SU1038949A1 - Device for correlation analysis (its versions) - Google Patents

Abstract

A device for correlation analysis, comprising a first module calculating unit, a unit calculating an instantaneous phase value, a delay unit, a subtracting unit, a convolution calculating unit, a sine calculating unit, a cosine calculating unit, two multipliers, two averaging units, a phase calculation glint, first and second the inputs of which are connected to the outputs of the first and second averaging blocks, respectively, the inputs of which are connected to the outputs of the first and second multipliers, respectively, the first inputs of which are connected to the output of the first block of the calculation The module slots, the first and second inputs of which are combined respectively with the first and second inputs of the instantaneous phase value calculation unit and are respectively the first and second information inputs of the device, the output of the instantaneous phase value calculation unit is connected to the first input of the calculation unit and the input of the delay unit, the output of which connected to the input of the subtraction unit, the output of which is connected to the platoon of the convolution calculation unit, the output of which is connected to the inputs of the sine calculation unit and the calculation unit to sine, the outputs of which are connected to the second inputs of the first and second multipliers, respectively; the output of the phase calculating unit is the first information output of the device, characterized in that, in order to expand the functionality by evaluating the correlation coefficient module, a third averaging unit is introduced into it The second module of the module calculation and the splitter, the output of which is the second information output of the device, the output of the first module of the module calculation is connected to the input of the third averaging block, the output of which is connected to the first input of the divider, the second input of which is connected to the output of the second module of the module calculation, the first and second inputs of which are connected to the fg outputs of the first and "L" second averaging blocks, respectively. 2. A device for correlation analysis, containing the first module calculating unit, instantaneous phase value calculating unit, delay unit S, subtraction unit, convolution calculating unit, sine calculating unit, cosine calculating unit, two multipliers, two averaging units, block 00 calculating the phase, the first and second inputs of which are connected to the outputs of JQO, respectively, the first and second blocks CO averaging, the inputs of which are connected to the outputs of the first and 4 CO of the second multipliers, the first inputs of which are connected to the output p The first module of the module calculating unit, the first and second inputs of which are combined with the first and second inputs of the unit of calculation of the instantaneous phase value, are the first and second information inputs of the device, respectively; the output of the unit of calculation of the instantaneous phase value is connected to the first input of the subtractor and the input of the delay unit, the output of which is connected to the second input of the subtraction unit, the output of which is connected to the input of the calculation unit

Description

a convolution whose output is connected to the inputs of the sine calculation unit and the cosine calculation unit, the outputs of which are connected to the second inputs of the first and second multipliers, respectively, and the output of the phase calculation unit is the first information output of the device, which is e with the fact that, in order to extend the functionality by evaluating the modulus of the coefficient of correlation with a given estimation discreteness, P switches, nl elements AND, OR element, fixed memory block, n у1 "1 multipliers, h blocks sra the third averaging unit, the second module calculating unit, the output of the first module calculating unit are connected to the input of the third averaging unit, the first and second inputs of the second module calculating unit are connected to the outputs of the first and second averaging blocks, respectively, and the third averaging unit output is connected to the first inputs

P multipliers, the output of the t-th (isi, n) coefficient of the block constant Ps1m ty1 is connected to the first input of the -th switch and the second input of the f -th multiplier, the output of which is connected to the first input (-th comparison block, the second input of which is connected to output of the module calculating module, output

The i-ro (fr2, nl) of the comparison unit is connected to the first input of the i-ro and the second input of the (-1) -th element AND, the output of the first comparison unit is connected to the first input of the first element AND and the second input of the first kollutator, the output of which is connected to the first input of the OR element, the output of the c-th comparison unit is connected to the second input (the n-lj-ro element AND, the output of the -th. (4-1, P-1) of the element AND is connected to the second input of the () -th switch, output which is connected to the (itl) -My input of the OR element, the output of which is the second information output of the device.

one

The invention relates to a definition; characteristics of narrowband random processes, designed for rapid assessment of the modulus and phase of the inter-period correlation coefficient of periodic signals during phase and amplitude fluctuations of the signal and can be used in measuring texHHKH, communication and automatic control systems.

The magnitude of the modulus of the correlation coefficient makes it possible to judge the width of the spectrum of a narrow-band random process, and the simultaneous measurement of the average phase shift over a known time interval characterizes the position of the center frequency of the spectrum on the frequency scale. In particular, it is important to estimate the position of the center frequency of the spectrum on the frequency scale in the correlators for automating the measurement process.

A device is known that calculates the correlation coefficient envelope and contains three input channels, each of which has a serially connected multiplying device, a low-pass filter and a time quantizer, as well as a generator, a phase-shifting circuit, a delay, and two polar correlator computing devices. l.

When calculating the envelope of the correlation coefficient, the device multiplies the incoming external signals by the signals from the generator. ra, the frequency of which should be approximately equal to the center frequency of the studied processes. The lack of an estimate of the position of the unknown center frequency spectrum of the incoming signals on the frequency scale is a disadvantage of this device.

The closest in technical essence is an average phase meter for running phases / L, containing a series-connected instantaneous phase meter, a delay unit, a subtraction unit, the second input of which is connected to the output of the instantaneous phase meter, a convolution unit and a trigon converter, and module, two multipliers, two averaging blocks and a phase calculating block, the first and second outputs of the trigonometric converter being connected respectively to the first inputs of the first and the second multipliers, the second inputs of which are interconnected through the unit and calculating unit connected to the input of the instantaneous value of the phase meter, the outputs of the first and second multipliers, respectively, first and second averaging units are connected to first and second inputs of the phase computation unit.

The device makes an estimate on the waveform, ha of the phase of the signal having an average

frequency 0o I for the selected time interval T, set in the delay unit. For radio-pulse periodic signals with phase and amplitude fluctuations, this estimate is an estimate of the average phase of the inter-period correlation coefficient 2.

A disadvantage of the known device is the lack of an estimate of the modulus of the correlation coefficient.

The purpose of the invention is to expand the functional capabilities of the device due to the additional evaluation of the module of the correlation coefficient of signals with the maximum use of the available equipment, as well as with a given estimation resolution.

This goal is achieved in that a correlation analysis device comprising a first module calculating unit, an instantaneous phase value calculating unit, a delay unit, a subtracting unit, a convolution calculating unit, a sine calculating unit, a cosine calculating unit, two multipliers, two averaging units, a phase calculation unit, the first and second inputs of which are connected to the outputs of the first and second averaging blocks, respectively, whose inputs are connected to the outputs of the first and second multipliers, respectively, the first inputs of which are connected The first and second inputs of the module are combined with the first and second inputs of the instantaneous phase value calculation unit and are respectively the first and second information inputs of the device, the output of the instantaneous phase value calculator is connected to the first input of the readout unit and the input the delay unit, the output of which is connected to the second input of the subtraction unit, the output of which is connected to the departure of the convolution calculation unit, the output whose stroke is connected to the inputs of the calculation unit with of the null and cosine calculator / outputs of which are connected to the second inputs of the first and second multipliers, the output of the phase calculating unit being the first information output of the device, the third averaging unit, the second module calculating unit and the divider whose output is the second information output of the device are entered , the output of the first unit of calculation of the module is connected to the input of the third averaging unit, the output of which is connected to the first input of the divider, the second input of which is connected to the output of the second unit and the calculation of the module, the first and second inputs of which are connected to the outputs of the first and second blocks, respectively, of the averaged and.

In recognition and adaptation systems, analysis is usually performed.

signals with predetermined properties; In particular, it is necessary to measure the frequency of signals with given values of the module of the correlation coefficient. For this, it is necessary to estimate the modulus of the correlation coefficient with a given discreteness, which is not carried out in the first version of the device.

 In the second embodiment, the device for correlation analysis, comprising: the first unit of the module calculating, the calculating unit of the instantaneous phase value, the delaying unit, the subtracting unit, the convolution calculating unit, the sine calculating unit, the cosine calculating unit, two multipliers, the averaging unit, a phase calculation unit, the first one; and the second inputs of which are connected to the outputs of the first and second averaging blocks, respectively, whose inputs are connected to the outputs of the first and second multipliers, respectively, the first inputs of which are connected to the output In the first module of the module, the first and second inputs of the module are combined respectively with the first and second inputs of the instant phase value calculator and are respectively the first and second 1information inputs of the device, the output of the instant phase value calculator is connected to the first input of the subtractor and the input of the delay block the output of which is connected to the second input of the subtraction unit, the output of which the cell is one with the input of the calculation unit of the convolution, the output of which is connected to the inputs of the sine calculation unit and the unit calculating cosine outputs are connected to second inputs of the first and second multipliers, wherein the output calculation unit. the phases is the first information on the device’s output, the switches are entered, the AND-1 of the AND elements, the OR element, the permanent memory block,

Q multipliers, q comparison units, the third averaging unit, the second module calculating unit, the output of the first module calculating unit are connected to the input of the third averaging unit, the first and second inputs of the second module calculating unit are connected to the outputs of the first and second averaging blocks, respectively, and the output of the third block the averaging is connected to the first inputs of the P multipliers, the output of the “-th ((r1, c)) coefficient of the fixed memory block is connected to the first input of the 4th switch and the second input of the -th multiplier, the output of which is connected to the first The input of the i-th comparison unit, the second input of which is connected to the output of the module’s calculation unit, output -) -th, nl) of the comparison unit is connected to the first input of the -th and second input of the (isi) -th element I, the output of the first comparison unit It is connected to the first input of the first element AND and the second input of the first switch, whose output is connected to the first input of the OR element, the output of the comparison block is connected to the second input of the {I-1) -th element AND, the output of the i-th , n-1) of the element I is connected to the second input (+1) of the switch, the output of which is connected to the (4 + 1) -th input ale ORT, the output of which is the second information output of the device. FIG. 1 shows the functional diagram of the device. The circuit (Fig. 1) contains the block I calculating the instantaneous phase value, the block 2 delay, the block 3 subtracting, the block 4 convolving, the block 5 calculating sine, the first block 6 calculating the module, the multiplier 7, the first and second blocks of averaging, block 9 calculating phase, second module 10, module averaging, third averaging block 11, divider 12 and cosine calculating block 13 (Figure 2) contains block 1 for calculating the instantaneous phase value, delay block 2, subtracting block 3, convolution block 4, calculating block 5 r sine, first 6 module calculating unit, multiplier 7, first and second block and 8 averaging, phase calculating unit 9, second modulo calculating unit 10, third averaging block 11, constant memory block .12, cosine calculating unit 13, comparison blocks 14, AND elements 15, switches 16, OR element 17 and multipliers 18. The device (fig; 1) works as follows. The instantaneous value block 1 determines the current phase of the input signal in each resolution interval. The readings are held for the repetition period in block 2 delays and are fed to block 3 subtraction. At the output of the subtraction unit, counts of the phase difference between the delayed and non-delayed signals are formed, which are converted to a single-digit interval with; using block 4 convolutions. From the convolution block, phase difference samples (QF) are fed to blocks 5 and 13, the outputs of which generate signals of the form sin 4 (f; and cos l (j;. These signals are sent to the first inputs of the multipliers 7, the second inputs of which receive the module counts of the input signal U ,, determined by modulus calculation unit 6 in the corresponding i-th resolution intervals, over the range. The resulting products U, sin.u (| and Uj cosiCf. are averaged in the corresponding averaging blocks 8 in which they are formed, NN sums and, - and, -siHianCi and 0 U ,, cosACf where N is the number of averaged samples. In block 9 it calculates c, the mean value of the phase by the formula (| avg.) In block 10, the module is calculated using the formula + Uj or an algorithm approximated to it. Block 11 averages the tmodule in 2 according to the algorithm M |, Z Oj and be performed similarly to block 8. At the output of divider 12, we obtain an estimate of the modulus of the coefficient of correlation of signals in accordance with formula I, ict i -) | u..l (rLCH, and; 5% L mg R 5: mT When implementing a device at a video frequency or In digital form, the signal to the device input must come in the form of the quadrature components A and Dg, received s for example, two phase detectors. In this case, the module 6 for calculating the module is similar to the block 10, and the block 1 is similar to the block 9 for calculating the phase. The device (Fig. 2) works as follows. Blocks 1-11 and 13 operate in the same way as described for the first variant. Module M from the output of the third block 11 of the averaging enters the n-kangshny scheme. In the j-th channel, the values in multiplier 18 are multiplied by a constant value Rj, coming from block 12. The result of the calculations is compared in comparison block 14 with the value Mj coming from block 10I at the output of the comparison block, a signal 1 is generated if M , Rj is MjiO and O, otherwise. The signal passes through the j-th element 15 and is a permitted signal for the j-th switch 16 to pass the value of Rj from block 12, if the second input of the element does not come from the (j-1) -ro channel. With a signal at the second input of the switch 16 at its output, the value of Rj is equal to 0. The outputs of all the switches are combined on the element OR 17, the output of which is the second information output of the device. Thus, the estimate of the modulus of the correlation coefficient of the input signals is obtained with the discreteness given in block 12. Thus, a new quality is obtained with a relatively small increase in the equipment, and therefore, weight, size and power consumption. In addition, the identity of the newly introduced units of calculation module

And averaging with the use of one-to-one | Memenie blocks substantially simplifies the engineering implementation of the invention. The application of the invention will allow the use of one device for solving the problem instead of a set of devices

Most of the hardware is Common, and many units may be identical. All this leads to a reduction in weight, size, power consumption and reduces the cost of the device; properties.

Claims (2)

A correlation analysis apparatus comprising a first module calculation unit, an instantaneous phase value calculation unit, a delay unit, a subtraction unit, a convolution calculation unit, a sine calculation unit, a cosine calculation unit, two multipliers, two averaging units, a phase calculation unit, the first and second inputs which are connected to the outputs of the first and second averaging units, the inputs of which are connected to the outputs of the first and second multipliers, the first inputs of which are connected to the output of the first calculation unit I am a module, the first and second inputs of which are combined respectively with the first and second inputs of the instantaneous phase value calculation unit and are respectively the first and second information inputs of the device, the output of the instant phase value calculation unit is connected to the first input of the calculation unit and the input of the delay unit, the output of which is connected with the second input of the subtraction unit, the output of which is connected to the input of the convolution calculation unit, the output of which is connected to the inputs of the sine calculation unit and the cosine calculation unit, outputs which are connected to the second inputs of the first and second multipliers, respectively, wherein the output of the phase calculation unit is the first information output of the device, characterized in that, in order to expand functionality by evaluating the module of the correlation coefficient, the third averaging unit, the second unit module calculation and a divider, the output of which is the second information output of the device, the output of the first module calculation unit is connected to the input of the third averaging unit, the output of which is connected ene divider to the first input, a second input coupled to an output of the second calculating unit block, first and second inputs are connected to outputs of the first and second averaging units. 2. A correlation analysis apparatus comprising a first module calculation unit, an instantaneous phase value calculation unit, a delay unit, a subtraction unit, a convolution calculation unit, a sine calculation unit, a cosine calculation unit, two multipliers, two averaging units, a phase calculation unit, the first and the second inputs of which are connected to the outputs of the first and second blocks ^ O, respectively. averaging, the inputs of which are connected to the outputs of the first and second multipliers respectively, the first 'inputs of which are connected to the output of the first unit of the module calculation, the first and second inputs of which are combined with the first and second inputs of the unit for calculating the instantaneous phase value and are respectively the first and second information the device inputs, the output of the instant phase value calculation unit is connected to the first input of the subtraction unit and the input of the delay unit, the output of which is connected to the second input of the subtraction unit anija whose output so1edinen to the input of calculating unit 10'38949 convolution, the output of which is connected to the inputs of the sine calculation unit and the cosine calculation unit, the outputs of which are connected to the second inputs of the first and second multipliers, respectively, and the output of the phase calculation unit is the first information output of the device, characterized in that, with In order to expand functionality by evaluating the module of the correlation coefficient with a given discreteness of the estimate, ή switches, C-1 AND elements, an OR element, a read-only memory block, P multipliers, h comparison blocks are introduced into it I, the third averaging block, the second module calculation block, the output of the first module calculation block is connected to the input of the third averaging block, the first and second inputs of the second module calculation block are connected to the outputs of the first and second averaging blocks, and the output of the third averaging block is connected to the first inputs P multipliers, the output of the f-th (<sl, n) coefficient of the constant memory block! connected to the first input of the j-ro switch and the second input of the i-th multiplier, the output of which is connected to the first input of the j-th block of comparison, the second input of which is connected to the output of the block __ module calculation, output <-th ((: 2.11-1) the comparison unit is connected to the first input of the ΐth and second input (jl) -ro of the And element, the output of the first comparison unit is connected to the first input of the first And element and the second input of the first switch, the output of which is connected to the first input of the OR element, the output of the ηth the comparison unit is connected to the second input (nl) -ro of the AND element, the output of the “-th. (1- 1, P-1) of the AND element is connected to the second input of the (1 + 1) -th switch, the output of which is connected to the (i + D-th input of the OR element, the output of which is the second information output of the device.