the speed of the noise suppression device.

This goal is achieved in that in a device containing a series-connected adder, the first input of which is the main input of the device, and the output of which is the output of the device, a detector, a low-pass filter, a sample-storage unit and a comparator, the second input of which is combined with the input of the sample unit -storage, the first amplitude regulator whose input is a compensation input of the device, and the output is connected to the second adder input, a phase shifter, a second amplitude regulator, the output of which is connected to the third input of the adder, and the input through the phase shifter is connected to the compensation input of the device, two integrators and two keys, and the outputs of the first and second keys through integrators are connected to the control inputs of the first and second amplitude controllers, the control inputs of the first and second keys are connected to the control inputs of the device, and the clock input of the sampling-storage unit is connected to the input of the clock sync pulses of the device, the voltage-pulse duration converter is connected in series, the first circuit coincidence, the pulse polarity inverter and the third key, the pulse generator, the output of which is connected to the second input of the first coincidence circuit, the fourth key, the input of which is connected to the output of the first coincidence circuit, the second coincidence circuit and the counting trigger, the direct and inverse outputs of which are connected to control inputs of the third and fourth keys, and the outputs of the third and fourth keys are combined and connected to the combined inputs of the first and second keys, the output of the comparator is connected to the input Torah coincidence circuit and a second input of the second matching circuit and the trigger input of the transmitter voltage-pulse width are connected to the inputs of the serial clock device.

The introduced voltage-to-pulse duration converter is used for proportional conversion of the level of the device error signal detected and smoothed by the low-pass filter to the pulse duration supplied to the first matching circuit.

The generator is used to generate pulses arriving at the first coincidence circuit.

A coincidence circuit forms a burst of pulses, the duration of which is proportional to the signal level of the device error.

The pulse polarity inverter provides the input to the input of the third key of pulses of the same amplitude and duration as the input of the fourth key, but of the opposite polarity.

The second matching circuit ensures that the clock trigger arrives at the input of the counting trigger only when the comparator is triggered, i.e. with an increase in the error signal at the input of the comparator, in comparison with the value of the error signal of the previous measure stored in the sample-storage block.

A counting trigger upon the arrival of a clock clock pulse at its input changes the state of its outputs to the opposite, switching the third and fourth keys.

The third and fourth keys are used to supply pulses to the inputs of the first and second keys that change the control voltages of the amplitude controllers of one or another polarity depending on the state of the counting trigger.

Together, all the nodes of the proposed device provide a change in the duration of the bursts of pulses controlling the amplitude regulators (the magnitude of the steps), in proportion to the level of uncompensated output noise and, thus, increasing the speed of the device.

The set of distinctive features proposed in this invention, the authors are not known.

The drawing shows a functional diagram of the device.

The interference compensation device comprises an adder 1, a detector 2, a low-pass filter 3, a sample-storage unit 4, a comparator 5, a first amplitude regulator 6, a phase shifter 7, a second amplitude regulator 8, the first and second integrators 9, 10, the first and second keys 11 , 12, a voltage-to-pulse converter 13, a first coincidence circuit 14, a pulse polarity inverter 15, third and fourth switches 16, 17, a pulse generator 18, a second coincidence circuit 19, and a counting trigger 20.

The keys 16, 17 are made on multiplexers of type 561 KP1, allowing switching signals of both polarities and combining the output with antiphase control [4; (p. 34, fig. 4)].

The voltage-to-pulse converter 13 is made according to the known scheme [5; (p. 105, fig. 5.6)].

The pulse generator 18 is made according to the known scheme [6; (p. 310, fig. 14.6b)]. As a match scheme 14, 19, you can use the logical elements [6; (p. 318-120)], the proposed device uses the 155LAZ chip.

The pulse polarity inverter 15 is made on an operational amplifier according to the known scheme [5; (p. 32. Fig. 2.1b)]

As the counting trigger 20, you can use the included universal trigger in a known manner [6; from. 324)], specifically used 155TM2.

The proposed device interference compensation works as follows.

The main input of the device receives useful signals and noise, mainly the noise comes to the compensation input. In adder 1, the interference of the main and compensation inputs is subtracted. Joint regulation of amplitudes and phases of interference for their further subtraction is provided by amplitude regulators 6, 8 and quadrature phase shifter 7.

The control voltages of the regulators 6, 8 come from the outputs of the integrators 9, 10. Two-way change of the control voltages occurs due to the accumulation by the integrators 9, 10 of the control pulses of positive or negative polarity. The control sequence of the regulators 6 and 8 is determined by switching the first and second keys 11, 12 in accordance with the selected tuning algorithm.

The uncompensated residual noise at the device output, after detection in the detector 2 and smoothing in the low-pass filter 3, is an error signal of the feedback loop of the device.

Storing the level of the error signal in the sample-storage unit 4 for one clock cycle allows using the comparator 5 to evaluate the direction of change of the error signal - its increase or decrease. Decreasing the error signal causes the selected direction to change the control voltage of the amplitude regulator 6 or 8 to the next control step, increasing the error signal causes a change in this direction, and in practice, reversing the polarity of the control pulses.

Control pulses are generated in the pulse generator 18 and are input to the matching circuit 14.

The voltage-to-pulse converter 13 in each clock cycle generates a pulse upon arrival of the clock pulse, the duration of which depends on the level of the error signal, and which goes to the second input of matching circuit 14. Thus, at the output of matching circuit 14, bursts of control pulses are formed, and the number of pulses per the packet corresponds to the error signal level. The minimum error signal corresponds to the minimum number of pulses in the packet, which determines the smallest step in the variation of control voltages and, ultimately, the value of the minimum attainable residual noise. The highest level of the error signal corresponds to the largest number of pulses in the burst, determined from the stability requirements of the device, and, accordingly, the largest tuning step of the amplitude controllers 6 and 8. Due to this dependence, in the initial setting period, when the level of the error signal is large, the adjustment is made in large steps, providing fast rough adjustment of the device, and with a decrease in the error signal, the tuning step is reduced to the minimum, providing the necessary accuracy of noise compensation.

The polarity of the control pulses accumulated by the integrators 9 and 10 in each control cycle is determined by the state of the counting trigger 20, the output voltages of which open one of the keys 16, 17 in turn.

The state change of the counting trigger 20 is as follows. Before the clock synchronization sample-storage block arrives at the clock input, the current value of the error signal from the output of the low-pass filter 3 acts on one input of the comparator 5, and the sample of this error signal made by the sampling-storage block according to the previous clock synchronization acts on the other input of the comparator 5. The resolving level for the second matching circuit 19 at the output of the comparator 5 is generated when the current value of the signal exceeds the sampling error of this signal for the previous clock cycle. Thus, the clock clock passes through the second coincidence circuit 19 and changes the state of the counting trigger 20 when the level of the error signal per control cycle increases, i.e. when the direction of regulation is wrong in terms of suppressing interference. A change in the state of the counting trigger 20 causes the switching of the third 16 and fourth 17 keys, broadcasting to the inputs of the keys 11, 12 and then to the integrator 9 or 10 pulses of opposite polarity and, accordingly, changing the direction of regulation of the amplitude regulator 6 or 8.

The joint operation of the newly introduced blocks provides the regulation of the amplitudes and phases of the interference of the compensation input of the device in steps, the magnitude of which depends on the level of uncompensated interference. At the initial stage of tuning, these steps are large and provide a high convergence rate of the interference compensation process, but at the final stage they are small and provide the necessary accuracy of noise compensation.

Thus, in the proposed device provides an increase in the speed of compensation for interference without compromising the accuracy of their compensation.

The technical efficiency of the proposed device is to increase the speed of noise compensation. This allows you to increase the effective time of the radar, even in conditions of switching interference.

The economic efficiency of the proposed device lies in the fact that to achieve the same increase in the sub-noise visibility of the radar (on average, when exposed to switching active interference), for example, by increasing the power of the transmitter, much higher costs are required.

Literature

1. US patent No. 3881177, 1975, T. 933, No. 5.

2. R.I. Kolotushkin "Auto Compensator with Search Oscillations". Questions of special radio electronics. Ser. RLT. issue 21, 1984, p. 130-136.

3. M.A. Leikykh "About compensation of interferences by means of the search extreme auto-compensator". Questions of special radio electronics. Ser. RLT, issue 1, 1984

4. "Radio" No. 11, 1986

5. V.I. Shcherbakov, G.I. Grezdov. "Electronic circuits on operational amplifiers. Kiev," Technics ", 1983

6. Handbook of circuitry for a radio amateur. Ed. V.P. Borovsky, Kiev, "Technique", 1987

Claims (1)

An interference compensation device comprising a series-connected adder, the first input of which is the main input of the device, and the output is the output of the device, a detector, and a low-pass filter, a sampling-storage unit, the information input of which is connected to the output of the low-frequency filter, a comparator, the information input of which connected to the output of the sample-storage unit, and the input of the reference voltage is connected to the input of the sample-storage unit, a phase shifter on π-2, the input of which is the compensation input of the device, the first and second amplitude controls, the signal inputs of which are connected, respectively, with the first and second outputs of the phase splitter on π-2, and the outputs are connected, respectively, with the second and third inputs of the adder, the first and second switches, the first and second integrators, the inputs of which are connected with the outputs of the corresponding keys, and the outputs are connected to the control inputs of the respective amplitude controllers, the control inputs of the first and second keys are, respectively, the first and second control inputs of the device, and the block sync input sample-storage is a device sync input, characterized in that, in order to improve performance, a voltage-pulse width converter is introduced into it, the information input of which is connected to the output of the low-pass filter, the first element And, the first input of which is connected to the output of the voltage-duration converter pulse, the third key, the pulse polarity inverter, the input of which is connected to the output of the first element And, and the output is connected to the information input of the third key, a pulse generator, the output of which the second is connected to the second input of the first element And, the fourth key, the information input of which is connected to the output of the first element And, is connected in series to the second element And, the first input of which is connected to the output of the comparator, and a counting trigger, the direct and inverse outputs of which are connected, respectively, with the control inputs of the third and fourth keys, the outputs of the third and fourth keys are connected to the information inputs of the first and second keys connected in parallel, and the second input of the second AND element and triggering the input d Converter voltage-pulse duration connected to the sync input of the device.