SU1753616A1 - Signal spectrum analyzer - Google Patents

Abstract

The invention relates to a technique for receiving wideband signals. It can be used to estimate the parameters of signals in a complex noise situation and a priori undetermined characteristics of the analyzed signals. SUMMARY OF THE INVENTION: signal spectrum analyzer, satellite driver, filter, dispersed delay line, detector, synchronizer, linear frequency-frequency modulated local oscillator, threshold unit, amplifier, And element, two inverters, two counters, two decoders, four blocks of And elements, three blocks of Counters, a block of delay elements, a block of decoders, a block of multiplexers, a delay element, a driver, a multiplexer and a key. 9 il.

Description

The invention relates to a technique for receiving and processing broadband signals and estimating their parameters under conditions of a complex noise situation and a priori uncertainty regarding the characteristics of signals.

A device for optimal processing of frequency-manipulated (FMN) signals is known, containing n receiving channels of the same structure, the outputs of which are connected to the corresponding inputs of the n-input adder whose output is the output of the device, the inputs of all channels whose number is equal to the known number of possible values of the input frequency signal, interconnected and form the input device. Each channel consists of a matched filter, amplifier and measuring channel. The input of the matched filter connected to the input of the measuring channel is a common input

receiving channel. The output of the matched filter is connected to the signal input of the amplifier, the control input of which is connected to the output of the measuring channel, and its output is the output of the receiving channel and is connected to the corresponding input of the adder common to all the receiving channels .. -. ;

It is also known to have a device that performs an optimal incoherent detection of FMN signals containing two mixers, an LFM-local oscillator. two band-pass filters, a first adder, a chirp filter, a delay line, two detectors, a second adder, a sampling pulse generator and a key. In this case, the inputs of the first and second mixers interconnected form the signal input of the device, the second inputs of the mixers are connected to the output of the chirped local oscillator, the input of which is the input of the device synchronization and

J

Xi

cl

Gj on

ABOUT

It is also not connected to the input of the sampling pulse generator, the output of which is connected to the key control input. The output of each mixer is connected by the input of its bandpass filter, the outputs of which are connected to the inputs of the first adder, the output of which is connected to the input of the chirp filter, the first output of which is connected to the input of the first detector, and the second output is connected to the input of the second detector connected to the inputs of the second adder, the output of which is connected to the information input of the key, the output of which is the output of the device,

The closest in technical essence to the present invention is a spectrum analyzer with a dispersive delay line (LLL) containing a mixer, chirping heterodyne, filter, LLL, detector, synchronizer, sweep generator and electron-beam indicator as a recording device. At the same time, the input signal is fed to one input of the mixer, the other input of which is connected to the output of the chirped oscillator, and the output is connected to the input of the filter, the output of which is connected to the input of the DLLD, whose output is connected to the input of the detector, the output of which is - a radiation tube (CRT), the horizontal deflection plates of which are connected to the output of the sweep generator, the input of which is connected to the output of the synchronizer, the second output of which is connected to the input of the chirped oscillator.

The device can operate under conditions of a priori uncertainty regarding the characteristics of the input signal, but it has limited possibilities in terms of distinguishing the types of input radio signals (quasi-harmonic, CWM-signals, time-frequency matrices, impulses) and estimates of their parameters.

The aim of the invention is to expand the class of analyzed signals (quasi-harmonic, CWM signals, pulse signals), estimate the number of signals simultaneously present at the input and determine their characteristics (frequencies and durations of elements of CWM signals, duration of quasi-harmonic and pulse signals and their frequency), as well as automating the analysis process.

The goal is achieved by the fact that a device containing a serially connected mixer, a filter and a dispersive delay line, a detector, a synchronizer and a linear-frequency-modulated local oscillator, is introduced into the threshold

block, amplifier, And element, first and second inverters, first and second counters first and second decoders, first, second, third and fourth blocks of And elements, first, second and third blocks of counters, block of delay elements, block of decoders, multiplexer and block multiplexers, delay, signal conditioner and key.

Dispersion delay line (DLZ), designed to compress a linear-frequency-modulated (chirp) pulse with a rectangular envelope

Uc (t) UmCOs Ub t - 0.5 {4 t,

Jc 2

(one)

has impulse response type

h (t) cos (Oo t + 0.5 fi t2, -0.5TC t 0.5TC, (2)

where Tc is the pulse duration and impulse response;

/ 2jrAfc / Tc is the coefficient characterizing the rate of change of the frequency of the chirp pulse (L fc is the deviation of the frequency of the signal pulse).

The chirp-impulse of the form (1), arriving at the DLZ input with an impulse response (2), creates at its output a response described by the expression

UB.x (t) umVBsint ° ta c-Jt

fi t

 COS (Do I, (3)

the maximum value of the envelope of which at t 0 is equal to Um VB where V DtsTs is the base of the input pulse, and the duration at the level of the put power decreases by a factor of comparison with the duration of the input pulse.

If the DLS 4f bandwidth, within which the linear dependence of the delay on frequency (with the rate of change / g / 2) is satisfied, exceeds Afc, while maintaining the other signal parameters, but changing the values of the average frequency of the signal fo, the DRL response will remain unchanged. form (3), however, the delay time of the compressed pulse will change.

Figure 1 shows the dependence of the signal delay in DLZ frequency

fa (t) - 1 (L-0. + kti 2 lg d fc / Tc.

If a radio pulse with a duration Tc and a frequency fc, which does not have frequency modulation, arrives at the information input of the mixer, a voltage from the local oscillator is applied to its other input, which is a periodically linear-frequency-modulated oscillation fV (t)

the mean frequency, the frequency deviation fr and the frequency modulation period Tg Tc. then, at the output of the mixer, LFM pulses are generated with a difference frequency fc - fr (t) and a frequency modulation period equal to Tg 5 Passes such pulses through the DLZ, we get a series of short Odlz pulses, the delay of each of which is 1E relative to the chirp frequency difference - linearly dependent on the value of fc10

(fc-fro) + kt (4) l

In this case, it is assumed that the values of the rates of change of the frequency of the heterodyne g and the corresponding parameter 4 of the dispersion delay line are equal in absolute value and opposite in sign. The described process is depicted in FIG.

If the input of a device that performs the described operations is affected by a complex broadband signal in the form of an often-manipulated, continuous signal with

with a duration of TC Tg, with an unknown, but 25 constant duration of the element Te (FBM signal), with unknown values and the number of manipulated frequencies (Fig. 3), then at the range of manipulated frequencies of the signal A fc (L tdlz - A fr), where 30 tdlz span of the linear part of the dispersion characteristics of the DLS, a pulse sequence is formed at the output of the DLS, the duration of each of which is tn 1 / Afr, and the temporal location of 35 of each of which, relative to the moment of the frequency difference, is determined by the corresponding frequency input signal. To obtain at least one 40 full amplitude squeezed pulses from each input signal element at the DLZ output, it is necessary that the TCH modulation period Tg does not exceed 0.5Te. This requirement is associated with a random time of 45. The time of the occurrence of elements relative to the beginning of the chirp cycles, which will be called frequency sweeps in the following. Obviously, to select the sweep duration in frequency Tg 50, it is necessary to have a priori knowledge of the minimum possible duration of the Temin element in the input signal

Tg O.TTeamim.

If the real value of Te is Tr, then at 55 each sweep in frequency from each element of the input signal there will be a series of pulses equally spaced from the beginning of the sweeps. The number of Ke pulses in each series can serve as an estimate of the duration of the element.

Tae KeTg,

having a rms error

about 0,5TG / (}.

The described phenomenon is depicted in FIG. 3 where the elements 1 and 2 of the input signal have a duration Te and frequencies fi and f2, the chirping LO frequency has an average value for, and the series of compressed pulses from the first element, indicated by 1, consists of pulses delayed with respect to differences frequency chirp-heterodyne at time t3i proportional to the frequency fi. The compressed pulses of the series, designated 2, are delayed by the time ta2 1e1 in accordance with the value of h. The presence in the sequence of pulses at the output of the SLD of a group of series having the same duration (the same Ke value), but different delay of the pulses, which is unchanged in each series, is a sign of a CBM signal.

A sign of a quasi-harmonic signal is a sequence of impulses at the output of a DLS, each of which has the same delay, constituting a single series with a duration of Te, which is commensurate with the duration of the analysis interval T0, i.e.

Te T0, Ke).

A sign of a pulse signal is a sequence of pulses at the output of a DLS, each of which has the same delay, but divided into several groups of the same duration with Te "To, Ke" (To / Tr).

The delay of pulses in sequences of pulses generated by a quasi-arma signal or a pulsed signal is uniquely related to their frequency and can be used to estimate it. If several different frequency signals are present at the input, the difference in frequency exceeds the potential resolution of the device.

Afpasp 1 / Tg,

on each frequency sweep, the corresponding number of individual compressed pulses are arranged according to the frequencies of the input signals. This phenomenon is indicative of the number of signals acting simultaneously on the input of the device (figure 4).

The purpose of further processing the flow of pulses from the output of the SLP is to, on the basis of its analysis, for a certain time interval with a duration

Then set: the number of radio signals acting on the device input within the interval To; determine the type of acting signals (from among: quasi-harmonic, pulsed, ChWM-signals) time-frequency matrices //; to evaluate the characteristics of the acting signals: the frequency or set of frequencies, the duration of the elongation of the CWM signal, the pulse duration and the period of the pulse signals, the duration and frequency of the quasi-harmonic signal.

If one places under one another a group of pulses corresponding to individual frequency sweeps obtained as a result of analyzing the input signals over the interval T0, for example, the picture shown in Fig. 5 is obtained, making it possible to work out the rules for processing the received pulse sequence to achieve the goal. . In Fig. 5, tn 1 / Afr is the duration of the compressed pulse, which determines the potential frequency resolution b f 1 / Tg. The number m is related to the duration of the analyzed implementation T0 by the ratio

m That / Tr,

and the number n, representing the number of allowed gradations in frequency

p Tgdp Tg -Afr B. The dots in Fig. 5 indicate the position of squeezed pulses at frequency sweeps (at intervals ITr ... (l + 1) Tr) for an additive mixture of two signals acting on the device input, one of which is a BWM signal with an element duration in the frequency range from fH to (fr + 4 / Tr), and the other is a quadharmonic signal with a duration greater than T0. and frequency (fn + 9 / Tr), where TH is the lower frequency of the analyzed frequency range of input signals.

The algorithm for processing a sequence of squeezed pulses consists in forming a histogram (distribution) of the number of signals simultaneously present in each of the m frequency sweeps.

Ki f (l). 1 1,2,3p.,

where Yu is the number of sweeps in frequency within which I signals are recorded. In this case, the numerical value Ki is equal to the relative duration of the i-fold signals in the interval T0. If, for example, i 1 and Ki m, then we can say that a quasi-harmonic signal with Tc T0 acted at the input (Fig. 5, line-by-line analysis).

And also in the formation of a family of p histograms (distributions), each of which corresponds to a specific value of T.z. (hence, the resolution value of the frequency from the analyzed range of the partial), and represents the distribution of the number of series of compressed pulses with the same series duration (Fig.5 postcolumn analysis). Each of histograms of this family

Cth (j) j 1,2,3m; 1 1, 2.3, ... n,

where Ltj is the number of series of pulses containing by j pulses in a series at a frequency of elements of the input signal defined by value I. For example, if a device has a CWM signal having 5 values of frequencies of elements with a duration of element Ta 12TG, then the number and value the signal frequencies will be determined by the corresponding numbers and values of I

non-zero histograms, the ascissus j of the numbers C 0 determines the duration of the element

fa-JTr, and the LJI numerical value gives information

the relative duration of all elements with this frequency within the interval T0. The affiliation of the input signal to the type of CVM is indicated by the equality of the values of all recorded.

Figure 1 shows the dispersion characteristic of the compressive filter (for example, DLZ); 2 are timing diagrams illustrating the relationship between the time-frequency characteristics of the input signal, the chirping local oscillator, the signal converted in the mixer, and the output pulses of the SLP; FIG. 3 shows timing diagrams illustrating the formation of a series of compressed pulses; figure 4

- timing diagrams illustrating the process of resolving input signals in frequency when they temporarily overlap; Fig. 5 illustrates the time-frequency dependence of the location of squeezed pulses in the analysis interval of duration To; on figb - functional diagram of the device; PA 7 is timing diagrams illustrating the interconnection of processes occurring in the proposed device;

on Fig is a possible variant of the functional diagram of the synchronizer; Fig. 9 shows timing diagrams explaining the principle of operation of the synchronizer.

The device consists of a mixer 1,

5 filter 2, delayed dispersion line 3, amplifier 4, detector 5, threshold unit 6, chirp local oscillator 7, synchronizer 8, first counter 9, element 10, first decoder 11, first inverter 12,

the first block of elements And 13 (13.1 ... 13.p), the second block of elements And 14 (14.1 ... 14.p), the first block of meters 15 (15.1 ... 15.p), the block of elements 16 (1 6.1 ... 1 bp) delay, the block of decoders 17 (17.1 ... 17.p), the third block of elements And 18 (18.1.1 .... 18.1. T) ... (18. p. 1 ... 18. p. M.) Of the SECOND block of counters 19 (19.1.1 .., 19.1.m) ... (19, n.1 ... 19.nm), block of multiplexers 20 (20.1 .. 20.t), the second counter 21, the delay element 22, the second decoder 23, the fourth block of the And 24 elements (24.1 .., 24.p), the counter block 25 (25.1 ... 25.p.), the multiplexer 26, the second in - the driver 27, the driver 28 of the signal and the key 29. At the same time, the mixer 1, fil lp 2, the dispersion delay line 3, the amplifier 4 and the detector 5 are connected in series. The second input of the mixer 1 is the input of the analyzer, and its first input is connected to the output of the chirped local oscillator 7. The detector output is connected to the first input of the threshold unit 6, to the second input of which the reference voltage is supplied from the reference voltage source device. The output of the threshold unit 6 is connected to the second input element And 10, the first input of which is connected to the input of the second inverter 27 and the third input of the synchronizer 8, the first output of which is connected to the input of the chirp-heterodyne, the first inputs of the fourth block of elements And 24 and the input of the delay element 22, and the second output is connected to the input of the first counter 9, the outputs of which are connected to the second inputs of the key 29 and the inputs of the first decoder 11. The output of the element 10 is connected through the first inverter 12 to the first inputs of the first block of elements 13 and directly first enter the second counter 21 and the first inputs of the second block of elements 14, the second inputs of which are connected to the corresponding second inputs of the first block of elements 13 and the corresponding outputs of the first decoder 11, and the outputs are connected to the corresponding second inputs of the first block of meters 15, the first inputs of which through the corresponding delay elements of the block of the delay elements 16 are connected to the corresponding outputs of the first block of elements And 13 and the corresponding second inputs of the third block of elements And 18, and the output coupled to corresponding inputs of block decoders 17, the outputs of which are connected to respective first inputs of the third unit element 18 and whose outputs are connected with the corresponding

the first inputs of the second block of counters

19, the second inputs of which are connected to the second inputs of the third block of counters 25 and the output of the driver 28 signals, and the outputs are connected to the corresponding second inputs of the multiplexer block

20. The outputs of which are the third outputs of the analyzer, and the first inputs are connected to the second inputs of the multiplexer 26 and the outputs of the key 29, which are the first outputs of the analyzer. The first input key 29 is connected to the output of the second inverter 27 and the input of the signal conditioner 28. The outputs of the second counter 21 are connected to the inputs of the second decoder 23, the outputs of which are connected to the corresponding second inputs of the fourth block of elements And 24, the outputs of which are connected to the corresponding first inputs of the third block of counters 25, the outputs of which are connected to the corresponding inputs of the multiplexer 26, the outputs of which are the second outputs of the analyzer.

The device works as follows.

At the first input of the mixer 1, the input radio signal Uc (t) or additive is supplied - a mixture of signals of the form: FMM, quasi-harmonic, pulsed. The second input of the mixer 1 from the LCHM-local oscillator 7 receives the sequence Ur (t) of the chirp oscillations (fig.7b), which have a period of frequency modulation Tr, frequency deviation 4tg and its average value Afro. The period Tg of continuous chirp oscillations is set by the synchronizer 8 at its first output (Fig. 7b) connected to the input of the chirp local oscillator 7. LFM heterodyne oscillations convert the input signal of the mixer 1 into the chirp oscillation of the difference frequency separated from other combinational frequency filter 2. Thus, after frequency conversion, the input signals acquire a periodic linear frequency modulation with a period Tr, frequency deviation dfr and a mean frequency equal to fci - fro, where fci is the value of the f-th frequency of the input signal. The input to the dispersion delay line 3, having a dispersion characteristic consistent with the chirp modulation parameters of the converted signal, turns into a sequence of short pulses (fig.7g), each of which corresponds to one time interval of oscillation at the input of the dispersion delay line 3, having continuous chirp throughout the Tg of this segment. The temporal position of each pulse relative to the beginning

Every period L (IM corresponds to the value (fci - fro), i.e. determined by the final frequency of the frequency fci. Transformation of the chirp signal in the dispersion delay line 3, resulting in the frequency fci being transformed into a time delay of the pulses The sequence of radio pulses from the output of the dispersion delay line 3 is forced by amplifier 4, which compensates for attenuation in the dispersion line 3 of the holder, and is fed to the input of the detector 5, the output of which is a sequence of video pulses to be further processed to extract useful information about the parameters of the input signal from it. This sequence goes to the first input of the quantizer b, the output of which produces a pulse signal in the levels of logic zero and one used by the element base. above the reference voltage supplied to the second input of the threshold unit 6, a video pulse with an amplitude of a logical unit appears at its output, otherwise the output the threshold unit is present logic-zero level. Binary amplitude quantization allows the spurious pulses generated by the noise accompanying the received signal to be screened out, as well as the pulses from the elements of the input signal obtained with an incomplete frequency sweep. This situation arises at the border of the elements, when the end or the beginning of the element falls between the beginning and the end of the frequency sweep - inside the interval Tg. These pulses will have a reduced amplitude.

The pulse sequence from the output of the threshold unit 6 is fed to the second input of the element 10, which carries out a time selection for the implementation of a pulse sequence of duration T0, within which the subsequent analysis is carried out. For this, the first input of the element AND 10 from the third output of the synchronizer 8 is supplied with a strobe of duration T0 (fig.Ta), which passes a sequence of pulses to the output of the element 10 And (fig.7g)

That mTr, m 1, The pulses from the output of the element And 10 are fed to the first inputs of the second block of elements And 14 directly and to the first inputs of the first block of elements And through the first inverter 12, as well as to the input of the second counter. The second block of elements And 14 transmits input pulses to the outputs,

if at its second outputs the potential of a logical unit acts, and does not let pass, if the potential of a logical zero acts on them. On the second entrances of the first

13 and the second 14 blocks of elements AND are supplied with potentials from the corresponding outputs of the first decoder 11. The parallel binary code from the outputs of the first counter 9 is fed to the inputs of this decoder,

the input of which receives a continuous sequence of pulses from the output 2 of the synchronizer 8. The period of these pulses Tm and the moments of their occurrence are rigidly connected with the duration of Tr and the temporal arrangement of the chirp cycles, and

Tg ptt,

where n is the number of permissible gradations of the frequency of the input signal.

The first counter 9 is in mode

continuous counting with overflow, so the binary code at its outputs varies cyclically from 0 to n with a period of Tr (Fig. 7d) and is strictly synchronized with the cycles of changing the chirp frequency of the local oscillator 7. Therefore

on the p outputs of the first decoder, successively, pulses appear cyclically, which alternately open on the second input the corresponding pairs of elements AND blocks of elements 13 and 14. If

at these intervals, the first inputs of the second block of elements 14 are present with a pulse from the output of the element 10 and then the contents of the corresponding counter of the first block of counters 15 are added to the unit arriving through the open corresponding element of block 14 at its second input. If s these time intervals the pulse at the output of the element And 10 is missing, then through the corresponding element of the delay block

delay elements 16 will reset this counter potential at its first input.

In Fig.7 e, f, s depict temporary

diagrams illustrating this process. Thus, each of the counters of the first block of counters 15 during the analysis interval T0 calculates the duration of a series of compressed pulses having the same delay relative to the chirping frequency oscillator, and therefore corresponding to a certain value of the input signal frequency. Each of the counters of the first block 15 accumulates these pulses if they repeat without gaps in their place in each frequency sweep.

At the first appearance of a pass (no impulse in place), the counters

 15 are reset (cleared) through

the corresponding elements of block 13 and the corresponding elements of the block 16, which are necessary for temporarily coordinating the operation of the counters of the first block 15, the decoders of the block 17, the elements of block i

During the analysis interval T0, the outputs of each counter of block 15 form different binary codes corresponding to the duration of a series of pulses with the same time delay. 3 itJ duration of the series is an estimate of the duration of the element of the input signal, which has the corresponding frequency value. For example, if at the output of the counter 15Tj, the binary number code is 7, then this means that in the input signal, there is a cell with a duration of Te 7TV and a frequency equal to fH + j / Tr. In order to count the number of identical durations Te of signal elements having the same frequency, the output of each counter of block 15 is connected to the input of the corresponding decoder of the block of decoders 17. These decoders work similarly to the first decoder 11, i.e. the potential of a logical unit appears only on that decoder output, the number of which corresponds to the binary code at its inputs.

Each output of each decoder unit 17 through the corresponding elements And the third block of elements And 18 connected the first inputs of the corresponding counters of the second block of counters 19. The contents of each of these counters through the corresponding element And block 18, opened by the potential of a logical unit from the corresponding output 1 .. .t the corresponding decoder of block 17, a unit is added whenever the corresponding counter of the first block of counters 15 is reset. For example, if an input signal is encountered in the input signal nt with a duration of Te 13TG and a frequency fH + 8L, then for 13 sweeps in frequency at the time of the occurrence of the potential of a logical unit at the eighth output of the first decoder 11, counter 15.8 of block 15 will be sequentially recorded with tact Tg with another 13 units (13 pulses in the series are equally located at the output of the AND 10 element, since the moments of the appearance of these pulses coincide with the intervals of occurrence of logical units at the eighth output of the first decoder 11). In the process of writing these 13 units to the counter 15.8, the binary code at its output will change from a value of 0 to a value of 13. In this case, the potentials of the logical will appear

units at the outputs 1 ... 13 of the decoder 17.8, alternately opening the elements AND 18.8.1 ... 18.8.13 of block 18, however, the increase in the contents of the account 5 19.8.1, .. 19.8.12 of block 19 will not occur, so as on the second inputs of the elements And 18.8.1 .., 18.8.12 of the block 18 at these moments there will be no impulse of the logical unit. This impulse is only on Wits, when from the 13th

0 output of the decoder 17.8 block potential logical 1 will open the element And 18.8.13 block 18m at the first pulse transmission in the considered series of pulses from the output of the element D 13.8 block 13 will add

5 unit to the contents of the counter 19.8.13 of block 19, and then with some delay in the delay element 16.8 of block 1-6 will reset the contents of the counter 15.8 of block 15 to zero.

0 Thus, by the time the analysis interval T0 ends, the counters of the second block of meters 19 are set to binary codes that are numerically equal to the number of corresponding durations Te of the elements

5 input signals and corresponding frequencies. So, in the counters: 19.1.1 is the number of elements of cTe Tg at the frequency fi fH + ./Tg; 19.1.2-Te-2Tg + 1 / Tr;

0 19.1.3- TE ZTG fi fH + 1 / Tr:

TE TG Te

., f5 fH + 5 / Tr; 2TG f5 fH + 5 / Tr;

19.5.m - Te - f5 TH + 5 / Tg;

19.pt. Te ttg fn TH + p.

The outputs of the counter of block 19 through the corresponding multiplexers of the block of multiplexers 20 are connected alternately to the corresponding third outputs of the analyzer during the time interval Tg immediately following the interval of analysis T0 (Fig. 7a, k). This is achieved by

connection via the key 29 of one cycle of binary codes from the output of the first counter chip (Fig. 7 m) to the first inputs of the multiplexer block 20. In accordance with the values of the changing binary code on these

the inputs alternately (with a clock change of T m) connect the corresponding second inputs of the corresponding multiplexer of block 20 with the corresponding third outputs of the analyzer. Key

29 is opened by a pulse of duration T at its first input, obtained by inverting the voltage of the third output of the synchronizer 8 by the second voltage inverter 27 (FIG. 7 a, k). Let us call this time interval the read interval. Inputs

ultiplexer 20.1 block multiplex 20 is connected to the outputs of the corresponding counters 19.1.1; 19.2.1; 19.3.1; ...; 19.p.1 of the second block of counters 19 and therefore at its output, within the reading interval, alternately formed numbers equal to the number of elements of the input signal Te in Tr at each of the allowed frequencies

fn + 1 / Tr, fH + 2 / Tr. .... fH + P / Tg.

Similarly, the inputs of the multiplexer 20.I block 20 are connected to the outputs of the corresponding counters 19.1.1; 19.2.1; 19.3.1; .... 19.d.I. Thus, within the read interval, the outputs of the multiplexer unit 20, and therefore, the third outputs of the analyzer, during the first cycle Tt of the readout interval, contain m parallel binary codes, each of which is numerically equal to the number of elements of the input signal having a duration Tg; 2TG; ZTg, ..., tT at the frequency fi + fic + 1 / Tg (distribution or histogram of the duration of elements of the input signal at the frequency fi in the analysis interval T0); during the second clock period Ti of the read interval, the outputs of these multiplexers will have a histogram of the duration of elements having a frequency of f2 fn + 2 / Tr, and so on until the end of the read interval, when the binary codes on the outputs of the block of multiplexers 20 form a histogram of the duration of the elements of the input signal frequency fn fH + n / Tr.

Simultaneously with the analysis of the input process according to the duration of the elements, the analyzer provides for its analysis by the number of signals forming the input process. This analysis is carried out by counting the number of signals differing in frequency by more than resolution discrete

,

in each frequency sweep (at each interval of Tr, fig.ug). For this, a sequence of pulses from the output of the element 10 is fed to the first input of the second counter 21, to the second input of which, through the delay element 22, short pulses are applied to reset the contents of the second counter into the input. These pulses correspond to the instants of the end of the sweeps in frequency (Fig. Tb). Therefore, in each frequency sweep cycle, the second counter 21 counts the number of compressed pulses in this train / az, equal to the number of signals with different allowed frequencies (Fig. T3). Before the counter is zeroed, the reset pulses from the output of the delay element 22 add one to the contents of the corresponding counter of the third block of meters 25. This correspondence is provided by the second decoder 23, the inputs of which receive a varying parallel binary code from the outputs of the second counter 21, and the output of the second decoder 23, whose number is equal to the value of the input binary code, is set to the logical unit that opens to the second input the corresponding element And the fourth block of elements And 24 and the pulse from the first output of the synchronizer, arriving at the first

5, the inputs of the fourth block of elements AND 24, adds one to the contents of the corresponding counter of the third block of meters 25, connected by its first input with the output of said element I,

0 of block 24. Thus, by the end of the analysis interval T0, the counters of the third block of meters 25 contain binary codes, numerically equal, respectively; In 25.1 - the number of sweeps in frequency on the interval T0,

5 in which one signal is fixed; in 25.2 - the number of frequency sweeps in the interval To, in which two signals are recorded, and so on; 25.n - the number of sweeps in frequency, in which n signals were recorded. The outputs of the third block of counters 25 are connected to the corresponding first passes of multiplexer 26, to the second (control) inputs of which, during the read interval, a sequence of rising-parallel binary codes with tact Tm from the outputs of key 29 is fed. At the same time, the outputs of multiplexer 26 are fed to The second outputs of the analyzer, alternately, starting from the first, connect the outputs of all n counters of the third block 25. Thus, within the reading interval Tr, the second outputs of the analyzer appear A number of parallel binary codes representing a soto histogram of the number of signals.

The outputs of the key 29 are the first outputs of the analyzer, in which within the reading interval at any moment there is a parallel binary code, numerically representing the signal frequency, which at this moment in time corresponds to a histogram of the duration of the elements represented by parallel binary codes on the third outputs of the multiS typlexors 20.

The 8 ends of the read interval, when accumulated during the analysis interval. That information issued to the first, second and third outputs of the analyzer, the analyzer should be restored to its initial state of readiness for analyzing the next implementation of the input process. This is accomplished by a reset pulse, which appears at the output of the signal generator 28, which coincides in time with the moment the reading interval ends and arrives at the second inputs of the second 19 and third 25 blocks of counters, which has encircled them.

The resulting histograms of element durations and the histogram of the number of signals are frequency-time portrera of the input signals, the nature of which also allows you to set the number of signals simultaneously acting on the analyzer input and their type (from the number of CVM, quasi-harmonic, pulse) by the described characteristics, and also evaluate their frequency and duration (the duration of the elements).

Most of the functional blocks of the proposed device, being known nodes of digital computing devices, can be made on the basis of high-speed elements of emitter-coupled logic (ECL). The first 9 and second 21 counters, as well as the counters of the first 17, second 19, and third 25 blocks of counters can be executed, for example, in the form of binary counters based on the K500 I / IE 136 modules. Element 10; The first 13, second 14, third 18 and fourth 24 blocks of elements And can be performed, for example, on the basis of modules K500 LL 110. The first 12 and three 27 inverters can be executed, for example, on the basis of K500 LE 111. The key 29 is a set of two-bit components And, one of the inputs of each of which is connected to the corresponding line of the multi-discharge output bus of the counter 9. The second inputs of all the elements And are interconnected and form the first (control) input of the key. It can be implemented on the basis of modules K500 LL 110. Multiplexer 26 and multiplexers of block 20 can be made, for example, on the basis of modules K500 ID 164 or K1500 ID 163, K1500 ID 164. The first 11, second 23 decoders and decoders of block 17 can be made, for example, on the basis of modules K1500 IL 170.

The signal conditioner 28 performs the function of forming a short pulse along the falling edge of a square pulse output from the second inverter 27 and can be performed, for example, on logic elements.

The delay elements of blocks 18 and 22 can be performed, for example, on the basis of several logical units connected in series (NOT, AND, OR), using the natural delay of signal propagation in them, as is done, for example, in the short pulse driver circuit.

The 5th threshold unit 6, which performs the function of the threshold device, may be made, for example, on the basis of the amplitude comparator K521SAZ.

10 F o rumlula and z o bre et e

A signal spectrum analyzer containing serially connected mixer, filter and dispersion delay line, detector, synchronizer and linear frequency modulated local oscillator, the input and output of which are connected to the first synchronizer output and the mixer input, the second input of which is the analyzer input, This is due to the fact that, in order to expand the class of the analyzed signals, a threshold unit, an amplifier, serially connected element AND and the first inverter, serially connected are introduced the first

5 counter and decoder, serially connected second counter and decoder, first and second blocks of elements And, first block of counters, block of delay elements, block of decoders, third block of elements

0 And, the second block of counters, the block of multiplexers, the delay element connected in series by the second inverter and the signal conditioner, the fourth block of elements And, the third block of counters, the multiplexer and

5 key, the first and second inputs of which are connected respectively to the output of the second inverter and the outputs of the first counter, the input of which and the first input of the element And are connected respectively to the second and

0 the third outputs of the synchronizer, the first output of which is connected to the input of the delay element and the first inputs of the fourth block of elements And, the second inputs and outputs of which are connected to the corresponding

The 5 outputs of the second decoder and the first inputs of the third block of meters, the outputs of which are connected to the first inputs of the multiplexer, the second inputs of which are connected to the key outputs, the first inputs of the multiplexer unit, are the first outputs of the analyzer, the second and third outputs of which are the outputs of the multiplexer and multiplexer block outputs, second inputs

5 of which are connected :: to the corresponding outputs of the second block of meters, the first inputs of which are connected to the outputs of the third block of elements I, the first inputs of which are connected to the outputs of the block of decoders, the inputs of which are connected to

the outputs of the first block of meters, the first inputs of which through the block of delay elements are connected to the corresponding outputs of the first block of elements And the second inputs of the third block of elements And, the output of the dispersion delay line through the amplifier is connected to the input of the detector, the output of the element And is connected to the first input of the second counter and the first inputs of the second block of elements And, the first inputs of the first and second inputs of the second block of elements And connected to the corresponding outputs of the first decoder, the output

the signal conditioner is connected to the second inputs of the second and third meter blocks, the output of the first inverter is connected to the second inputs of the first block of elements And, the outputs of the second block of elements And are connected to the corresponding second inputs of the first block of meters, and the third output of the synchronizer is connected to the input of the second inverter The second input element And is connected to the output of the threshold unit, the first input of which is connected to the output of the detector, and the second input of the threshold unit is the reference input of the analyzer.

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Claims (1)

Claim A signal spectrum analyzer containing a series-connected mixer, a filter and a dispersion delay line, a detector, a synchronizer, and a linearly-frequency-modulated local oscillator, the input and output of which are connected to the first synchronizer output and mixer input, the second input of which is the analyzer input, characterized in that, in order to expand the class of analyzed signals, a threshold block, an amplifier, a series-connected element And, and a first inverter, series-connected the first a meter and a decoder, a second counter and a decoder connected in series, a first and a second block of AND elements, a first counter block, a delay element block, a decoder block, a third And block of elements, a second counter block, a multiplexer block, a delay element, a second inverter and a shaper connected in series signal, the fourth block of AND elements, the third block of counters, a multiplexer and a key, the first and second inputs of which are connected respectively to the output of the second inverter and the outputs of the first counter, the input of which is the first the first input of the And element is connected respectively to the second and third outputs of the synchronizer, the first output of which is connected to the input of the delay element and the first inputs of the fourth block of And elements, the second inputs and outputs of which are connected to the corresponding outputs of the second decoder and the first inputs of the third block of meters, the outputs of which are connected to the first inputs of the multiplexer, the second inputs of which are connected to the outputs of the key, the first inputs of the multiplexer block and are the first outputs of the analyzer, the second and third outputs which are respectively the outputs of the multiplexer and the outputs of the unit of multiplexers, the second inputs of which are connected :: to the corresponding outputs of the second block of counters, the first inputs of which are connected to the outputs of the third block of elements And, the first inputs of which are connected to the outputs of the block of decoders, the inputs of which are connected to the outputs of the first block of counters , the first inputs of which through a block of delay elements are connected to the corresponding outputs of the first block of elements And and the second inputs of the third block of elements And, and the output the dispersion delay line through the amplifier is connected to the detector input, the output of the element And is connected to the first input of the second counter and the first inputs of the second block of elements And, the first inputs of the first and second inputs of the second blocks of elements And are connected to the corresponding outputs of the first decoder, the output of the signal conditioner is connected to the second the inputs of the second and third blocks of counters, the output of the first inverter is connected to the second inputs of the first block of elements And, the outputs of the second block of elements And are connected to the corresponding second moves of the first block of counters, and the third output of the synchronizer is connected to the input of the second inverter, while the second input of the And element is connected to the output of the threshold block, the first input of which is connected to the output of the detector, and the second input of the threshold block is the reference input of the analyzer. ϊί \ Fig. H Figa φι / g. B ^H iiiiiiiiifciiiiiiiiir ^; July 7 + "ι_ π π π π π ηη π π π π π π π π ⁶ Li ι ι II ί Ί Ύ ι ι ι ι ι ι Γ a H. Z7 Anolysis and Accumulation Zone Fig 9 Tr mfy Zonar ——— ——— >> I give the result. mama