RU2785898C1 - Automated device for control of the mutual influence of signals - Google Patents

Abstract

FIELD: instrumentation.

SUBSTANCE: invention relates to the field of instrumentation and can be used to create systems for automatic control of the mutual influence of signals in radio channels and in wired telecommunication channels. The effect is achieved by the fact that the claimed solution provides for two objects of control, five registers, a decoder, two amplifiers, a counter, read-only memory (ROM), a delay element, a pulse generator, an analog-to-digital converter (ADC), a trigger, three OR elements , AND element, "Reset" and "Start" buttons, control result output block, comparator, signal mutual influence calculation block, two calculation blocks, two amplitude detectors, two frequency detectors, two phase detectors, five adders, eight quadrators, seven subtractors devices, seven module devices, two square root devices, divider, register, nine AND elements.

EFFECT: increasing the reliability of monitoring the mutual influence of signals in the communication lines of data transmission channels.

1 cl, 6 dwg

Description

The invention relates to instrumentation and can be used to create systems for automatic control of the mutual influence of signals in radio channels and in wired telecommunication channels.

A device for monitoring electronic products is known (Patent RU 2071107 dated 27.12.96, class G05B 23/02), using the measurement of a generalized performance indicator that determines the compliance of the technical condition of the controlled product with its intended purpose - the transmission of information with a given or lesser probability of errors .

However, the prototype did not take into account the fact when signal transmitters are operated that have their technical condition in line with their intended purpose, the transmission of information with a given or lower probability of errors, which transmit modulated signals to radio channels or wired telecommunication channels, but do not take into account the mutual influence of the transmitted signals in the environment. distribution. Studies have shown that signals with frequency modulation (FM), phase modulation (PM), amplitude modulation (AM), quadrature multilevel, multiphase modulation (QAM) even when using different carrier frequencies, phases and amplitudes can have mutual influence on each other , leading to the loss of transmitted modulating information (Scientific journal of the Higher Attestation Commission of the Russian Federation. Modern science-intensive technologies. No. 6 (June) 2020, pp. 31-37. Section Technical sciences. Publishing house and editorial office: Publishing House "Academy of Natural Sciences" Article "Model of information security control systems "author Vlasov V.I., Vlasov S.V.).

In accordance with the theoretical studies carried out, an analytical model is defined for determining the “distances” ƒ(x ₀₁ , y ₀₁ ) between the signals S1(t) and S2(t) in a multidimensional metric space:

where:

r - oscillation amplitude; ω - cyclic frequency; ϕ - initial phase of the signal.

The purpose of the invention: improving the reliability of the control of the mutual influence of signals in the communication lines of data transmission channels based on multidimensional metric spaces.

In FIG. 1 shows a block diagram of the proposed device; in fig. 2 shows a functional diagram of the block for calculating the magnitude of the mutual influence of signals 3; in fig. 3 shows a diagram of the control unit 4; in fig. 4 shows a diagram of the calculation unit 11; in fig. 5 shows a diagram of the calculation block 12; in fig. 6 shows a block diagram of the device operation algorithm.

The automated device for monitoring the mutual influence of signals contains a control object 1, a control object 2, a block for calculating the magnitude of the mutual influence of signals 3, a control unit 4, an analog-to-digital converter (ADC) 5, an AND element 6, an AND element 7, a register 8, a comparator 9, control result output block 10. As an object of control, both the transmitter of modulated signals and the transmitter modulator can be used.

The block for calculating the magnitude of the mutual influence of signals 3 contains a calculation block 11, a calculation block 12, amplitude detectors 13, 16, frequency detectors 14,17, phase detectors 15, 18, adders 19, 27, 34, 48, 49, quads 20, 22, 26, 33, 42, 43, 44, 45, subtractors 21, 25,29, 30, 32, 35, 39, module devices 23, 24, 28, 31, 40, 46, 50 A1, IPC G06G 7/12), multipliers 36, 37, 38, square root extractors 41, 51 (Invention certificate SU 620986 A1 IPC G06G 7/20), divider 47.

The calculation unit 11 contains a sinω ₁ 52 calculation device, a cos ω ₁ 53 calculation device (Invention Certificate SU 1494002 A2), a sin ϕ1 54 calculation device, a cos ϕ ₁ 55 calculation device, multipliers 56, 57, 58, 59, 60. Calculation unit 11 has contacts 1, 2, 3, 4, 5, 6, 7. Moreover, the output of the amplitude detector 13 through contact 2 of the calculation unit 11 is connected in parallel to contact 1 and the second inputs of the multipliers 57, 59, 60 of the calculation unit 11. The output of the frequency detector 14 through contact 3 of the calculation unit 11 is connected in parallel to the inputs of the calculation device sinω ₁ 52 and the calculation device cosω ₁ 53. The output of the phase detector 15 is connected through contact 4 of the calculation unit 11 in parallel to the input of the calculation device sinϕ ₁ 54 and the calculation device cosϕ ₁ 55. The output of the calculation device sinω ₁ 52 is connected in parallel to the first inputs of the multipliers 56 and 58. The output of the cosω ₁ 53 calculator is connected to the first input of the multiplier 60. The output of the device in calculation sinϕ ₁ 54 is connected to the first input of the multiplier 58. The output of the multiplier 58 is connected to the first input of the multiplier 59. The output of the calculation device cosϕ ₁ 55 is connected to the second input of the multiplier 56. The output of the multiplier 56 is connected to the first input of the multiplier 57. The output of the multiplier 57 is connected to pin 7 calculation unit 11. The output of the multiplier 59 is connected to pin 6 of the calculation unit 11. The output of the multiplier 60 is connected to pin 5 of the calculation unit 11.

The calculation unit 12 contains a calculation device sinω ₂ 61, a calculation device cos ω ₂ 62, a calculation device sin ϕ ₂ 63, a calculation device cos ϕ ₂ 64, multipliers 65, 66, 67, 68, 69. The calculation unit 12 has contacts 1, 2, 3, 4, 5, 6, 7, 8. Moreover, the output of the amplitude detector 16 is connected to the first input of the adder 19 and through contact 1 of the calculation unit 12 is connected to the second inputs of the multipliers 66, 68, 69 of the calculation unit 12. The output of the frequency detector 17 through contact 2 of the block calculation 12 is connected in parallel to the inputs of the calculation device sinω ₂ 61 and the calculation device cos ω ₂ 62. The output of the phase detector 18 is connected through contact 3 of the calculation unit 12 in parallel to the input of the calculation device sinϕ ₂ 63 and the calculation device cosϕ ₂ 64. The output of the calculation device sinω ₂ 61 connected in parallel to the first inputs of the multipliers 65 and 67. The output of the calculation device cosω ₂ 62 is connected to the first input of the multiplier 69. The output of the calculation device sinϕ ₂ 63 is connected to watts to the other input of the multiplier 67. The output of the calculation device cosϕ ₂ 64 is connected to the second input of the multiplier 65. The output of the multiplier 66 is connected to pin 6 of the calculation unit 12. The output of the multiplier 68 is connected in parallel to the contacts 5, 8 of the calculation unit 12. The output of the multiplier 69 is connected in parallel to the contacts 4, 7 of the calculation block 12. Contact 1 of the block for calculating the magnitude of the mutual influence of signals 3 is connected in parallel to the inputs of the amplitude detector 13, frequency detector 14, phase detector 15, and contact 2 of the block for calculating the magnitude of the mutual influence of signals 3 is connected in parallel to the amplitude detector 16, frequency detector 17, phase detector 18.

The first input of the adder 19 is connected to the output of the amplitude detector 16, and to pin 1 of the calculation unit 12. The second input of the adder 19 is connected to the contact 1 of the calculation unit 11, and the output of the adder 19 is connected to the input of the quadrator 20, the output of which is connected to the first input of the subtractor 39 , to the second input of which the output of the module device 28 is connected, the input of which is connected to the output of the square root extractor 41, the input of which is connected in parallel to the output of the adder 34 and to the first input of the divider 47. The output of the subtractor 39 is connected to the input of the quadrator 45, the output of which is parallel connected to the second inputs of multipliers 36, 37, 38.

Contact 5 of the calculation unit 11 is connected in parallel to the first input of the subtractor 21 and to the input of the module 23. Contact 4 of the calculation unit 12 is connected to the second input of the subtractor 21. The output of the subtractor 21 is connected to the input of the quadrator 22, the output of which is connected to the first input of the adder 27 The output of the module device 23 is connected to the first input of the subtractor 29, the second input of which is connected to the output of the module device 46, and the output of the subtractor 29 is connected to the first input of the multiplier 36.

Contact 6 of the calculation unit 11 is connected in parallel to the first input of the subtractor 25 and to the input of the module device 24, the output of which is connected to the first input of the subtractor 30, the output of which is connected to the first input of the multiplier 37.

Contact 7 of the calculation unit 11 is connected in parallel to the first input of the subtractor 32 and to the input of the device module 31, the output of which is connected to the first input of the subtractor 35.

Contact 5 of the calculation unit 12 is connected to the second input of the subtractor 25, the output of which is connected to the quadrator 26, the output of which is connected to the second input of the adder 27, the output of which is connected to the first input of the adder 34, to the second input of which the output of the quadrator 33 is connected, to the input of which the output of the subtractor 32 is connected.

Contact 6 of the calculation unit 12 is connected in parallel to the second input of the subtractor 32 and to the input of the device module 40, the output of which is connected to the second input of the subtractor 35, the output of which is connected to the first input of the multiplier 38.

Contact 7 of the calculation unit 12 is connected to the input of the device module 46.

Contact 8 of the calculation unit 12 is connected to the input of the device of the module 50, and the output of the device of the module 50 is connected to the second input of the subtractor 30.

The output of the multiplier 36 is connected in series through the quadrator 42 to the first input of the adder 48, to the second input of which the output of the multiplier 37 is connected in series through the quadrator 43. The output of the adder 48 is connected to the first input of the adder 49, to the second input of which the output of the multiplier 38 is connected in series through the quadrator 44.

The output of the adder 49 is connected to the second input of the divider 47, and the output of the divider 47 is connected to the input of the square root extractor 51, the output of which, through contact 3 of the block for calculating the magnitude of the mutual influence of signals 3, is connected to the input of an analog-to-digital converter (ADC) 5, the output of which is connected in parallel to the first inputs of elements AND 6, AND 7. Contact 6 of control unit 4 is connected to the second input of element AND 6, and contact 7 of control unit 4 is connected to the second input of element AND 7. The output of element AND 6 is connected to the first input of register 8, the output which is connected to the second input of the comparator 9, to the first input of which the output of the AND element 7 is connected. Three outputs of the comparator 9 are connected to the block of outputs of the control results 10, and the third output of the comparator 9 is also connected in parallel to the second input of the register 8 and contact 5 of the control unit 4.

The start button 95 is connected to the input of the element OR 93, the output of which is connected to the setting input of the trigger 92, the direct output of which is connected to the first input of the element AND 90, to the second input of which the pulse generator 89 is connected. The output of the element And 90 is connected in parallel to the inputs of the element delay 87 and counter 88. The output of the delay element 87 is connected in parallel to the input of the amplifier 85 and to the control input of read-only memory (ROM) 86, to the information inputs of which the outputs of the counter 88 are connected in parallel and these outputs of the counter 88 are connected in parallel to the inputs of the decoder 74. Outputs ROM 86 is connected in parallel to the inputs of the registers 70, 72, 77, 79, 83. The output of the amplifier 85 is connected in parallel to the second inputs of the AND elements 71, 73, 78, 82, 84.

The output of register 70 is connected to pin 1 of control unit 4. The output of register 72 is connected to pin 2 of control unit 4. The output of register 77 is connected to the input of delay element 76, the output of which is connected in parallel to pin 3 of control unit 4 and to the output of element AND 80. Output register 79 is connected in parallel to contact 4 of control unit 4 and to the output of element AND 81. The output of register 83 is connected in parallel to the second inputs of elements AND 80 and 81, the first inputs of which are connected in parallel to the output of element OR 75, contact 7 of control unit 4 and reset inputs registers 77 and 79.

The first output of the decoder 74 is connected to the first input of the AND element 71. The second output of the decoder 74 is connected to the first input of the AND element 73, the third output of the decoder 74 is connected to the first input of the AND element 78, the fourth output of the decoder 74 is connected in parallel to the first input of the AND element 82 and to contact 6 of the control unit 4. From the 5th to the nth outputs of the decoder 74 are connected in parallel to the inputs of the OR element 75, and the nth output of the decoder 74 is connected in parallel to the reset inputs of the registers 70, 72.

Contact 5 of the control unit 4 is connected to the first input of the OR element 94, to the second input of which the "Reset" button 96 is connected, and the output of the OR element 94 is connected in parallel to the reset input of the trigger 92 and to the input of the amplifier 91, the output of which is connected in parallel to the reset inputs of all registers and counter 88.

Contact 1 of control unit 4 is connected to the second input of control object 1, and contact 3 of control unit 4 is connected to the second input of control object 2.

Contact 2 of control unit 4 is connected to the first input of control object 1, and contact 4 of control unit 4 is connected to the first input of control object 2.

The device works as follows.

Before starting operation, the device is reset by applying the “Reset” signal from the button 96 through the OR element 94 to the reset input of the trigger 92 and through the amplifier 91 to the reset inputs of all registers and counter 88. In the initial state, the contents of register 8, registers 70, 72, 77, 79, 83 of the control unit 4 is zero, the trigger 92 and the counter 88 are reset, and the AND element 90 is closed for the passage of pulses from the pulse generator 89. Also, before starting work, the code of the carrier frequency of the control object 1 is sequentially entered into the permanent memory 86, code the carrier frequency of the control object 2, the stimulus code of the generated signal from the QAM-object of control 1, the stimulus code of the generated signal from the QAM-object of control 2, and these stimulus codes must correspond to the signals of the canstellation diagrams of the control object 1 and control object 2, which have the minimum values of the amplitude difference and phases of the generated modulated signals at the outputs of control objects 1 and 2. These values are entered by the operator based on the analysis of the code words of the same canstellation diagrams installed in the control object of QAM-objects of control 1 and 2. Next, the stimulus codes of all symbols of the canstellation diagrams installed in the control objects 1 and 2 are sequentially entered into the permanent memory 86.

The automatic control cycle begins with the “Start” signal from the button 95, which, having passed through the OR element 93 to the installation input of the trigger 92, provides the last signal equal to a logical unit at the direct output, which opens the AND element 90 for the passage of pulses from the pulse generator 89 to the input of the delay element 87 and the counting input of the counter 88.

Having arrived at the counting input of the counter 88, the first pulse from the generator 89 changes the contents of this counter by one, that is, in this case, it generates the address code of the first word of the program for setting the parameters of control objects 1 and 2 at the output of the counter 88. The next address code comes from the output of the counter 88 to the control inputs of the ROM 86 and in parallel to the inputs of the decoder 74. After the time required to complete the transients in the counter 88, the first pulse from the pulse generator 89 through the delay element 87 is fed to the input of the ROM 86 as a "read" signal, and to the input of the amplifier 85 as a sync pulse. On the "read" signal, the ROM 86 reads the words of the control program at the frequency of the pulse generator 89. In this case, the contents of the counter 88 changes every time it receives pulses from the pulse generator 89 at its counting input. In the permanent memory 86, before starting work, the codes of the values of the carrier frequencies of the first control object 1, the second control object 2, the code of the minimum phase difference of two possible symbols of the QAM canstellation diagram, the code of the minimum amplitude difference of two possible symbols of the QAM canstellation diagram, and the codes of all symbols of the QAM canstellation diagram (Lagutenko O.I. Modern modems. - M .: Eco-Trends, 2002).

From the output of the read-only memory device 86, the command codes are fed in parallel to the inputs of the registers 70, 72, 77, 79, 83. When the code of the first counting pulse from the output of the counter 88 arrives at the input of the decoder 74, a logical unit is formed at the first output of the decoder 74, which is fed to the first input of the element And 71, the second input of which receives a signal from the output of the amplifier 85, thereby allowing the recording of the code of the carrier frequency of the control object 1 into the register 70. When the code of the second counting pulse from the output of the counter 88 is received at the input of the decoder 74, at the second output of the decoder 74, a logical unit is formed, which is fed to the first input of the AND element 73, the second input of which receives a signal from the output of the amplifier 85, thereby allowing the recording of the carrier frequency code of the control object 2 into the register 72. From the outputs of the registers 70 and 72, the codes of the carrier frequencies through, respectively contacts 1, 2 of the control unit 4 are fed to the first installation inputs of control objects 1 and 2, respectively. When the code of the third counting pulse from the output of the counter 88 is received at the input of the decoder 74, a logical unit is formed at the third output of the decoder 74, which is fed to the first input of the AND element 78, the second input of which receives a signal from the output of the amplifier 85, thereby allowing writing to the register 77 stimulus code, which corresponds to the setting of the control object 1 to issue a signal at its output with the specified values of the amplitude and phase of the previously set carrier frequency. When the code of the fourth counting pulse from the output of the counter 88 arrives at the input of the decoder 74, a logical unit is formed at the fourth output of the decoder 74, which is fed to the first input of the AND element 82, the second input of which receives a signal from the output of the amplifier 85, thereby allowing writing to the register 79 stimulus code, which corresponds to the setting of the control object 2 to issue a signal at its output with the specified values of the amplitude and phase of the previously set carrier frequency, and the values of the stimulus code entering the input of the control object 2 correspond to the minimum values of the phase difference and amplitude of the canstellation diagram between the phase values and the amplitude of the control object 1 and the control object 2. From the output of the register 77 through the delay element 76, which performs a time delay between pulses of the pulse generator 89, the stimulus code through contact 3 of the control unit 4 enters the first input of the control object 1, which at its output gives set carrier signal and amplitude and phase values of the modulated signal in accordance with the canstellation diagram. Delay element 76 delays the arrival of the stimulus code at the first input of the control object 1 by the time interval between the pulses of the generator 89 to ensure the simultaneous receipt of stimulus codes at the second inputs of the control objects 1 and 2. From the output of the control object 1, the modulated QAM signal arrives through contact 1 of the block calculating the magnitude of the mutual influence of signals 3 in parallel to the inputs of the amplitude detector 13, frequency detector 14, phase detector 15. From the output of the control object 2, the modulated QAM signal enters through contact 2 of the block for calculating the magnitude of the mutual influence of signals 3 in parallel to the inputs of the amplitude detector 16, the frequency detector 17, phase detector 18. From the output of the frequency detector 14, the amplitude of the detected signal, corresponding to the carrier frequency of the test object 1, through contact 3 of the calculation unit 11, is fed in parallel to the input of the sinω1 52 calculation device and the cosω ₁ 53 calculation device. From the output of the sinω ₁ 52 calculation device, the floor the calculated value of sinω ₁ is fed in parallel to the first inputs of the multipliers 56 and 58. From the output of the calculation device cosω ₁ 53, the obtained value of cosω ₁ is fed to the first input of the multiplier 60. From the output of the phase detector 15 through contact 4 of the calculation unit 11, the amplitude value of the signal corresponding to the phase of the modulated The QAM signal is fed in parallel to the inputs of the calculation device sinϕ ₁ 54 and the calculation device cosϕ ₁ 55. From the output of the calculation device sinϕ ₁ 54 the obtained value is fed to the second input of the multiplier 58, and the signal from the output of the calculation device cosϕ ₁ 55 is fed to the second input of the multiplier 56 From the output of the amplitude detector 13, through contact 2 of the calculation unit 11, the signal is fed to the second inputs of the multipliers 57, 59, 60 and through contact 1 of the calculation unit 11 to the second input of the adder 19. The value obtained from the output of the multiplier 56 is fed to the first input of the multiplier 57, s the output of which the received signal comes through contact 7 of the calculation unit i 11 in parallel to the first input of the subtractor 32 and to the input of the module device 31. From the output of the multiplier 58, the signal goes to the first input of the multiplier 59, from the output of which the signal through contact 6 of the calculation unit 11 goes in parallel to the input of the module device 24 and the first input of the subtractor 25. From the output of the multiplier 60, through contact 5 of the calculation unit 11, the signal is sent in parallel to the first input of the subtractor 21 and to the input of the module device 23.

From the output of the amplitude detector 16, the signal enters in parallel to the first input of the adder 19 and through contact 1 of the calculation unit 12 in parallel to the second inputs of the multipliers 66, 68, 69. From the output of the frequency detector 17, the signal arrives through contact 2 of the calculation unit 12 in parallel to the input of the sinω calculation unit ₂ 61 and a device for calculating cosω ₂ 62. From the output of a device for calculating cos ω ₂ 62, the signal is fed to the first input of the multiplier 69. From the output of the phase detector 18, the signal through contact 3 of the calculation unit 12 is sent in parallel to the input of the calculation device sin ϕ ₂ 63 and the device for calculating cos ϕ ₂ 64. From the output of the device for calculating sinω ₂ 61, the signal is fed in parallel to the first input of the multiplier 65 and the first input of the multiplier 67. The second input of the multiplier 65 receives a signal from the output of the device for calculating cosϕ ₂ 64. From the output of the multiplier 65, the signal is fed to the first input of the multiplier 66. From the output of the calculation device sinϕ ₂ 63, the signal is fed to the second input of the variable 67, from the output of which the signal enters the first input of the multiplier 68, from the output of which the signal through contact 8 of the calculation unit 12 enters the input of the module 50 device and through contact 5 of the calculation unit 12 enters the second input of the subtractor 25. From the output of the multiplier 69, the signal through contact 4 of the calculation unit 12 enters the second input of the subtractor 21 and through contact 7 of the calculation unit 12 enters the input of the module 46 device. 32, from the output of which the signal is fed to the input of the quadrator 33.

From the output of the adder 19, the signal is fed to the input of the quadrator 20, from the output of which the signal is fed to the first input of the subtractor 39.

From the output of the subtractor 21, the signal goes to the input of the quadrator 22, from the output of which the signal goes to the first input of the adder 27. From the output of the subtractor 25, the signal goes to the input of the quadrator 26, from the output of which the signal goes to the second input of the adder 27.

From the output of the device module 23, the signal is fed to the first input of the subtractor 29, the second input of which receives the signal from the output of the device module 46.

From the output of the device module 24, the signal is fed to the first input of the subtractor 30, the second input of which receives the signal from the output of the device module 50.

From the output of the adder 27, the signal is fed to the first input of the adder 34, the second input of which receives the signal from the output of the quadrator 33. From the output of the adder 34, the signal is fed in parallel to the first input of the divider 47 and to the input of the square root extractor 41, from the output of which the signal is fed through device of the module 28 to the second input of the subtractor 39, from the output of which the signal is fed to the input of the quadrator 45, from the output of which the signal is fed in parallel to the second inputs of the multipliers 36, 37, 38.

From the output of the subtractor 29, the signal goes to the first input of the multiplier 36, from the output of which the signal goes to the input of the quadrator 42, from the output of which the signal goes to the first input of the adder 48.

From the output of the subtractor 30, the signal is fed to the first input of the multiplier 37, from the output of which the signal through the quadrator 43 is fed to the second input of the adder 48, from the output of which the signal is fed to the first input of the adder 49

The first input of the subtractor 35 receives a signal from the output of the module device 31, the second input of the subtractor 35 receives a signal from the output of the module device 40, and from the output of the subtractor 35 the signal arrives at the first input of the multiplier 38, from the output of which the signal passes through the quadrator 44 to the second input of the adder 49, from the output of which the signal goes to the second input of the divider 47, from the output of which the signal goes to the input of the square root extractor 51, from the output of which the amplitude value of the minimum possible “distance” between signals in a multidimensional metric space, through the contact 3 of the block for calculating the magnitude of the mutual influence of signals 3 enters the analog-to-digital converter 5, where it is digitized and fed in parallel to the first inputs of the elements And 7 and And 6, the second input of the element And 6 receives a logical unit from the fourth output of the decoder 74 through contact 6 of the control unit 4. And to the second input of the element AND 7 through contact 7 of the control unit 4 receives a signal from the output of the OR element 75. From the output of the AND element 6, the digital code of the threshold value is written to the register 8, from the output of which it enters the second input of the comparator 9.

With further receipt of counting pulse codes from the output of the counter 88 to the input of the decoder 74, on the fifth and subsequent n-outputs, logical units are sequentially formed, which are fed to the inputs of the OR element 75. The signals from the output of the OR element 75 are fed in parallel to the first inputs of the AND elements 80 and 81, to the reset input of the register of stimulus codes 77, the reset input of the register of stimulus codes 79, zeroing them and in parallel enter the first input of the element AND 84, the second input of which receives clock pulses from the output of the amplifier 85. When a logical unit appears on the n-th output logical unit, it enters the reset inputs of registers 70 and 72, resetting them. From the output of the AND element 84, the pulses are fed to the control input of the stimulus code register 83, allowing the recording of the canstellation chart symbol codes used in control objects 1 and 2 into the register 83, and the symbol codes were previously recorded in the ROM 86.

The same stimulus codes of the words of the canstellation diagrams from the output of the register 83 through the AND elements 80 and 81 simultaneously arrive, respectively, through the contacts 3,4 of the control unit 4 to the first inputs of the stimulating codes of control objects 1 and 2. From the outputs of control objects 1 and 2, QAM-modulated signals of the same words, but different carrier frequencies are sent to contacts 1 and 2 of the block for calculating the magnitude of the mutual influence of signals 3 and the automatic calculation of the "distance" between the signals in a multidimensional metric space is carried out, that is, determining the magnitude of the mutual influence of two signals.

At the output of the square root extractor 51 there will be a voltage, which is the result of measuring the magnitude of the mutual influence of the signals from the outputs of control objects 1 and 2, described by expression 1, which is digitized in the analog-to-digital converter 5 and through the AND element 7 is fed to the first input of the comparator 9 .

If the value of mutual influence (the distance between the spheres in a multidimensional metric space) is less than the allowable value, then a logical unit occurs at the corresponding third output of the comparator, which is fed in parallel to the input of the block for outputting control results 10, to the second (reset) input of register 89, resetting it and through contact 5 of the control unit 4 to the first input of the OR element 94, from the output of which the signal is sent in parallel to the reset input of the trigger 92 and to the input of the amplifier 91, from the output of which the signal is fed to the reset inputs of registers 70, 72, 77, 79, 83, zeroing them, thereby the device comes to its original state. The control results output block 10 displays information that the use of these modulated signals under study at these carrier frequencies is unacceptable and this combination of canstellation diagrams and carrier frequencies is rejected and the decision “not good” is made. If the value of mutual influence (the distance between the spheres in a multidimensional metric space) is greater than or equal to the allowable value recorded in register 8, then a logical unit occurs at the corresponding first and second outputs of the comparator, which means that the use of these modulated signals under study at these carrier frequencies is acceptable and is taken out decision is "good".

Claims (1)

Automated device for monitoring the mutual influence of signals. containing a control object, five registers, a decoder, two amplifiers, a counter, a read only memory (ROM), a delay element, a pulse generator, an analog-to-digital converter (ADC), a trigger, three OR elements, an AND element, the "Reset" and "buttons" Start”, control result output block, comparator, characterized in that a second control object is introduced, a block for calculating the mutual influence of signals, two calculation blocks, two amplitude detectors, two frequency detectors, two phase detectors, five adders, eight quadrators, seven subtractors , seven module devices, two square root extractors, a divider, a register, nine AND elements, and the first calculation unit contains a sinω ₁ calculator, a cos ω ₁ calculator, a sin ϕ ₁ calculator, a cos ϕ ₁ calculator, five multipliers, seven contacts, moreover, the output of the first amplitude detector through the second contact of the first calculation unit is connected in parallel to the first terminal clock of the first calculation unit and the second inputs of the second, fourth and fifth multipliers of the first calculation unit, the output of the first frequency detector through the third contact of the first calculation unit is connected in parallel to the inputs of the sinω ₁ calculation device and the cosω 1 calculation device _of the first calculation unit, the output of the first phase detector is connected through the fourth contact of the first calculation unit is parallel to the input of the calculation device sinϕ ₁ and the calculation device cosϕ _{1 of} the first calculation unit, the output of the calculation device sinω ₁ is connected in parallel to the first inputs of the first and third multipliers of the first calculation unit, the output of the calculation device cosω ₁ is connected to the first input of the fifth multiplier of the first calculation block, the output of the calculation device sinϕ ₁ is connected to the first input of the third multiplier of the first calculation block, and the output of the third multiplier is connected to the first input of the fourth multiplier of the first calculation block, the output of the calculation device cosϕ ₁ is connected to the second input of the first multiplier of the first calculation block, and its output is connected to the first input of the second multiplier of the first calculation block, the output of the second multiplier is connected to the seventh contact of the first calculation block, the output of the fourth multiplier of the first calculation block is connected to the sixth contact of the first calculation block, the output of the fifth multiplier of the first calculation block is connected to the fifth contact of the first calculation block, the second calculation block contains a sinω ₂ calculation device, a cos ω ₂ calculation device, a sin ϕ ₂ calculation device, a cos ϕ ₂ calculation device, five multipliers, eight contacts, and the output of the second amplitude detector is connected to the first input of the first adder and through the first contact of the second calculation unit is connected to the second inputs of the second, fourth and fifth multipliers of the second calculation unit, the output of the second frequency detector through the second contact of the second calculation unit is connected in parallel to to the inputs of the sinω ₂ calculation device and the cosω 2 calculation device _of the second calculation unit, the output of the second phase detector is connected through the third contact of the second calculation unit in parallel to the input of the sinϕ ₂ calculation device and the cosϕ ₂ calculation device of the second calculation unit, while the output of the sinω ₂ calculation device is connected in parallel to the first inputs of the first and third multipliers of the second calculation unit, and the output of the cosω ₂ calculation device is connected to the first input of the fifth multiplier of the second calculation unit, the output of the sinϕ ₂ calculation device is connected to the second input of the third multiplier of the second calculation unit, the output of the cosϕ ₂ calculation device is connected to the second the input of the first multiplier of the second calculation unit, the output of the second multiplier of the second calculation unit is connected to the sixth contact of the second calculation unit, the output of the fourth multiplier of the second calculation unit is connected in parallel to the fifth and eighth contacts of the second calculation unit, the output of the fifth multiplier of the second calculation unit is connected in parallel to the fourth and seventh contacts of the second calculation unit, and the first contact of the unit for calculating the magnitude of the mutual influence of signals is connected in parallel to the first inputs of the first amplitude detector, the first frequency detector, the first phase detector, and the second contact of the unit for calculating the magnitude of the mutual influence of signals the influence of signals is connected in parallel to the inputs of the second amplitude detector, the second frequency detector, the second phase detector of the unit for calculating the magnitude of the mutual influence of signals, the first input of the first adder is connected to the output of the second amplitude detector of the unit for calculating the magnitude of the mutual influence of signals, and to the first contact of the second calculation unit, the second the input of the first adder of the block for calculating the magnitude of the mutual influence of signals is connected to the first contact of the first block of calculation, and the output of the first adder is connected to the input of the first quadrator, the output of which is connected to the first input the first subtractor, to the second input of which the output of the first device of the module is connected, the input of which is connected to the output of the first square root extractor, the input of which is connected in parallel to the output of the second adder and to the first input of the first divider, the output of the first subtractor is connected to the input of the second quadrator, the output of which is connected in parallel to the second inputs of the first, second and third multipliers of the block for calculating the magnitude of the mutual influence of signals, the fifth contact of the first calculation block is connected in parallel to the first input of the first subtractor and to the input of the second device of the module, the fourth contact of the second is connected to the second input of the first subtractor calculation unit, the output of the first subtractor is connected to the input of the third quadrator, the output of which is connected to the first input of the second adder, the output of the second device of the module is connected to the first input of the second subtractor, the second input of which is is connected to the output of the third device of the module, and the output of the second subtractor is connected to the first input of the first multiplier, the sixth contact of the first calculation unit is connected in parallel to the first input of the third subtractor and to the input of the fourth device of the module, the output of which is connected to the first input of the fourth subtractor, the output which is connected to the first input of the second multiplier, the seventh contact of the first calculation unit is connected in parallel to the first input of the fifth subtractor and to the input of the fifth device of the module, the output of which is connected to the first input of the first subtractor, the fifth contact of the second calculation unit is connected to the second input of the third subtractor , the output of which is connected to the input of the fourth quadrator, the output of which is connected to the second input of the second adder, the output of which is connected to the first input of the second adder, the output of the fifth quadrator is connected to the second input of which, to the input of which is connected en output of the fifth subtractor, the sixth contact of the second calculation unit is connected in parallel to the second input of the fifth subtractor and to the input of the sixth device of the module, the output of which is connected to the second input of the fifth subtractor 35, the output of which is connected to the first input of the third multiplier, the seventh contact of the second block calculation is connected to the input of the third device of the module, the eighth contact of the second calculation unit is connected to the input of the sixth device of the module, and the output of the sixth device of the module is connected to the second input of the fourth subtractor, the output of the first multiplier is connected in series through the fourth quadrator to the first input of the third adder, to the second input which the output of the second multiplier is connected in series through the fifth quadrator, and the output of the third adder is connected to the first input of the fourth adder, to the second input of which the output of the third multiplier is connected in series through the sixth quadrator, the output of the fourth The third adder is connected to the second input of the first divider, and the output of the first divider is connected to the input of the second square root extractor, the output of which, through the third contact of the unit for calculating the magnitude of the mutual influence of signals, is connected to the input of an analog-to-digital converter (ADC), the output of which is connected in parallel to the first to the inputs of the first and second AND elements, the sixth contact of the control unit is connected to the second input of the element of the first AND element, and the seventh contact of the control unit is connected to the second input of the second AND element, the output of the element of the first AND element is connected to the first input of the first register, the output of which is connected to the second the input of the comparator, to the first input of which the output of the second element AND is connected, three outputs of the comparator are connected to the output block of the control results, and the third output of the comparator is also connected in parallel to the second input of the first register and to the fifth contact of the control unit, the counter outputs of the control unit are connected in parallel to the inputs of the decoder, the outputs of the ROM are connected in parallel to the inputs of five registers of the control unit, the output of the first amplifier is connected in parallel to the second inputs of five elements AND of the control unit, the output of the first register of the control unit is connected to the first contact of the control unit, the output of the second register of the control unit is connected to the second contact control unit, the output of the third register of the control unit is connected to the input of the second delay element, the output of which is connected in parallel to the third contact of the control unit and to the output of the first element AND the control unit, the output of the fourth register of the control unit is connected in parallel to the fourth contact of the control unit and to the output of the second element And the control unit, the output of the fifth register of the control unit is connected in parallel to the second inputs of the first and second elements of the AND control unit, to the first inputs of which the output of the first element OR of the control unit, the seventh contact of the control unit and the reset inputs of the control unit are connected in parallel third and fourth registers of the control unit, the first output of the decoder is connected to the first input of the first element AND of the control unit, the second output of the decoder is connected to the first input of the second element AND of the control unit, the third output of the decoder is connected to the first input of the third element AND of the control unit, the fourth output of the decoder is connected in parallel to the first input of the fourth element I of the control unit and to the sixth contact of the control unit, from the 5th to the nth outputs of the decoder are connected in parallel to the inputs of the first element of the control unit, and the nth output of the decoder is connected in parallel to the reset inputs of the first and second registers , the fifth contact of the control unit is connected to the first input of the second element OR, to the second input of which the "Reset" button is connected, the first contact of the control unit is connected to the second input of the first object of control, and the third contact of the control unit is connected to the second input of the second object of control, the second contact control unit connected to the lane the first input of the first object of control, and the fourth contact of the control unit is connected to the first input of the second object of control.

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