RU2007044C1 - Device for search of noise-like signal - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: device has mixer 1, wide-band amplifier 2, demodulator 3, narrow-band amplifier 4, detector 5 with low frequency filter, controlled heterodyne 6, discriminator 7, correcting amplifier 8, controlled clock 9, gate 10, OR gate 11, delay line 12, gate 13, random number generator 14, m channel gates 15₁-15_m, OR gate 16_m, m correlation meters 17₁-17_m, m threshold gates 18₁-18_m, p additional threshold units 19₁-19_р, halving counter 20, switch 21, m commutators 23₁-23_m, m voltage scaling circuits 24₁-24_m, controlled timer 25, m multiplexers 26₁-26_m, threshold number counter 27, OR gate 28, decoder 29. EFFECT: increased speed of search for noise-like signal.

Description

 The invention relates to radio engineering and can be used to search for complex noise-like signals in radar, telemetry and communication systems.

 Known devices for searching for noise-like signals that use multi-channel search schemes with a two-stage procedure. The disadvantage of these devices is that the decrease in the average search time due to the two-stage procedure is limited by the fact that the analysis time at the first stage is fixed and does not depend on the actual signal-to-noise ratio at the input of the search device.

 Of the known devices for searching for a noise-like signal, the closest in technical essence is a device for searching for noise-like signals.

 However, it has a significant drawback: loss of time during the search due to the fact that the analysis time and thresholds when examining the "empty" (without signal) positions of the uncertainty region are fixed and do not depend on the actual signal-to-noise ratio at the input of the device.

 The purpose of the proposed device search for noise-like signal is to reduce the search time.

 The drawing shows a block diagram of the proposed device.

 The device comprises a series-connected mixer 1, the first input of which is the information input of the search device, a broadband amplifier 2, a demodulator 3, a narrow-band amplifier 4, a detector with a low-pass filter 5 and a controlled local oscillator 6, the output of which is connected to another input of the mixer 1.

 To the output of the broadband amplifier 2, the inputs m of the correlators 17 are connected and the discriminator 7 is connected in series, a correction amplifier 8, a controlled clock generator 9, to the output of which are connected the first valve 10, the second element OR 11, the PSP generator 14; serially connected delay lines 12, the second gate 13 and the clock input of the scanning unit with an additional output 22, the first output of which is connected to another input of the controlled local oscillator 6, and the second and third outputs are connected respectively to the control inputs of the first valve 10 and second valve 13, the output of which connected to another input of the second element OR 11.

 The fourth output of the scan unit with an additional output 22 is connected to the input of the threshold number counter 27 and m threshold valves 18 connected in series, the output of the last of which is connected through the key 21 to the “Reset” inputs of m correlators 17 and the threshold number counter 27 and the scan unit input with an additional output 22, the additional output of which through the counter 20 to 2 is connected to the control inputs of m switches 23, the first inputs of which are connected to the outputs of the corresponding m correlators 17 directly, and the second inputs through matching m level 24 divisors.

 The outputs of the PSP generator 14 are connected to the reference inputs m of the correlators 17 and the signal inputs m of the channel gates 15, the outputs of which are combined on the first element OR 16, the output of which is connected to the second input of the discriminator 7 and demodulator 3.

 The outputs of each of the m switches 23 are connected to the control inputs of the m channel gates 15 and m of the threshold gates 18 and to the common input of the corresponding mth group of P additional threshold blocks 19 (P = 1, 2, ...) and m multiplexers 26, the signal inputs of which are connected to the outputs P of the additional threshold blocks 19, and the outputs of the multiplexers 26 are combined on an additional OR element 28, the output of which is connected to the first input of the controlled timer 25, the output of which is connected to the control input of the key 21.

 The outputs of the counter of the threshold number 27 are connected to the control inputs of the corresponding m multiplexers 26 and through the decoder 29 to the other input of the controlled timer 25.

 The proposed device operates as follows.

The input broadband signal by the mixer 1 is transferred to the industrial frequency and, through the broadband amplifier 2, is fed to the signal inputs of the correlators 17m, in which the input signal and the reference signals from the outputs of the SRP 14 are convolved. The value of the convolution voltage at the output of the correlators 17 _m makes a decision about the presence or absence of a signal at the investigated position of the signal uncertainty region. The full signal search cycle is divided into two: in the first cycle, the search is carried out under the assumption of a “strong” signal at the input of the search device (large signal-to-noise ratio), and in the second, in the assumption of a “weak” signal (minimum acceptable signal-to-noise ratio). In the first search cycle, a “log. 0” is set at the output of the counter 20 by 2, which is fed to the control inputs of the switches 23 _m , while the output signals of the correlators 17 _m are supplied to the inputs of the additional threshold elements 19 _m ^p and the threshold valves 18 _m through switches 23 _m after attenuation by voltage dividers 24 _m . In the second search cycle, the signal at the output of the counter 20 and 2 with the installation is set to "log. 1" and the output signals of the correlators 17 _m pass through the switches 23 _m without attenuation. For fixed threshold values of additional threshold elements 19 _m ^p and threshold gates 18 _m, this is equivalent to searching the first cycle with a high threshold, i.e., with a false alarm probability F -> 0.

The circuit connected to the outputs of the i-th switch 23 _i (1≅i ≅m) has P + 1 threshold levels that satisfy the condition
U ₁ <U ₂ <. . . <U _p <U _{p + 1} (1)
The first P levels are set by the i-th group consisting of P additional threshold elements 19 _i ^p , the last P + 1 threshold level is in accordance with (1) the maximum and is set by the i-th threshold valve 18 _i . If the maximum threshold value is exceeded by the signal from the output of the switch 23 _{i, the} corresponding elements — the switch valve 15 _i and the threshold valve 18 _i open and close, respectively. The outputs of the additional threshold elements 19 _i ^p alternately in order of increasing threshold values (and numbers) through the corresponding multiplexer 26 _{i are} connected to the corresponding input of the second OR circuit 28.

The multiplexers 26 _{m are} controlled by a code coming from the outputs of the counter 27 of the threshold number. This code is generated as follows. 22 scanning unit with an additional output at intervals T _a, equal time analysis examined position in the first stage, instructs closure analyzing a pulse supplied through the series connected threshold valves 18 _m and a key 21 for adjusting the input number threshold counter 27 and input "Reset "correlators 17 _m , setting them to the initial state, in which the outputs of the first (in each of m groups) additional threshold elements 19 _m ^{1 are} connected to m inputs of the second OR circuit 28 through multiplexers 26 _m . If during the analysis of any position the minimum threshold value U _{1 is} not exceeded in any of the m channels, then the analysis termination pulse again passes through the series-connected threshold valves 18 _m and key 21, discharges the integrators in the correlators 17, sets the number counter 27 threshold to the initial state and, returning to the scanning unit 22, with an additional output, changes by 1 the state of the corresponding counter, which registers the number of positions studied, and produces a shift of the reference sequence. Scanning by delay consists of shifts of the reference signals by m clocks, i.e., by the value of m τ, where τ is the duration of the SRP element.

Frequency scanning is performed by changing the frequency of the controlled local oscillator 6 by Δf, which is consistent with the bandwidth of the correlators 17 _m , each time after viewing all positions by delay (taking into account the time of transient processes). If necessary, shift by m cycles performed first closing valve 10 and opening the second valve 13 for the time during which the first pulse counter m at node 22 with additional scanning output managed counted from the clock generator 9. To generate pulses with period T _and the first counter complement a decoder tuned to the number K _a = T _a / τ. The second counter in the scanning unit 22 with an additional output keeps track of the pulses arriving through the key 21 to its clock input. When this counter counts a predetermined number of pulses equal to N / m, where N is the period of the SRP, a transfer pulse occurs (for example, from the decoder of the 2nd counter), which is sent to the input of the third counter from the DAC. Moreover, the latter is calibrated together with the local oscillator 6 so that a change in the number at its input by 1 changes the frequency of the local oscillator 6 by Δf. When the third counter counts the number of pulses equal to ΔQ / Δf, where Δ Q is the region of uncertainty of the signal by frequency, the output of the decoder connected to it has an impulse to complete the search cycle over the entire time-frequency region of uncertainty, which is fed to the additional output of the scanning unit 22 with an additional exit.

This pulse of the end of the search cycle changes the state of the counter 20 to 2 with the installation, while the control inputs of the switches 23 _m receive "log. 1" and the output signals of the correlators 17 _m pass through them without attenuation, and the second cycle of the signal search begins.

If during the analysis of T _and any position in the i-th channel in any of the search cycles observed exceeding of the threshold value of the first stage U ₁ without exceeding the maximum threshold level U _{P + 1,} the first supplemental threshold element 19 _i ¹ belongs to the i group i is triggered and its output signal through the corresponding multiplexer 26 _i and the second circuit OR 28 is fed to the first input of the controlled timer 25, which closes the key 21 for the time ΔT _a , which is necessary to prohibit the passage of the next pulse of the end of the analysis (in this case, the reset of integrators in the correlators of 17 _m descends and the analysis time of the studied position increases by the value of T _a ). The next pulse comes from the scanning unit 22 with an additional output after a time T _a , changes the threshold number 27 to the control inputs of the multiplexers 26 _m through 1 counter code 27, through which the outputs of the second will be connected to the inputs of the second circuit OR 28 at the 2nd analysis stage additional threshold elements 19 _m ² with threshold values U ₂ .

If at one of the steps after successively exceeding 1, 2,. . . , K - 1 threshold values in the Kth additional threshold element, the level U _{K was} not exceeded (K ≅ P), the next pulse of the analysis completion passes through key 21, resets the correlators 17 _m , sets the counter 27 of the threshold number to the initial state, and, Returning to the scanning unit 22 with an additional output, it changes by 1 the code of the corresponding counter of the studied positions and carries out the shift of the reference SRP. Moreover, in contrast to the prototype device, where the first stage of analysis (see Fig. 3) has a fixed duration T ₁ , in the proposed device (see Fig. 4), the decision about the absence of a signal at this position can be made at any of P steps (in Fig. 4 shows the case when P = 2) for a time less than T ₁ , which leads to a reduction in search time.

If the threshold values are 19 _i ¹ . . . 19 _i ^{p are} successively exceeded in all P additional threshold elements of the i-th channel without exceeding the maximum level U _{P + 1} , then the threshold number counter generates a code of the (P + 1) -th state in which the outputs of all additional threshold elements 19 _m ^{p are} disabled from the second OR circuit 28, and at the output of the decoder 29, a signal is generated that arrives at the second input of the controlled timer 25, which was started at the previous stage, after which the duration of its output signal increases to the value T _n > ΔT _a . In this case, the key 21 is closed and the analysis time of this position increases to the value necessary for a more reliable decision on the presence or absence of a “convolution” signal in this channel. A controlled timer can be made in the form of a circuit consisting of two timers. The outputs of the timers are combined in an OR circuit, the output of which is the output of a controlled timer, and the first input is the input of the first timer. The second timer is started by the output signal of the first, and the output of the first timer is connected to the input of the second through a key controlled by a memory element with a reset, which stores the output signal of the decoder 25, which is supplied to the second input of the controlled timer.

If during the test T _n there is no excess of the (P + 1) th (maximum) threshold level in the channel being tested, then the key 21 opens, passes the next pulse of the end of the analysis and the device proceeds to the analysis of the next position by delay.

If the maximum level P + 1 of the threshold level U _{P + 1} is exceeded in the tested i-th channel, then the search device decides to detect the signal, i.e., the corresponding switching gate 15 _i opens and the reference memory bandwidth of this channel through the OR 16 circuit enters discriminator 7, and the corresponding threshold gate 18 _{i is} closed, turning off the search and the device enters the signal tracking mode. This mode is implemented by the AFC circuit, which includes a mixer 1, a broadband amplifier 2, a demodulator 3, a narrowband amplifier 4, a low-pass filter 5, controlled by a local oscillator 6, and a delay tracking circuit consisting of a discriminator 7, a correction amplifier 8, a controlled clock generator 9, the first gate 10, the element OR 11, the generator PSP 14, one of the shifted sequences of which, corresponding to the detected channel, enters through the circuit OR 16 to the discriminator 7.

 A positive effect when using the proposed device is to reduce the average signal search time and is achieved due to the fact that the full search cycle consists of two cycles: the first - for a "strong" signal with high thresholds and a minimum probability of false alarm, in which the multistage analysis is "empty" "position ends at the initial stages, and the second - for a" weak "signal with thresholds optimal for its detection, at which the step analysis time at each position is variable No, not exceeding a fixed analysis time of the first stage in a two-stage search. (56) Copyright certificate of the USSR N 1095433, cl. H 04 L 7/04, 1982.

Claims (1)

 NOISE-SEARCH SEARCH DEVICE containing a series-connected mixer, the first input of which is the information input of the device, a broadband amplifier, a demodulator, a narrow-band amplifier, a detector with a low-pass filter and a controlled local oscillator, the second input of which is connected to the first output of the scanning unit, the first element is connected in series OR the inputs of which are connected to the outputs of the m-channel gates (where m = 1, 2,..., n), a discriminator, the second input of which is connected to the output of the broadband an amplifier, a correction amplifier, a controlled clock generator, a first gate, a second OR element, and a pseudorandom sequence generator (PSS), the outputs of which are connected to the signal inputs m of the corresponding channel gates and the reference signal inputs of the corresponding correlators, the reset inputs of which are connected to each other, connected in series m threshold gates, the control inputs of which are connected to the control inputs of m corresponding channel gates, a delay line connected in series the input of which is connected to the clock input of the scanning unit and the output of the controlled clock generator, and the second valve, the output of which is connected to the second input of the second OR element, the control inputs of the first and second valves are connected respectively to the second and third outputs of the scan unit, characterized in that , in order to reduce the search time for a noise-like signal, m level dividers, m switches, m groups of p additional threshold blocks (p = 1,2,. . . p), m multiplexers, a sequentially connected decoder, a controlled timer, the second input of which is connected to the output of an additional OR element, and a key, as well as a counter for two and a threshold number counter, while the output of each of m correlators is connected to the inputs of the corresponding level divider and switch, the second input of which is connected to the output of the level divider, the control inputs m of the switches are interconnected and with the additional output of the scan unit through the counter by two, and the output of each of m switches is connected to the control the input input of the corresponding channel gate and with p connected additional threshold blocks of the mth group, and the outputs p of the additional threshold blocks of each of the m groups are connected via the corresponding multiplexer to the corresponding input of the additional OR element, the output of the mth threshold gate is connected via key to the input of the scanning unit, with the reset inputs of m correlators and with the installation input of the threshold number counter, the input of which and the input of the first threshold valve are connected to each other and to the fourth output the house of the scanning unit, and the output of the threshold number counter is connected to the control inputs of m multiplexers and to the input of the decoder.