SU1191940A1 - Device for analysing information - Google Patents

Abstract

A DEVICE FOR ANALYSIS OF INFORMATION, containing the first subtractor, the first input connected to one of the input buses directly, and the second input through the first integrator, the second subtractor, the first full-wave rectifier connected by the output to the first input of the second subtractor and the input to the output of the first subtractor, the third a subtractor connected by the first input to the output of the first integrator and the output to the input of the second full-wave rectifier, the fourth subtractor, the fifth subtractors, the first one-third octave filters, Connected outputs with the first inputs of the fifth subtractors, sixth subtractors, an OR element connected with the outputs to one of the output buses, and control buses connected to the second inputs of the second, third subtractors and fifth subtractors and to the first inputs of the fourth subtractors and generic subtractors, characterized in that, in order to improve the accuracy of identifying pieces of information, the first, second and third notch filters, the seventh, eighth, ninth and tenth subtracters, the eleventh and two The eleventh subtractors, the second, third, fourth and fifth integrators, the first, second, third, fourth and fifth detectors, the sixth and seventh detectors, the third full-wave rectifier, the first and second full-wave rectifiers, the first and second quadratures, the switch, the second one-third octave filters, first and second voltage dividing units, and first and second multiplying units. the OR element is connected by inputs through the first detector to the output of the eighth subtractor, through the third detector to the output of the ninth subtractor, through the fifth detector to the output of the tenth subtractor and through the sixth and seventh detectors to the outputs of the eleventh and twelfth subtractors, respectively. the first of which are connected by the first input through the first full-wave rectifiers to the output of the fifth subtractors, the second input is connected to the interconnected corresponding output bus, the output of the corresponding third-octave filter and the input of the corresponding second quadrant connected to the output of one of the output buses and with the first input of the corresponding two-second subtractor connected by the second input through one of the second two-sexes (L of periodical rectifiers to the output of the corresponding sixth A reader connected to the corresponding output bus by the second input directly, and to another of the output lines and to the output of the corresponding one of the first three-octave filters through one of the first quadrants, while the first subtractor is connected to the switchable contacts of the switch with the output directly and through the first voltage dividing unit one of the inputs connected to the output of the second dividing unit, for example, CO 4, is connected to one input with the first input of the fourth subtractor and the other input with connected Between itself the corresponding output bus, the second input of the fourth subtractor and the output of the first multiplication unit connected via the third integrator to the corresponding output bus and to the first input of the second subtractor connected by output through the second detector to the first input of the seventh subtractor connected by the second input to the output of the third full-wave quad and to the corresponding output bus directly and through the sequentially connected fifth integrator and second

Description

the multiplier unit connected to the interconnected output bus and the first input of the tenth subtractor, the second input of which through the fourth detector is connected to the output of the fourth subtractor, the seventh subtractor is connected by the first input to another of the input buses directly, the second input through the second integrator and the output to to the input of the first notch filter, the third notch filter is connected by an output to the inputs of the second one-third octave filter, the third two-phase rectifier and the fourth integrator, the output of which is th connected to sootvetstvuyushaya she output bus and to the first input of the eighth subtractor, the second input of which is connected to the output of the second full-wave rectifier and pereklyuchayush, s switch contact is coupled to first inputs of third octave filters.

one

The invention relates to instrumentation, namely, devices for analyzing information.

The purpose of the invention is to improve the accuracy of identification of information sites.

The drawing shows one of the possible variants of the device for analyzing information.

The device for analyzing information contains the first subtractor 1, the first input connected to one of the input buses 2 directly, and the second input through the first integrator 3, the first full-wave rectifier 4 connected by the output to the first input of the second subtractor 5 and the input to the output of the first subtractor 1 , the third subtractor 6 connected by the first input to the output of the first integrator 3 and the output to the input of the second full-wave rectifier 7, the fourth subtractor 8, the first one-third octave filters 9 connected by the outputs with the first The signals of the fifth subtractors 10, the sixth subtractors 11, the element OR 12, connected by an output to one of the output buses 13, and control buses 14, connected to the second inputs of the second, third subtractors 5 and 6, the fifth subtractors 10, and to the first inputs of the fourth subtractor 8 and sixth subtractors 11.

In addition, the device for analyzing information contains first, second and third notch filters 15, 16 and 17 sequentially connected, seventh, eighth, ninth and tenth subtracters 18-21, eleventh and twelfth subtracters 22 and 23, second, third, fourth and fifth integrator 24-27, first, second, third, fourth and fifth detectors 28-32, sixth and seventh detectors 33 and 34, third full-wave rectifier 35, first and second full-wave rectifiers 36 and 37, first and second quadrs 38 and 39, switch 40, second one-third octave filter s 41, the first and second blocks 42 and 43 of the voltage division, the first and second blocks 44 and 45 multiply, and the element OR 12 is connected by inputs through the first detector 28 to the output of the eighth subtractor 19, through the third detector 30 to the output of the ninth subtractor 20 , through the fifth detector 32 to the output of the tenth subtractor 21 and through the sixth and seventh detectors 33 and 34 to the outputs of the eleventh and twelfth subtractors 22 and 23, respectively, the first of which are connected to the first input through the first full-wave rectifiers 36 to the output of the fifth subtractors 10, and

the second input is connected to the interconnected corresponding of the output tires 13, the output of the corresponding one of the second one-third octave filters 41 and the input of the corresponding one of the second quadrants 39 connected by the output with one of the output

tires 13 and with the first input of the corresponding twelfth subtractor 23 connected by the second input through one of the second full-wave rectifiers 37 to the output of the corresponding sixth subtractor 11,

connected to the corresponding output bus 13 by the second input directly, and to the other of the output tires 13 and to the output of the corresponding one-third three-octave filter 9 through one of the first quadrants 38, while the first subtractor 1 is connected by output to the switchable contacts of the switch 40 directly and through the first unit 42 voltage division, one of the inputs connected to the output of the second voltage dividing unit 43, connected by one input to the first input of the fourth

subtractor 8 and another input with interconnected corresponding output bus 13, the second input of the fourth subtractor 8 and the output of the first multiplication unit 42 connected via the third integrator 25 to the corresponding output

bus 13 and to the first input of the second subtractor 5 connected by the output through the second detector 29 to the first input of the ninth subtractor 20 connected by the second input to the output of the third full-wave

rectifier 35 and to the corresponding output bus 13 directly and via serially connected fifth integrator 27 and second multiplication unit 45 to interconnected corresponding output bus 13 and to the first input of the tenth subtractor 21, the second input of which through the fourth detector 31 is connected to the output the fourth subtractor 8, as well as the seventh subtractor 18 is connected by the first input to another of the input buses 13 directly, the second input through the second integrator 24 and the output to the input of the first notch filter 15, the third reject The filter 17 is connected by an output to the inputs of the second one-third octave filters 41, the third full-wave rectifier and the fourth integrator 26, the output of which is connected to the corresponding output bus 13 and to the first input of the eighth subtractor 19, the second input of which is connected to the output of the second full-wave rectifier 7, and the switching contact of the switch 40 is connected to the inputs of the first one-third octave filters 9.

The operation of the device is based on the determination of the noise and interference signal, on the calculation of the current statistical estimates of the characteristics of this signal in the passbands of the second one-third octave filters 41, whose passbands correspond to the pass-bands of the first one-third octaves filters 9.

The noise signal is determined by the fact that along the aircraft bead radio channel, along with the transmission of measurement information, the reference calibration sine wave signal of a stationary amplitude and frequency is transmitted through a special channel. The interference signal is additively multiplicatively superimposed on the information and calibration signals as it passes through the radio path. The interference signal is extracted by three notch filters 15-17, the first of which is fed the centered value of the calibration signal after passing through the radio path to one of the input buses 2, to the other of which the data of the measuring signal is received code signals are provided that correspond to the a priori value of the calculated statistical estimates of the probability characteristics of the analyzed signal. From the output layer 2, the signal of the analyzed information simultaneously arrives at one of the input buses 13, at the first input of the subtractor 1 and at the input of the integrator 3. At the output of the integrator 3, a signal is generated that is proportional to the current value of the average, which simultaneously goes to one of the output tires 13 and The first input of the subtractor 6. The output of the subtractor 1 generates a signal proportional to the centered value of the signal, which is fed to the inputs of the full-wave rectifier 4, to the first input of the voltage dividing unit 42 and to the switch 40.

Simultaneously from the input bus 2, the calibration signal is fed to the input of the subtractor 18 to the input of the integrator 24, the output of which forms a signal proportional to the average value of this signal. From the output of the integrator 24, the signal is fed to the second input of the subtractor 18, where a signal is generated that is proportional to the centered value of the calibration signal to the input of the first notch filter 15.

The notch filter 15 suppresses the calibration signal, extracting all noise, harmonics and harmonics from it,

5 signal when passing through the radio path of information transfer. From the input of the notch filter 15, the signal is fed to the input of the notch filter 16, connected in series with the notch filter 17.

Q Series-connected notch filters 16 and 17, suppressing the second and third harmonics of the calibration signal, extract the signal of the radio transmission path of information. From the output of the notch filter 17, the signal goes to the inputs of the integrator 26, two5 half-period rectifiers 35 and the second one-third octave filters 41.

At the output of the integrator 26, a signal is generated that is proportional to the average signal, which is fed to the input of the subtractor 19 and to one of the output buses 13.

0 At the output of the full-wave rectifier 4, a signal is generated that is proportional to the current value of the amplitude of the signal, which is simultaneously fed to the subtractor 19, to the input of the integrator 25 and to one of the output tons 13.

five

In subtractor 6, the a priori value of the signal from the first control bus 14 to the subtractor 6 is subtracted from the signal. The signal from the output of the subtractor 6 through the full-wave rectifier 7 is fed to the input of the subtractor 19, in which the signal proportional to the modulus of the difference subtracts the signal proportional to the average value of the signal.

If the difference modulus is greater, then from the output of the subtractor 19 through the detector 28 a positive signal is fed to the input of the element OR 12.

In the subtractor. 5 from a signal proportional to the current amplitude value,

0 subtracts the prior value of the amplitude of the signal from one of the control buses. 14 of the buses to the subtractor 5. A signal proportional to the difference in amplitudes from the output of the subtractor 5 through the detector 29 enters the subtractor 20.

5 At the output of the full-wave rectifier 35, a signal is formed that is proportional to the current value of the amplitude of the noise signal fed to the input of the subtractor 20, to the input of the integrator 27 and to the corresponding output bus 13.

In subtractor 20, a signal proportional to the amplitude of the noise signal is subtracted from a signal proportional to the difference in amplitudes. If the difference modulus is greater, then from the output of the subtractor 20 a positive signal through the detector 30 enters the input of the element OR 12. From the output of the integrator 25, the signal enters the input of the first multiplication unit 44, the output of which produces a signal proportional to the standard deviation of the signal.

From the output of the integrator 27, the signal is fed to the input of the second multiplication unit 45, at the output of which a signal is generated that is proportional to the standard deviation of the noise signal.

The signal proportional to the current value of the standard deviation of the signal from the output of multiplication unit 44 is fed to the output bus 13, to one input of the voltage dividing unit 43 and subtractor 8, to the other inputs of which from the corresponding control bus 14 comes the a priori value of the root-mean-square value of the signal being analyzed.

From the output of the subtractor 8, the signal through the detector 31 is fed to the input of the subtractor 21. The signal from the output of the multiplier 45 is fed to one of the output buses 13 and to the input of the subtractor 21, in which the signal proportional to the average is subtracted from the signal proportional to the center difference of the average values of the signal the value of the noise signal.

If the module of the centered difference is larger, then from the output of the subtractor 21 a positive signal through the detector 32 is fed to the input of the element OR 12.

When processing the stationary data of the measuring signal, the switch 40 is set to the appropriate position and the signal data is fed to the inputs of the first one-third octave filters 9 from the output of the subtractor 1.

In the second voltage dividing unit 43, the current value of the ratio of the average signal value to the a priori value is calculated, from the output of which the signal is fed to the input of the voltage dividing unit 42.

When processing the non-stationary data of the measuring signal, the switch 40 is set to a different position and the transformed data of the signal from the output of the voltage dividing unit 42 is fed to the inputs of the first three-octave filters 9.

From the output of the first one-third octave filters 9, proportional to the current value of the amplitude-frequency spectrum, go to the corresponding output buses 13, to the inputs of the first quadrants 38 and to the inputs of the first subtractors 10, to the other inputs of which from the corresponding control buses 14 arrive a priori values of the analyzed signal in the pass bands of the third-octave filters 9. At the output of the first quadrants 38, a signal is generated that is proportional to the spectral power density, which is fed to the corresponding tires 13 and in rows of second subtracters 11, other inputs of which with the actuating Shin sootvetstvuyushaya 14 receives a priori values of the analyzed signal in the passband 0 fil third octave trov 9.

From the outputs of the first subtractors 10, the first full-wave rectifiers 36 receive signals to the inputs of the third subtractors 22.

5 From the outputs of the second subtractors 11 through the second full-wave rectifiers 37 signals are fed to the inputs of the fourth subtractors 23. Signals proportional to the current value of the amplitude-frequency spectrum of the noise signal from the output of the second one-third octave filters 41, the bandwidth of which is equal to the bandwidth of the first one-third octave filters 9, arrive at the corresponding tires 13, at the other inputs of the third subtractors 22 and at the inputs of the second

5 quadrants 39.

The signals, proportional to the current value of the spectral power density, from the outputs of the quadrants 39 are fed to the corresponding tires 13 and to other inputs

0 fourth subtractors 23.

From the outputs of the subtractors 22, the signals through the first detectors 33 arrive at the corresponding inputs of the element OR 12.

From the outputs of the subtractors 23, the difference signals go through the second detectors 34

to the corresponding inputs of the element OR 12. The current difference modules when comparing them in the subtractors 22 and 23, respectively, with the current values in the passbands of the third-octave filters 9 and 41, take into account the multiplicative nature of the noise signal, whose frequency and spectral components can increase or decrease frequency and spectral components of the measuring signal. If there are no signals at the input of the control units 14 proportional to the calculated values of the probability characteristics, then the traditional method of processing and analysis is preserved, i.e. the registration of the measurement information and the results of processing is carried out throughout the measurement

0, the ratio of the current probabilistic values to their calculated values allows for the prompt determination of the factor of safety, reliability of control and operation of the devices under test.

5 When at least one positive signal is received at the inputs of the element OR 12, a positive signal is generated at its output, which is fed to one of

Claims (1)

DEVICE FOR ANALYSIS OF INFORMATION, containing the first subtractor, the first input connected directly to one of the input buses, and the second input through the first integrator, the second subtractor, the first half-wave rectifier connected by the output to the first input of the second subtractor and the input to the output of the first subtractor, the third subtractor connected by the first input to the output of the first integrator and the output to the input of the second half-wave rectifier, the fourth subtractor, fifth subtractors, the first one-third octave filters, the outputs with the first inputs of the fifth subtractors, sixth subtractors, an OR element connected by the outputs to one of the output buses, and control buses connected to the second inputs of the second, third subtractors and fifth subtractors and to the first inputs of the fourth subtractor and sixth subtractors, characterized in that, in order to improve the accuracy of identifying sections of information, the first, second and third notch filters, the seventh, eighth, ninth and tenth subtractors, the eleventh and twelfth calculators are introduced in series integrators, second, third, fourth and fifth integrators, first, second, third, fourth and fifth detectors, sixth and seventh detectors, third half-wave rectifier, first and second half-wave rectifiers, first and second quadrants, switch, second third-octave filters, first and third the second voltage dividing blocks and the first and second multiplication blocks, and the OR element is connected by inputs through the first detector to the output of the eighth subtractor, through the third detector to the output of the ninth subtractor, through the fifth detector to the output d of the fifth subtractor and through the sixth and seventh detectors to the outputs of the eleventh and twelfth subtracters, respectively, the first of which are connected by the first input through the first half-wave rectifiers to the output of the fifth subtractors, the second input is connected to the interconnected output bus, the output of the second third-octave filter and the input of the corresponding of the second quadrators, connected by the output to one of the output buses and with the first input of the corresponding two-nadtsyh subtractor, connected by a second input through one of the second half-wave rectifiers to the output of the corresponding sixth subtractor, connected directly to the corresponding output bus by the second input, and to the output of the corresponding buses from the first one-third octave filters through one of the first quadrants, the first subtractor is connected by the output to the switch contacts of the switch directly and through the first voltage division unit, one of the inputs connected to the output of the second voltage division unit a connection connected by one input to the first input of the fourth subtractor and another input connected to each other by the corresponding output bus, the second input of the fourth subtractor and the output of the first multiplication unit, connected through the third integrator to the corresponding output bus and to the first input of the second subtractor, connected by the output through the second detector to the first input of the seventh subtractor, connected by the second input to the output of the third half-wave rectifier and to the corresponding output bus directly and through the fifth integrator and WTO connected in series SU „„ ° 1191940 swarm multiplication unit to the corresponding corresponding output bus and the first input of the tenth subtractor, the second input of which through the fourth detector is connected to the output of the fourth subtractor, the seventh subtractor is connected by the first input to the other of the input buses directly, the second input through the second integrator and an output to the input of the first notch filter, the third notch filter is connected to the inputs of the second one-third octave filters, the third half-wave rectifier and the fourth integrator, you the stroke of which is connected to the corresponding output bus and to the first input of the eighth subtracter, the second input of which is connected to the output of the second half-wave rectifier, and the switching contact of the switch is connected to the inputs of the first one-third octave filters.