RU2071107C1 - Inspection device for radioelectronic parts - Google Patents

Abstract

FIELD: measurement technology; automatic-control systems for complex radioelectronic parts. SUBSTANCE: device has polling commutator 3, master commutator 2, analog-to-digital converter 4, parameter deviation computing and evaluating unit 5, inspection result output unit 6, stimulating signal unit 7, control unit 8, signal switch 9, switch 10, standard signal shaper 11, relative difference factor meter 12, AND gate 13, threshold value meter 14 for relative difference factor, signal-energy-to-noise-spectral-density metering unit 15, comparator 16, OR gate 17. EFFECT: improved validity of inspection results due to using generalized index of part serviceability, that is, data transmission with desired or worse error probability, as indication of its condition. 2 cl, 6 dwg

Description

 The invention relates to instrumentation and can be used to create automatic control systems for complex electronic products.

 A device for monitoring the parameters of electronic products (ed. St. N 166539A1 from 07.23.91, class G 06 F 15/46), using the measurement of a complex indicator, which is a function of a number of parameters of the controlled product. As such a complex indicator, it was proposed to use the mutual difference coefficient (CWR) of the reference signal, the parameters of which have nominal values, and the signal being monitored (from the output of the control object).

где:

h² отношение энергии сигнала к спектральной плотности шума;
G g² коэффициент взаимного различия эталонного сигнала и сигнала контролируемого средства связи;
Pк, Рэ мощности соответственно контролируемого и эталонного сигнала;
Z $\genfrac{}{}{0ex}{}{\text{*}}{\text{э}}$ (t) функция, комплексно сопряженная с

;

комплексная форма представления соответственно контролируемого и эталонного сигналов;
T длительность элемента сигнала.In general terms, when the values of the parameters of the real means of communication are different from the nominal (reference), the probability of an error of incoherent element-by-element reception under noise interference conditions is determined by the expression:

Where:

h ^{2 the} ratio of signal energy to spectral noise density;
G g ^{2 the} coefficient of mutual difference between the reference signal and the signal of the controlled means of communication;
Pk, Pe of the power of the controlled and reference signal, respectively;
Z $\genfrac{}{}{0ex}{}{\text{*}}{\text{uh}}$ (t) a function complex conjugate to

;

a comprehensive presentation of the respectively monitored and reference signals;
T is the duration of the signal element.

для ФРМ,
где U_m, ω,ψ соответственно амплитуда, несущая частота и начальная фаза сигнала.For the case of the r-th variant of discrete narrow-band frequency (BH) or phase-difference-manipulated (PRM) signals, they use their analytical representation
Z _rк (t) = U _mк exp [j (ω _rк t + ψ _к )] for

for FRM,
where U _m , ω, ψ, respectively, are the amplitude, carrier frequency, and initial phase of the signal.

где η относительная величина краевых искажений дискретного сигнала.By the formula (2) we determine the CWR of the controlled and reference frequency-manipulated signals:

where η is the relative value of the edge distortions of the discrete signal.

Как видно из фиг. 6, зависимость коэффициента G g² от разности частот контролируемого и эталонного сигналов, определяемой нестабильностью частоты радиосредства и краевых искажений контролируемого сигнала представляет собой поверхность в трехмерном пространстве, характерной особенностью которой является наличие глобального максимума G g² макс 1 в точке, соответствующе случаю равенства значений всех параметров контролируемого сигнала номинальным (Ω=0,η=0). Отклонение значения любого из параметров от номинального значения вызывает уменьшение g. Согласно ГОСТ 14662-83 краевые искажения, вносимые передающей аппаратурой радиосвязи, не должны быть более 3% во всех режимах излучения. При этом (см. фиг. 5) коэффициент взаимного различия не должен быть ниже порогового g_пор ² G 0,94, т.е. область работоспособности по параметру η определяется интервалом значений g²∈[0,94;1].. Допуск на относительную нестабильность частоты, например, для радиостанции Р-143 равен Δf/f₀ 3 • 10^-6, что при передаче на частоте f_o 18 МГц дискретной информации со скоростью 50 Бод соответствует точке на оси абсцисс

Т/2П 0,17. Область допустимых значений параметров для данной радиостанции представляет собой участок с нанесенной сеткой g²(η,ΩT/2П. Пусть надлежит провести приемосдаточные испытания двух радиостанций, значения параметров первой из которой определяется точкой a (η = 0,023;ΩT/2П = 0,16),, второй точкой (η = 0,022;ΩT/2П = 0,02). Поскольку точка "а" находится в пределах области допустимых значений, то принимается решение о годности первой радиостанции к эксплуатации. Что касается второго контролируемого изделия, то оно возвращается изготовителю как не пригодное к эксплуатации, так как точка δ находится вне поля установленных допусков. Однако в первом случае КВР эталонного сигнала и сигнала контролируемой радиостанции g $\genfrac{}{}{0ex}{}{\text{2}}{\text{a}}$ = 0,87, а во втором g $\genfrac{}{}{0ex}{}{\text{2}}{\text{б}}$ = 0,93, что с учетом выражения (1), где h² 10, соответствует прогнозируемой вероятности ошибки поэлементного приема Р_оша 6,4 • 10^-3 и P_ошб 4,6 • 10^-3.After the transformations and the introduction of the notation W = ω _{rk -ω re, the} expression for the mutual difference coefficient will take the final form:

As can be seen from FIG. 6, the dependence of the coefficient G g ² on the difference between the frequencies of the controlled and reference signals, determined by the instability of the frequency of the radio and edge distortions of the controlled signal, is a surface in three-dimensional space, a characteristic feature of which is the presence of a global maximum G g ² max 1 at a point corresponding to the case of equality of values all parameters of the monitored signal are nominal (Ω = 0, η = 0). Deviation of the value of any of the parameters from the nominal value causes a decrease in g. According to GOST 14662-83, the edge distortions introduced by the radio transmission equipment should not be more than 3% in all radiation modes. In this case (see Fig. 5), the mutual difference coefficient should not be lower than the threshold g _pore ² G 0.94, i.e. the working area with respect to the parameter η is determined by the interval of values g ² ∈ [0.94; 1] .. The tolerance for relative frequency instability, for example, for the P-143 radio station, is Δf / f ₀ 3 • 10 ^-6 , which when transmitted at the frequency f _o 18 MHz discrete information with a speed of 50 Baud corresponds to a point on the abscissa axis

T / 2P 0.17. The range of permissible parameter values for this radio station is a section with a grid of g ² (η, ΩT / 2P. Let acceptance tests of two radio stations be carried out, the parameter values of the first of which are determined by the point a (η = 0,023; ΩT / 2П = 0,16 ) ,, the second point (η = 0.022; ΩT / 2P = 0.02). Since the point "a" is within the range of acceptable values, a decision is made on the suitability of the first radio station for use. As for the second controlled product, it returns manufacturer as not suitable for use oation, since the point δ is outside the set tolerance field, however, in the first case, the CWR of the reference signal and the signal of the monitored radio station $\genfrac{}{}{0ex}{}{\text{2}}{\text{a}}$ = 0.87, and in the second g $\genfrac{}{}{0ex}{}{\text{2}}{\text{b}}$ = 0.93, which, taking into account the expression (1), where h ² 10, corresponds to the predicted probability of the error of the element-wise reception of _Rosh 6.4 • 10 ^-3 and _Pshb 4.6 • 10 ^-3 .

 Therefore, when monitoring radio stations according to the parameters, the customer can accept a product that is characterized by further use with a greater probability of erroneous reception than a rejected product.

 For real tools, a generalized indicator of the suitability of using these tools for certain operating conditions is the probability of erroneous reception of signal elements.

 The purpose of the invention is to increase the reliability of control of electronic products by deciding on their performance by a generalized indicator of the quality of functioning, which determines the conformity of the technical condition of the controlled product to its intended purpose, the transmission of information with a given or lesser probability of errors.

Entering into the device the required value of the probability of erroneous reception of the signal element, given according to the technical conditions for the controlled product, we obtain the value of the threshold of the RCC _pore . By comparing the value of the coefficient of mutual difference between the test signal and the reference signal with a threshold pore value, a decision is made on the suitability or unsuitability of the controlled product for operation under predetermined conditions with a given probability of an error in receiving a signal element.

 In FIG. 1 shows a structural diagram of the proposed device; in FIG. 2 one of the embodiments of the device; in FIG. 3 is a functional diagram of a deviation calculation and parameter estimation unit; in FIG. 4 microprocessor operation algorithm; in FIG. 5 general control algorithm.

The device for monitoring the parameters of object 1 comprises a master switch 2, an interrogator switch 3, an analog-to-digital converter 4, a deviation calculation and parameter estimation unit 5, a control result output unit 6, stimulating signal unit 7, a control unit 8, a signal switch 9, a key 10 , a shaper of the reference signal, a meter 12 of the coefficient of mutual difference of signals, element And 13, a meter of the threshold value of the coefficient of mutual difference 14, block 15 measuring the ratio of signal energy to spectral density noise (h ² ) (USSR author's certificate N 1001489, class N 04 B 3/46), comparator 16, OR element 17, and the inputs of the OR element 17 are connected to the outputs (A> B), (A B), (A <B) of the comparator 16 and to the inputs of the control result output unit 6. The output of the OR element 17 is connected to the second input of the AND element 13.

 The composition of the master switch 2 includes amplifiers 18.1 18m and relays 19.1 19.m. Interrogation switch 3 contains amplifiers 20.1 20.m and relays 21.1 21. m. The output register 22 is shown in the analog-to-digital converter 4. The deviation calculation and parameter estimation block 5 comprises a microprocessor 23, an automatic control unit 24 (for example, a code decoder), a parameter deviation digital register 25, an AND 26 29 group of elements, and an OR 30 group of elements ( for example, interface buses) The control unit 8 contains the Start and Reset buttons 31 and 32, respectively, the OR elements 33 35, the trigger 36, the pulse generator 37, the And element 38, the delay element 39, the amplifiers 40 43, the counter 44, the block 45 read-only memory, decoder 46 commands a strobe input registers 47 and 48 command the control switches 2 and 3 and the code registers 49 of the stimulus, and the nominal tolerance of 50 51.

The signal switch 9 includes an amplifier 52 and 53, as well as a contact group of four input and six output contacts, the first input contact of switch 9 being connected to the output of the interrogating switch 3 and, when the relay 53 is off, normally closed with the 1st output contact, which is connected to the input of the analog-to-digital converter 4. The second input contact of the switch 9 is connected to the output of the normalizing unit 70 and when the relay 53 is off, it is not closed with any contact. The 3rd input contact is connected to the output of the register of codes of nominal values 50 and when the relay 53 is disconnected, it is normally closed with the 3rd output contact connected to the input of the element And 27 of block 5. The 4th input contact is connected to the output of the register 22, 2nd the output contact is connected to the inputs of the multipliers 65.1 and 65.2 and to the input of the measuring unit h ² 15, the 4th output contact is connected to the input of the And element 72 of block 14, the 6th output contact is connected to the first input of the comparator 16. The control result output unit 6 contains input register 54.

 In addition, the microprocessor 23 includes an information input unit 55, an information output unit 56, a read-only memory unit 57, a firmware control unit 58, an arithmetic logic unit (ALU) 59, and a RAM unit 60.

 The microprogram control unit 60 contains the microprogram control unit 61 (MPU) proper, which is used to generate micro-command addresses depending on the conditions coming from the ALU 59 to the microprogram memory block 62, which stores the microprogram received in the microprocessor 23.

 The microprocessor 23 is used to perform arithmetic operations on operands introduced into it and to provide the required algorithm for the interaction of the blocks of the device. Shaper 11 of the reference signal is designed to generate a signal similar to the output signal of the electronic object 1 of the control, but the parameters of the reference signal have nominal values.

 The measuring instrument 12 of the CWR signals includes a phase shifter 64, which converts the reference signal according to Hilbert, two multipliers 65.1 and 65.2, two integrators 66.1 and 66.2, two quadrants 67.1 and 67.2, adder 68, gate block 69, normalizing block 70 and delay element 71.

The meter 14 of the threshold value of the coefficient of mutual difference, consisting of an element And 72, a doubler 73, a quadrator 74, a logarithmic device 75, a divider 76, and the 1st input of the And 72 element is connected to the 4th output terminal of the switch 9 signals, 2nd input And element 72 is connected to the output of the automatic control unit 24, the input of the doubler 73 is connected to the output of the And 72 element, the output of the doubler 73 is connected to the input of the quadrator 74, the output of the quadrator 74 is connected to the input of the logarithmic device 75, the output of which is connected to the first input of the divider 76, the second input of which is connected to the output of the measurement unit 15 of h ² , the input of which is connected to the 2nd output terminal of the signal switch 9. The output of the divider 76 is connected to the second input of the comparator 16.

 The device operates as follows.

 First, n m parameters are monitored (from the set of parameters characterizing the technical state of the radio-electronic object 1) that do not affect the value of the coefficient of mutual difference between the controlled and reference signals. At the same time, the controlled signal is converted into a code, compared with the code of the nominal value, calculating the parameter deviation value, then the result of the conversion is compared with the code of the admissible parameter deviation value, determining the parameter estimate ("normal" or "not normal").

After that, instead of the remaining m parameters characterizing the quality of the output signal of the electronic object 1, measure the coefficient of mutual difference of the controlled and reference signals g ² , which is a complex parameter (indicator of the quality of the controlled signal). The measurement result is converted into digital form and compared in the comparator 16 with the threshold code of the CWR of the permissible value calculated by the functional dependence in block 14 of the probability of erroneous reception of the signal R _OS . If g ² G is greater than or equal to g _pores , then a decision is made that all m parameters are within tolerances and the totality of parameter deviations within tolerances does not give a probability of a reception error above a set preset value of _Rsh.set . The control of object 1 ends here. The threshold value of the CWR q _{pore is} calculated by the previously selected required probability of erroneous reception for a given control object and the calculated parameter of the ratio of signal energy to spectral noise density at the output of the control object.

 Before starting work, the device is initialized by applying a "Reset" signal from button 32 through the OR element 35 and amplifier 40 to the reset inputs of all the registers and triggers of the device, as well as to the reset input of the microprocessor 23. In the initial state, the contents of registers 22, 25, 47 52 and 54 of the node 60 of the microprocessor 23 is zero, the trigger 36 and the counter 44 are reset, and the element And 38 is closed for the passage of pulses from the generator 37.

 In the initial state, the output of the stimulating signal block 7 is disconnected using the relay 19.1 19.m of the master switch 2 from the inputs of the monitoring object 1, the outputs of which are also disconnected using the relay 21.1 21.m of the polling switch 3 from the first signal input of the signal switch 9.

 At the same time, in the initial state, the information input of the analog-to-digital converter 4 is connected to the output of the interrogating switch 3 through the normally closed first input and first output contacts of the relay 53.

 The automatic control cycle begins by supplying a “Start” signal from button 31, which, having passed through the OR element 33 to the installation input of trigger 36, ensures that the output of the last signal is equal to a logical unit, which opens the And 38 moment for pulses from the generator 37 to the input element 39 delay and counting input of the counter 44.

 Having arrived at the counter input of the counter 44, the first pulse from the generator 37 changes the contents of this counter by one, i.e. in this case, generates at the input of the counter 44 the address code of the first word of the program of the controlled parameter. After the time required to complete the transients in the counter 44, a pulse is transmitted from the generator 37 through the delay element 39 to the input of the permanent storage device 45 as a signal: “read”, and to the input of the amplifier 41 as a clock pulse. According to the “read” signal, the read-only memory 45 performs, with the frequency of the generator 37, reading the words of the control program of the parameter in question. In this case, the contents of the counter 44 changes by one each time a pulse is received and from its counter input from the generator 37. The program information is read by the read-only memory 45 at the same time from the addresses of one of the registers 47 51 or the decoder 46 where this information should go. In the register 49 enter a code that determines the type of stimulating signal generated by block 7.

In register 47 enter the command that defines the point in the object 1 of the control where this stimulating signal will be applied. In register 43 enter the command that defines the point in the object 1 of the control from which should be removed controlled signal. In the register 50 enter a code that determines the nominal value of the monitored parameter and also enter the value of R _OSH . In the register 51 enter a code that determines the allowable value of the deviation of the parameters from the nominal value (tolerance on the parameter). After entering the program information into the registers 47 51, a code is supplied to the input of the decoder 46, according to which the latter generates an impulse command "Start" of the analog-to-digital converter 4 and the microprocessor 23.

 The last code is supplied to the decoder 46, which ensures the formation of the “Stop” pulse command at its output. By this command, the reading of program information by the permanent storage device 45 is terminated, since the Stop command, coming to the input of the OR element 34 and then to the trigger input of the trigger 35, removes the resolving potential from the input of the And 38 element, preventing the passage of pulses through it from the generator 37 .

 When the “Start” command is received at the input of the microprocessor 23, the algorithm for managing the calculations and the interaction of blocks 4, 6, and 8 with each other in automatic mode, written to node 57, is launched. A code is entered into the automatic control unit 24 from the control output of the microprocessor 22, according to which a control signal is generated that provides the input of the nominal value code from the output of the register 50 through the third input and output contacts of switch 9 and through the group of elements 27 and the group of elements OR 30 ALU 59 microprocessor 23 as the first operand. After receiving the signal "End of conversion" from the output of the analog-to-digital converter 4, the microprocessor 23 issues a code to block 24, which ensures that the block 24 generates a signal according to which the code stored in register 22 is entered as an operand through the 4th input and 5 output contacts switch 9 and through the group of elements AND 26 and the group of elements OR 30 in the ALU 59 of the microprocessor 23, where the magnitude and sign of the deviation of the parameter of the monitored signal from its nominal value are calculated.

 The microprocessor 23 issues the resulting code and the deviation sign to its information output. At the same time, the microprocessor 23 issues through the control output to the block 24 the address code of the register 25, where the received code and the deviation sign are written.

 The next clock from the control output of the microprocessor 23 to the input of block 24, the code is entered, according to which a control signal is generated that provides the code input of the permissible value of the deviation of the parameter from the output of the register 51 through the group of elements AND 28 and the group of elements OR 30 in ALU 59 of the microprocessor 23 as first operand. Next, the microprocessor 23 issues a code to block 24, according to which the contents of the register 25 are entered through the AND 29 and OR 30 elements as the second operand into the ALU 59 of the microprocessor 23, where the deviation of the parameter of the monitored signal from the nominal value is compared with the tolerance for deviation of the parameter.

 The comparison result is output through the information output of the microprocessor 23 to the register 54 of the control result output unit 6. At the same time, the microprocessor 23 gives to the input of block 24 a register address code 54. As digits carrying information about the evaluation of the monitored parameter, sign digits of the obtained control result are used. The output of the Minus sign in this case is connected to the “Rating: Invalid” input of block 6, and the output of the Plus sign with the “Rating: Suitable” input, respectively.

где Z_к(t), Z_эt) функции времени, определяющие структуру соответственно контролируемого и эталонного сигналов;

функция времени, сопряженная по Гильберту с
Р_э мощность эталонного сигнала;
T длительность элемента эталонного сигнала.Having issued the control result to block 6 for registering an indication, the microprocessor 23 supplies two control codes in series to the input of block 24. According to the first of them, block 24 generates and outputs to Block 8 a "Reset" signal, which is input to the OR element 35 and then to amplifier 40, as a result, the device is restored to its initial state. According to the second code, block 24 provides the start signal, which is fed to the input of the OR element 33 and then to the installation input of the trigger 36, the control procedure for the second and subsequent parameters proceeds similarly. After controlling the nm parameters, a signal appears at the mth output from the second group of control outputs of block 8 of the programs. This control signal, coming through the amplifier 52 to the relay 53, provides in the switch 9 of the signals the switching of the first signal input with a second signal output, the second input with the first signal output, the third input with the fourth output, the fourth input with the sixth output. In addition, the signal from the mth control output of block 8 of the program opens the electronic key 10, while ensuring the passage of the stimulating signal from the output of block 7 to the input of the shaper 11 of the reference signal. Thus, the monitored signal is fed to the first signal input of the meter 12 of the coefficient of mutual difference between the signals from the output of the interrogating switch 3 through the switch 9 and to the input of the measurement unit 15 h ² , and the reference signal Z _e is supplied to the second signal input of the meter 12 from the output of the shaper 11 ( t). At the same time, a controlled signal is supplied to the first inputs of the multipliers 65.1 and 65.2, the reference signal is sent to the second input of the multiplier 65.1 directly, and to the second input of the multiplier 65.2 through the phase shifter 64, which provides a signal conjugated by Hilbert with the signal arriving at its input. The results of multiplication from the outputs of blocks 65.1 and 65.2 are fed to the signal inputs of integrators 66.1 and 66.2, where the integration process takes place over a time interval equal to the duration of the element of the reference signal. From the outputs of the integrators, the signals are supplied to the inputs of the quadrants 67.1 and 67.2, and then from their outputs to the corresponding inputs of the adder 67. From the output of the adder 68, the signal is fed to the information input of the gating unit 69, to the control input of which at time t T from one of the outputs of the element 71 delays a gating pulse. Then, a pulse is supplied from the second output of the delay element 71 to the control inputs of the integrators 66.1 66.2 to reset them to the zero state. The input of element 71 is the control input of the meter 12 of the coefficient of mutual difference between the signals and is connected to the output of the electronic key 10. From the output of the strobe block 69, the signal is fed to the input of the normalizing block 70, consisting of a power meter of the reference signal and a voltage divider (not shown). The output of the normalizing unit 70 will contain a voltage representing the result of measuring the mutual difference coefficient of the signal of the controlled object and the reference signal, described by the following expression:

where Z _to (t), Z _e t) time functions that determine the structure of the respectively monitored and reference signals;

Hilbert time function with
P _{e the} power of the reference signal;
T is the duration of the element of the reference signal.

The result of measuring the coefficient g G from the output of the meter 12 CWR signals through switch 9 (input 2 output 1) is fed to the information input of the analog-to-digital converter, from the output of register 22 of the analog-to-digital converter 4 through input 4 and output 6 of the switch 9 is fed to the first input comparator 16. From the output of the register 50, the previously set value of _{Psh is} received through the 3 input of the switch 9 and the 4 output to the first input of the And 72 element, the second input of which receives an enable signal from the automatic control unit. From the output of element And 72, the value of P _Osh goes to the input of the doubler 73, in the doubler 70 the value of P _Osh doubles and from the output of the doubler 73 goes to the input of the quadrator 74, where the square of the doubled value of P _Osh takes place, from the output of the quadrator 74 the received value goes to the input of the logarithmic device 75, the output of which the signal is supplied to the first input of the divider 76, the second input of which receives a signal that determines the value of h ² from the output of block 15 of the measurement h ² .

С выхода делителя 76 значение g_пор поступает на второй вход компаратора 16, где происходит сравнение значений g и g_пор. В зависимости от полученного результата g > g_пор, g g_пор, g < g_пор на одном из трех соответствующих выходах компаратора 16 появится единица, которая поступает на один из входов блока 6 вывода результатов контроля (для индикации информации "Оценка: годен", "Оценка: продольное значение" и Оценка: негоден" и на один из входов элемента ИЛИ 17, с выхода которого логическая единица поступает на второй вход элемента И 13. Так как на первом входе элемента 13 присутствует напряжение с m-го выхода второй группы управляющих выходов блока 8, то с выхода элемента И 13 на вход элемента ИЛИ 34 блока 8 поступит команда "Стоп" для прекращения дальнейшего контроля объекта 1.At the output of the divider 76, a code combination will be present, which is the result of measuring the threshold value of the CWR for a given probability of error R _{osh of the} test object 1

From the output of the divider 76, the value of g _then goes to the second input of the comparator 16, where the values of g and g _then are compared. Depending on the result obtained, g> g _pores , gg _pores , g <g _pores , a unit appears at one of the three corresponding outputs of the comparator 16, which is fed to one of the inputs of the control results output unit 6 (for displaying the information "Rating: good", " Evaluation: the longitudinal value "and Evaluation: unsuitable" also to one of the inputs of the OR element 17, from the output of which the logical unit goes to the second input of the And 13. element. Since the first input of the element 13 contains voltage from the mth output of the second group of control outputs block 8, then from the output of the element And 13 at the input of the OR element 34 of block 8, the Stop command will be received to stop further monitoring of object 1.

 The decision is made that the parameters that have not been controlled by m, which determine the value of the mutual difference coefficient (i.e., the function of which the selected indicator g is a function of), are normal or not normal, and the totality of deviations of the values of these parameters from the nominal values does not give an error probability greater than the specified, less than the specified or equal to the specified.

The use of this device allows to increase the reliability of the control, since the quality indicator g quantitatively determines the correspondence to the technical state of the communication device for its intended purpose, the transmission of information with a given or lesser probability of errors, to obtain the value h ² of the control object, which excludes the acceptance of the product, which is more likely during further operation erroneous reception than a rejected value. A side economic effect is an increase in the speed of control of electronic products as compared with the prototype, since if the CWR is below the threshold value, it is not necessary to measure the parameters in full, because the parameter values can be in the range of acceptable values, but the combination of these parameters during actual operation may give the probability of erroneous reception more than specified by the technical conditions for this controlled product.

Claims (2)

 1. A device for monitoring electronic products, containing a master switch, the signal outputs of which are the outputs of the device used to connect the inputs of the control object, an interrogating switch, the signal inputs of which are the inputs of the device, used to connect the outputs of the control object, a signal switch, analog-to-digital converter , a unit for calculating deviations and parameter estimates, a unit for outputting a control result, a meter for the mutual difference coefficient, a block of stimulating signals , a shaper of the reference signal, a key, an AND element, and a control unit, the information output of which is connected to the input of the stimulating signal block, connected by the output to the information input of the key and the information input of the master switch connected by address inputs to the outputs of the address of the first group of the control unit connected by outputs of the second address groups with address inputs of the interrogating switch connected by the output to the first information input of the signal switch, one of the outputs of the address of the second group of the control unit The signal is connected to the control input of the signal switch, the first input of the And element, and the control input of the key, connected by the output to the input of the shaper of the reference signals and the input of the start of the meter of the coefficient of mutual difference of signals, connected to the second information input of the signal switch, connected to the first and second outputs with information inputs respectively, an analog-to-digital converter and a meter for the coefficient of mutual difference between the signals, the trigger input of the analog-to-digital converter The driver is connected to the first interrupt input of the deviation calculation and parameter estimation block and the control output of the control unit connected by the output of permissible deviation values to the first information input of the deviation calculation and parameter estimate block connected to the start and reset outputs to the control block start and reset inputs, and the first and second information outputs, respectively, to the first and second information inputs of the control result output unit, the output of the AND element is connected to the input of the control unit, characterized in that the device includes a unit for measuring the ratio of signal energy and noise spectral density, a comparator, an OR element, and a threshold difference coefficient threshold meter including a And element connected in series, a doubler, a quadrator, a logarithmic unit, a divider, and a control unit nominal value output connected to the third information input of the signal switch associated with the fourth information input with the information output of the analog-to-digital converter, the third inf a radiation output with a second information input of the deviation calculation and parameter estimation unit, a fourth information output with the first input of the AND element of the threshold value of the mutual difference coefficient, the fifth information output with the third information input of the deviation calculation and parameter estimation unit, the sixth information output connected to the first input of the comparator connected by the second input to the output of the divider connected by the second input to the output of the meter of the ratio of signal energy to spectrum noy noise density associated with the second information input of output switch signals, two outputs inequality and equality comparator output connected respectively to the second, third and fourth information inputs of the control unit and outputting the respective inputs of the OR gate, the output associated with the second input element I.  2. The device according to claim 1, characterized in that the signal switch includes a relay with four groups of contacts, each of which contains a movable contact and, in addition to the second group, two fixed contacts, and the second group contains a fixed contact combined with the first fixed contact of the first groups, moving contacts from the first to fourth contact groups are the corresponding information inputs of the switch, fixed contacts of the first, third and fourth contact groups are respectively the first and second , Third, fourth, fifth and sixth outputs switch information, one terminal of the relay coil connected to the bus zero potential and the second terminal of the relay coil connected to the output of the amplifier whose input is a control input of the switch.

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