RU1841025C - Device for determining the type of intrapulse modulation - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: device further comprises, including a driver, the input of which is connected to the output of the delay element, the first counter, the first key, the output of which is a device output, the second driver in series connected to the output of the amplifier-limiter, the second counter, the second input of which is connected to the output of the first counter and the second key, the input of which is connected to the second input of the second counter and the output is the second output of the device, wherein the control inputs of the first and the second keys are connected to the output of the device for recognizing the linear-frequency-modulated signal.

EFFECT: expanding the functionality by determining the direction of frequency deviation of a linear-frequency-modulated signal.

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Description

The proposed device for determining the parameters of intrapulse modulation of linear-frequency-modulated (chirp) signals belongs to the receivers of pulse information and is intended for use in radio intelligence stations (RTR) and passive target designation systems (PSTSU) as an apparatus for distinguishing and estimating the parameters of intrapulse modulation of signals.

As the first analogue, we consider the device by author. swith No. 1840962 (application 1575094 dated February 21, 1974), in which to determine the type of modulation of complex signals, the multiplication of two signals shifted in time is used, and further weighting of the energies of certain parts of the beat signal spectrum is performed at the multiplier output. The beat signal spectrum during LFM signal processing is concentrated in a relatively narrow band and much narrower at the input signal of the device, and the beat signal spectrum during the phase shift keying (FM) signal is inversely proportional to the delay time in the multiplier circuit (autocorrelator) and much wider than the beat signal spectrum during processing Chirp signals. According to these distinctive features of the beat signal spectra, the processing of the chirp and FM signals makes a decision on the type of modulation of the input signal. The disadvantage of this device is the narrow range of operating frequencies of the channel to distinguish between FM signals and the required high signal-to-noise ratio, which determines low sensitivity.

As a second analogue, consider the device according to ed. swith No. 1841158 (application 1587293 dated March 14, 1975), in which the autocorrelator is made according to a quadrature circuit to expand the frequency range of distinguishing FM signals. The algorithm for deciding on the type of modulation is similar to that discussed above, so the low sensitivity of the device is its disadvantage.

In the considered analogs, a common autocorrelator is used to distinguish between FM and LFM signals, while the requirements for the delay duration in the autocorrelator circuit for processing FM and LFM signals are contradictory. If, for processing FM signals, the delay time must be no more than the duration of the partial radio pulse of the FM signal, practically not more than 0.2 µs, then for processing the chirp signals, the delay in the autocorrelator circuit is determined by the duration and frequency deviation of the chirp signal and practically amounts to at least 0, 5 µs Having a common delay line circuit autocorrelator can not meet these conflicting requirements, so considered analogues distinction and FM chirp signal is made within a narrow range of parameters intrapulse modulation signals being processed (e.g., when choosing the delay time in a chain _of autocorrelator τ = 0.5 ms we confidently distinguish the chirp signals, but the FM signals are distinguished only when the partial radio pulse duration is more than 0.5 µs). Therefore, a narrow range of parameters of the intrapulse modulation of the processed chirp and FM signals is a disadvantage of the considered analogs.

As the third analogue, consider the device according to the author. swith No. 1840896 (application 2206387 dated July 5, 1976), in which separate channels for processing the chirp and FM signals are used to expand the range of modulation parameters of the processed signals. Each channel contains autocorrelators, which include delay lines, multipliers and filters, and the delay in the autocorrelator circuit of the channel for processing the chirp signal is chosen much more than the analogous delay in the channel for processing the FM signal. To distinguish between the chirp signal, information on the bipolarity of the voltage of the beat signal at the output of the autocorrelator low-pass filter is used. This method of implementing the device leads to the fact that when processing FM signals, the response of the autocorrelator of the channel of the chirp signal is also bipolar and a false indication of the chirp signal reception is generated at its output. To exclude false information when processing FM signals, blocking of the formation of the characteristic of the chirp signal, which is carried out by the characteristic of reception of FM signals, is performed. However, the sensitivity of the channel for processing the chirp signal in this device is 5–7 dB higher than the sensitivity of the channel for processing the FM signal due to the different bands at the outputs of the autocorrelators of the corresponding channels (the band of processing FM signals is much wider than the band for processing the chirp signals). Different channel sensitivity leads to the fact that FM signals in the dynamic range 5-7 dB higher than the sensitivity level of the processing channel of chirp signals are taken as chirp signals, because in this band the channel for processing FM signals does not work and does not block the channel for processing the chirp signal. Therefore, in this dynamic range, the device has a low reliability of distinguishing signals on the output of the "chirp".

As a fourth analogue, we consider a device in which, to increase the reliability of distinguishing chirp signals, the algorithm of equality of time intervals between zero-transitions of the beat signal of the autocorrelator response to the chirp signal is used. Formation of the sign of receiving chirp signals is produced here after successive comparison of each current interval between adjacent zero-transition pulses of the autocorrelator response with its previous value, that is, two adjacent intervals are always compared, and the decision on receiving the chirp signal is taken when three or more are equal (depending on the required statistical reliability of distinguishing) such intervals. The time intervals between zero-transitions of the beat signal at the output of the autocorrelator on the FM and other types of signals are not the same and false information at the output of the "chirp" from their influence in the device is missing.

As the fifth analogue, we consider the device by author. swith No. 1841016 (application No. 3102645 dated September 24, 1984), in which to distinguish between the chirped signals, the algorithm considered when describing the fourth analogue is used, but the formation of the sign of receiving the chirped signals is produced here after successive comparison of each of the current intervals between adjacent zero-transition pulses beat signal with an average value of the interval within the duration of the distinguishable chirp signal. This leads to an increase in the sensitivity of the device while ensuring high reliability of distinguishing chirp signals.

A common drawback of the considered analogs is the lack of measurement of the parameters of the intrapulse modulation of a distinguished chirp signal, which reduces the effectiveness of the RTR and PSTsU systems in solving problems of signal selection and identification, identifying the type of radar station and its carrier, and the organization of radio countermeasures. The low effectiveness of solving these problems is due to the fact that in the modern theater of military operations most of the potential enemy radars use chirp signals. Under these conditions, knowledge of the type of modulation of a complex signal is not enough to successfully solve these problems. Other distinctive features of signals from each other within each species are required. These can be, for example, the parameters of intrapulse modulation of complex signals. When distinguishing chirp signals, the main parameters of intrapulse modulation are frequency deviation, frequency tuning rate, and direction of frequency deviation. The considered analogues do not allow estimation of the parameters of the intrapulse modulation of signals, which is their disadvantage.

As the sixth analogue, consider the device by author. view. No. 1841020 (application 3167395 dated 04.04.1987), which is an improvement of the fifth analogue described above in order to increase its efficiency by measuring the frequency of chromo-frequency signal tuning. The device allows you to determine one of the parameters of the intrapulse modulation of the chirp signal, which increases the efficiency of the PTP and PSCU systems.

The proposed technical solution is aimed at eliminating the above disadvantages of the known devices and allows you to make an assessment of the direction of the frequency deviation of the chirp signal, which will increase the efficiency of the systems RTR and PSTSU.

As a prototype, we select the device by author. swith No. 1841158 (application 1587293 dated March 14, 1975), considered in the description of the second analogue, which is close to the proposed device to the technical essence and most closely to it in general features.

The known device (Fig. 1) contains a series-connected limiting amplifier whose input is the input of the device, a delay line, a quadrature power divider, a first multiplier, the second input of which is connected to the output of the limiting amplifier, the first band-pass filter, the first peak detector and the comparison circuit whose output is the output of the device, and also contains a reset pulse shaper, the input of which is connected to the output of the amplifier-limiter, a low-pass filter whose input is connected to the output of the first multiplier, the second peak detector, whose input is connected to the output of the low-pass filter, and the output to the second input of the comparison circuit, and the second multiplier connected in series, the first and second inputs of which are connected, respectively, to the output of the limiting amplifier and the second output of the quadrature the power divider, the second bandpass filter and the third peak detector, the output of which is connected to the first input of the comparison circuit, and the control input is connected to the control inputs of the first and second peak detectors and to you the pulse shaper reset.

As mentioned above, the disadvantage of the prototype is the impossibility of estimating the parameters of intrapulse modulation of complex signals, which reduces the effectiveness of the RTR and PSCU systems in solving the problems of signal selection and identification, recognition of the type of radar and its carrier, and the organization of radio counteraction.

The aim of the present invention is to improve the efficiency of the device by measuring the direction of the frequency deviation of the chirp signal.

This goal is achieved by the fact that in the known device containing the amplifier-limiter, the input of which is the input of the device, the delay element, the input of which is connected to the output of the amplifier-limiter, and the comparison circuit, introduced two keys, the control inputs of which are connected together and are the control input devices, and the signal inputs of the first and second keys are connected, respectively, with the first and second outputs of the comparison circuit, two inputs of which are connected, respectively, with the output of the delay element and with the output of Ithel limiter, and outputs the keys are output devices;

the comparison circuit contains two pulse shapers, the inputs of which are the inputs of the comparison circuit and two pulse counters, the outputs of the first and second drivers are connected to the counting inputs, respectively, of the first and second pulse counters, the high-order transfer outputs of which are connected to zeroing inputs, respectively , the second and first pulse counters and are the outputs of the comparison circuit.

Thus, the introduction of new elements and connections into the device made it possible to obtain a new effect — an increase in efficiency by changing the direction of the frequency of the chirp signal.

The authors are not aware of technical solutions that have features that match the distinctive features of the proposed technical solution.

FIG. 2 shows a block diagram of the proposed device.

The device contains an amplifier-limiter 1, delay elements 2, comparison circuit 3, keys 4, 5. Comparison circuit 3 contains pulse shapers 6, 7 and pulse counters 8, 9.

The input of the limiting amplifier 1 is the input of the device. The output of the amplifier-limiter 1 is connected to the input of the comparison circuit 3, as well as through a delay element 2 - with another input of the comparison circuit, the outputs of which are connected to the signal inputs of keys 4, 5, the outputs of which are the outputs of the device, and the control inputs of which are connected together and control input device. The inputs of the comparison circuit 3 are the inputs of pulse formers 6, 7, the outputs of which are connected to the counting inputs of pulse counters 8, 9, the transfer outputs of the most significant digits of which are connected to the zeroing inputs of other pulse counters and are the outputs of the comparison circuit.

To determine the slope sign of the chirp frequency deviation, the frequencies of the delayed and non-chirped signals are compared. It uses the fact that with a positive frequency deviation sign (the frequency of the signal increases linearly within the pulse duration) the frequency of the delayed chirp signal will be less than the frequency of the unaltered chirp signal at the same time. With a negative deviation sign, the frequency of the delayed chirp signal will be higher than the frequency of the delayed.

The device works as follows.

The received chirp signal, the sign of the slope of the frequency deviation of which is necessary to determine, goes to the amplifier-limiter 1, which serves to amplify the signal to a level sufficient for further digital devices, and then to the input of the frequency comparison circuit 3, to the second input of which the signal comes from the output of the amplifier-limiter 1 through the delay element 2.

From the inputs of the comparison circuit 3 through pulse formers 6, 7, which are used to pair the signals from the output of the amplifier-limiter 1 and delay element 2 with the levels of digital logic used, amplitude-normalized pulses with the frequency of the delayed and unlabeled chirp signals arrive at the pulse counters 8 and 9. If the frequency of the delayed signal is higher than the frequency of the non-delayed one, then at the transfer output of the high-order pulse counter 8, the transfer pulse appears earlier than at the output of the pulse counter 9. In this case, the pulse Enos output of the pulse counter 8 resets the pulse counter 9 and at its output pulses are absent. Thus, when the frequency of the delayed chirp signal exceeds the frequency of the delayed signal (which corresponds to receiving the chirp signal with a negative slope of the frequency deviation), the output of the pulse counter 8 will contain pulses of the sign of the chirp signal with a negative slope of the frequency deviation. With a positive slope of the frequency deviation, when the frequency of the unbound chirp signal is higher than the frequency of the delayed, the pulses of the characteristic of receiving the chirp signal with a positive slope of the frequency deviation will be present at the second output of the frequency comparison circuit (output of the pulse counter 9). By analogy with the above, they reset the pulse counter 8 until a transfer pulse appears at its output.

From the outputs of the comparison circuit 3, the pulses of the signs of receiving a chirp signal with a negative or positive slope of the frequency deviation are received through the keys 4 and 5 to the output of the device. The keys are used to prohibit the issuance of false information when processing other types of signals, for example, when receiving multi-frequency signals. For this purpose, a strobe is supplied to the control inputs of the keys when receiving chirp signals, for example, from the output of the device for recognizing chirp signals.

The number of bits used pulse counters is determined by the required accuracy of the frequency comparison. For practical cases, when the delay time of the delay element is within 0.5 ÷ 1 μs and the slope of the increase of the chirp signal of more than 1 MHz / μs using high-speed emitter-coupled transistor logic (in the layout used pulse counters on the 500IE134 chip and a delay of 0.5 μs, performed on the cable RC-75-2-11) four pulses of the pulse counters are sufficient to ensure the accuracy of the determination of the slope sign of the frequency deviation of the received chirp signal with a probability higher than 0.95.

All nodes of the proposed device are made according to well-known standard schemes of modern analog and digital equipment.

The use of the proposed device in the RTR and PSTSU stations allows to improve the quality of solving problems of signal selection and identification, increase the probability of identifying the type of radar and its carrier, and improve the organization of effective radio countermeasures.

Claims (1)

A device for determining the type of intrapulse modulation according to the author's certificate No. 1841158, characterized in that, in order to extend the functionality by determining the direction of the frequency of the chirp signal, serially connected shaper is entered, the input of which is connected to the output of the delay element, the first counter and the first key, output which is the first output of the device, connected in series to the second driver, the input of which is connected to the output of the limiter amplifier, second counter, sec second input coupled to an output of the first counter and a second key, the input of which is connected to the second input of the first counter and the output is the second output of the apparatus, the inputs of the first and second switch control connected to a device outlet for recognition the chirp signal.

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