RU44833U1 - COMPLEX SIGNAL PROCESSING DEVICE - Google Patents

Abstract

The utility model is aimed at expanding the range of Doppler frequency shifts analyzed by the processing device of a complex quasi-continuous signal with a large base. The specified technical result is achieved in that the specified range of Doppler frequency shifts is divided into K + 1 sections, which are processed in parallel using the main and K additional channels of the correlation-filter segment signal processing. K local oscillators and K multipliers provide an offset of the input signal supplied to each additional processing channel by an amount multiple of the range of Doppler frequency shifts analyzed by one channel. The vernier delay blocks provide a change in the duration of the reference signals in additional processing channels so as to compensate for the change in the duration of a quasi-continuous signal with a large base, which is due to the movement of the target during the coherent signal processing in this channel. 1 C.p.F., 3 ill.

Description

The utility model relates to the technique of correlation receivers and can be used in radar stations with a complex quasi-continuous probing signal when targets are detected in a wide range of Doppler frequencies.

A distinctive feature of radars with a complex quasicontinuous signal is the long duration and wide spectrum of the emitted signal. For the coordinated processing of such signals, correlation-filter signal processing devices consisting of a set of complex signal demodulators and a comb of Doppler filters are preferred (V. Sloka. Issues of processing radar signals. M., Soviet Radio, 1970. - C.114). However, the correlation filter scheme has limitations when processing complex quasi-continuous signals with a large base in a wide range of Doppler frequencies. They are related to the fact that a high-speed target can fly a distance equal to or greater than the size of the resolution element over a distance equal to the signal duration. In this case, the movement of the target causes not only a Doppler frequency shift, but also a change in the signal duration, which must be taken into account during its coordinated processing.

The closest to the present utility model in terms of technical nature and the achieved result when used is a device for processing a complex signal according to the patent (RU No. 34757 U1, IPC 7 G 01 S 7/28, 2003).

The known device (see figure 1) can be represented as a series-connected clock pulse generator 1 (TI generator 1), a reference signal generation block 2 (FOS block 2), a signal segment compression block 3 (CCC block 3), the input of which is the input of the device and the spectral processing unit 4 (CO unit 4), the output of which is the output of the device, as well as the synchronization signal generation unit 5 (FSS unit 5), the input of which is connected to the output of the generator 1 TI, and the output is connected by the synchronization bus to the third input block 3 CCC and from the second an input unit 4 SB.

CCC block 3 contains N signal segment correlators, each of which contains a multiplier and an integrator connected in series with memory and reset, and a multiplexer with their connections. The first input of block 3 CCC are the second

the inputs of N multipliers connected by a bus of reference signals to the output of block 2 FOS. The second input of block 3 CCC, which receives the input signal, are the first inputs of N multipliers. The clock and reset inputs of N integrators with memory and reset, as well as the address inputs of the multiplexer, are combined into a common block synchronization bus and are the third input of CCC block 3.

Block 4 WITH contains the first RAM, the second RAM, the FFT processor and the envelope detector with their connections. The first input of the CO unit is the information inputs of the first RAM and the second RAM, and the output is the envelope detector output. Address, clock and write inputs - reads of the first RAM and the second RAM are combined into a common synchronization bus of the block and are the second input of the block 4 WITH.

Block 5 of the FSS contains a frequency divider, the input of which is the input of block 5 of the FSS, a binary counter of a range element, a binary counter of signal segments, a trigger record - read, and a switch with their connections. The outputs of the blocks included in the FSS unit 5 are combined into a common block synchronization bus, which is the second output of the FSS unit 5.

The device implements segmented convolution of complex signals and provides parallel signal processing in a wide range of delays and Doppler frequency shifts while reducing the cost of hardware implementation of the device. However, the prototype device when using quasi-continuous signals with a large base also has a limit on the maximum value of the Doppler frequency shift of the processed signal.

The correlation filter scheme for processing a complex signal can be applied if the condition

V _t · T _S <d ₀ ,

where V _t is the radial velocity of the target,

T _S - signal duration,

d ₀ is the resolution of the signal in range.

After simple transformations using the well-known relations between the parameters of a complex signal and the Doppler frequency shift, we obtain a restriction on the maximum value of the Doppler frequency shift of the signal processed by one processing channel

where f ₀ is the carrier frequency of the probe signal,

In - the value of the base of the complex signal.

For example, with f ₀ = 10 GHz and B = 10 ⁶ , the maximum value of the Doppler frequency shift of the processed signal ΔF is 10 KHz, that is, this limitation is significant when processing quasi-continuous signals with a large base reflected from high-speed targets.

The problem that this utility model aims to solve is to create a device that provides processing of quasi-nonperine signals with a large base when detecting targets in a wide range of Doppler frequency shifts.

The technical result achieved using the present invention is to expand the range of analyzed Doppler frequency shifts.

The task with the achievement of the above technical result is achieved by the fact that the device for processing a complex signal containing a series-connected clock pulse generator (TI generator), a block for generating reference signals (FOS block), a first block for compressing signal segments (CCC block), input which is the input of the device, and the first block of spectral processing (block СО), as well as a block for generating synchronization signals (block FSS), the input of which is connected to the output of the generator TI, and the output is connected by bus synchronization with the third input of the first CCC unit and with the second input of the first CO unit, a high-frequency clock pulse generator (VTI generator) is introduced, the input of which is connected to the output of the TI generator, K vernier delay blocks (NC), K local oscillators, K multipliers, K additional blocks CCC, K additional blocks of CO and a multiplexer, while the first, second and third inputs K of NC blocks are connected respectively to the output of the FOS block, to the output of the VTI generator and to the output of the FSS block, and the outputs are connected to the first inputs K of additional CC blocks C, the second inputs of which are connected to the outputs of K multipliers, the third inputs are connected to the outputs of the FSS unit, and the outputs are connected to the inputs of K additional blocks of CO, the outputs K of local oscillators are connected to the inputs of K multipliers, the inputs of the first block of CO and K of additional blocks of CO are connected to separate the inputs of the multiplexer, the control input of which is connected to the output of the FSS unit, and the output is the output of the device.

The extension of the range of analyzed Doppler frequency shifts in the inventive device is achieved by dividing the specified range of Doppler frequencies into K + 1 sections, which are processed in parallel. The possibility of parallel processing is achieved through the introduction of additional

blocks with their connections. The introduction of K local oscillators and K multipliers provides a shift of the input signal supplied to each additional processing channel by an amount multiple of the range of Doppler frequency shifts analyzed by one channel. NC blocks provide a change in the duration of the reference signal, which compensates for the change in the duration of a quasi-continuous signal with a large base, due to the movement of the target during the coherent signal processing.

The utility model is illustrated by drawings, on which:

figure 1 - structural electrical diagram of the device of the prototype;

figure 2 is a structural electrical diagram of the inventive device;

figure 3 is a structural electrical diagram of a vernier delay unit.

The device (see figure 2) contains K + 1 channels of correlation-filter segmented signal processing. The first channel form a series-connected block 3 CCC, the second input of which is the input of the device, and block 4 WITH. The remaining K channels consist of 10-1 ... 10-K CCC blocks and 11-1 ... 11-K СО blocks connected in series. The second input of block 3 CCC is connected to the second inputs of the multipliers 9-1 ... 9-K, the first inputs of which are connected the outputs of the local oscillators 8-1 ... 8-K, respectively. The output of block 1 of the generator TI is connected to the inputs of block 2 FOS, block 5 FSS and generator 6 VTI, the output of which is connected to the second inputs of blocks 7-1 ... 7-K NC. The output of the FOS block 2 is connected to the first input of the CCC block 3 and through blocks 7-1 ... 7-K NC with the first inputs of the blocks 10-1 ... 10-K CCC, the outputs of the multipliers 9-1 are connected to the second inputs of which ..9-K, respectively. The output of the FSS block 5 is connected by a synchronization bus with the third inputs of blocks 3, 10-1 ... 10-K CCC, with the second inputs of blocks 4, 11-1 ... 11-K CO, with the third inputs of blocks 7-1 .. .7-K NC and with the control input of multiplexer 12, the output of which is the output of the device. Separate inputs of the multiplexer 12 are connected to the outputs of blocks 4 and 11-1 ... 11-K WITH.

Blocks 1-5, 10-1 ... 10-K and 11-1 ... 11-K have no design features in comparison with the corresponding blocks of the prototype. The VTI generator 6, which generates clock pulses with a repetition rate increased by K times, multipliers 9-1 ... 9-K, local oscillators 8-1 ... 8-K and multiplexer 12 are well-known elements.

Each block 7-1 ... 7-K NC contains a shift register 13, the information input of which is the first input of block 7, a binary counter 14, the clock input of which is connected to the clock input of the shift register 13 and is the second input of block 7, the third input of which is the reset input of the binary counter 14, and

a multiplexer 15, the information and address inputs of which are connected to the output of the shift register 13 and the output of the binary counter 14, respectively, and the output is the output of block 7. Blocks 7-1 ... 7-K NC provide a shift of the reference signal to a fractional part of the clock cycle of the modulating sequence reference signal. The rate of change of the duration of the reference signal at the output of the multiplexer 15 depends on the number K of the processing channel and is determined by the discharge of the address signal supplied to the input of the multiplexer 15 of the K-th channel. The group of bits at the output of the binary counter 14 is shifted by one bit in the direction of the lower bits as the channel number increases.

The device operates as follows.

The input of the device (the second input of the CCC block 3 and the second inputs of the multipliers 9) receives an input signal to be processed in the range of analyzed Doppler frequency shifts from - F _dmax to ₊ F _dmax . For definiteness, we assume that the input signal is presented in the form of two quadrature components that underwent analog-to-digital conversion with a frequency f ₁ = 1 / T ₀ , where T ₀ is the time discrete of a complex quasicontinuous signal specified by a generator of 1 TI.

If we limit the range of frequency shifts analyzed by one channel of the correlation-filter segment processing from -ΔF / 2 to ₊ ΔF / 2, then the number of K channels for covering the required range of Doppler frequency shifts from - F _dmax to ₊ F _dmax is determined from the relation

K = 2F _dmax / ΔF-1.

The range of Doppler frequency shifts for each processing channel is . The parallel inclusion of such channels with an offset of the input signal arriving at the inputs of the processing channels by an amount multiple of ΔF provides the overlap of the required range of Doppler frequency shift. The key elements of the device are blocks 7-1 ... 7-K vernier delay. The clock inputs of the shift register 13 and the binary counter 14 receive clock pulses with a frequency K times the frequency of the clock pulses of the reference signal. The binary counter 14 is reset by pulses of the total signal duration. At the information input of the shift register 13, a reference signal is received, the delay of which at the output of the multiplexer 15 smoothly (with a small step equal to K fractions of the sampling interval of the input signal) changes by one delay resolution element during the coherent signal processing. In signal processing channels with positive frequency shifts, the delay decreases, and in channels with

negative frequency shifts - increases. After the end of the signal processing time, the delay in the NC blocks 7 is set to the initial state and the process repeats. Thus, blocks 7-1 ... 7-K NC provide compensation for changes in the duration of a quasi-continuous signal with a large base due to the movement of the target during the coherent signal processing in this channel.

The main and additional processing channels implement segment correlation-filter processing of complex signals in the corresponding range of Doppler frequency shifts similarly to the prototype (RU No. 34757 U1, IPC 7 G 01 S 7/28, 2003) and provide target marking with Doppler frequency shifts falling into given range. The output marks K + 1 of the processing channels are combined into a single stream by temporarily combining them with multiplexer 12.

Thus, at the output of the device in question, the results of processing a complex signal appear in the entire analyzed range of Doppler frequency shifts.

Claims (2)

1. A device for processing a complex signal containing serially connected clock generator (TI generator), a block for generating a reference signal (block FOS), a first block for compressing signal segments (block CCC), the input of which is the input of the device, and the first block for spectral processing ( block СО), as well as a block for generating synchronization signals (FSS block), the input of which is connected to the output of the TI generator, and the output is connected by a synchronization bus to the third input of the CCC block and to the second input of the CO block, characterized in that a high-frequency clock pulses generator (VTI generator) was introduced, the input of which is connected to the output of the TI generator, K vernier delay blocks (NC), K local oscillators, K multipliers, K additional CCC blocks, K additional CO blocks and a multiplexer, while the first, second and the third inputs K of the NC blocks are connected respectively to the output of the FOS block, to the output of the VTI generator and to the output of the FSS block, and the outputs are connected to the first inputs K of additional CCC blocks, the second inputs of which are connected to the outputs of K multipliers, the third inputs are sub are connected to the output of the FSS block, and the outputs are connected to the inputs of K additional blocks of CO, the outputs of K local oscillators are connected to the inputs of K multipliers, the inputs of the first block of CO and K of additional blocks of CO are connected to separate inputs of the multiplexer, the control input of which is connected to the output of the FSS block, and the output is the output of the device. 2. The device according to claim 1, characterized in that the vernier delay (NC) block contains a shift register, the information input of which is the first input of the NC block, a binary counter whose clock input is connected to the clock input of the shift register and is the second input of the NC block, the third input of which is the binary counter reset input, and the multiplexer, the information and address inputs of which are connected to the shift register output and the binary counter output, respectively, and the output is the output of the NC block.