SU765813A1 - Device for matrix testing of radio electronic circuits - Google Patents

Description

The invention relates to the field of automation and computer technology and is intended for use in systems for checking and optimizing parameters by the criterion of reliability. Inertialess electronic circuits in static mode. The known device for conducting matrix tests of electronic circuits does not have sufficient accuracy, as it allows to investigate the effect of only two parameters, without taking into account the correlation links arising between the parameters. The closest technical solution to the invention is a device for conducting matrix tests of electronic circuits. containing a control unit, the output of which is connected to the first inputs of a random number sensor, blocks for the formation of test signals, simulation, control, the three sections of the operating area, the computing unit and the nominal value setting unit, connected by one output to the first input of the control unit and the other inputs to the output of the computing unit and the first OUTPUT-clock generator, the second and third outputs of which are connected respectively to one input of the switching unit, connected by another input through the block of implementations to the first output of the random number sensor, and the second input of the control unit, the third input of which is connected to one output the home of the implementation analyzer connected by the input to the output of the control unit and the other output to the second input of the construction section of the operability section, the output of which is connected to the second input of the computing unit, and the output of the switching unit connected to the second input of the modeling unit connected to the second input of the control unit and the third input - with one output of the block; the formation of test signals, with the third input of the control block connected to the first output of the clock generator z. However, this device also does not have high accuracy, due to the limited nature of taking into account the influence of parameters on each other. The purpose of the invention is to improve the accuracy of the device.

This is achieved by the fact that it contains correlator matrix matrices and the modulator of the coefficients of influence coefficients connected by the output to the third input of the computing unit and inputs to the output of the control unit and one output of the matrix of influence coefficients, the inputs of which are connected to another output the test signal generating unit connected by the second input to the second output of the random number sensor, the output of the control unit and the other output of the nominal value setting unit, and others goy shaper output matrix coefficients effect connected through matrix generator correlation coefficients, the other input connected to the output of the control unit, to chetvepto / Iy input of the computing unit.

The drawing shows the functional diagram of the device.

The proposed device comprises a switching unit 1, an implementation enumeration unit 2, a random number (quanta) sensor 3, a control unit 4, a clock generator 5, a test signal generating unit b, a modeling unit 7, a control unit 8, an analyzer 9 implementations, a unit 10 building cross sections of the health domain, computing unit 11, nominal value setting unit 12, shaper 13 (determining unit) of influence coefficient matrices, shaper 14 (determining unit) of influence coefficient modules, and shaper 15 (determining unit nor) matrices of correlation coefficients.

Switching unit 1 (typesetting field) is a group of key elements that provide switching representatives of the quanta of the studied elements of the physical model of the circuit and are controlled by unit 2 of the brute force implementations. The brute force block implementation serves to control the switching keys. Sensor 3 random quanta serves to find the required number of initial random points (by the parameters of the components of the circuit under study and by external influences) on the command from the control unit, it satisfies the health conditions, and to conduct a consistent pairwise random search of the parameters of the physical model of the circuit under study. block 7 for each initial random point. The control unit 4 through the sensor 3 random quanta controls the enumeration block of implementations, finding the necessary number of initial random points satisfying the operability conditions, and carrying out a sequential pairwise enumeration of the parameters of the physical model of the tested circuit of unit 7 for each initial random point, outputs to the block 10 for building sections the field of health current numbers of parameters and their quanta involved in the search, at the command of the unit 12 installation of nominal values, includes the corresponding number of quantum the parameter of the physical model of the circuit, permits the test signals to block 13 for those initial random points that satisfy the performance conditions, and in block 13 for determining the matrix of coefficients of influence on the optimum nominal values of the parameters of the components obtained for each initial random point that satisfies the conditions of health , gives permission for the determination of correlation coefficient matrices in block 15 and the modules of influence coefficients in block 14, and also coordinates the work of the other blocks . The clock pulse generator 5 is used to synchronize the operation of the switching units, control and set the nominal values with the control unit for a given rhythm. The test signal generating unit B generates a complex of external input signals for each specific physical model of the circuit. The modeling unit 7 is designed as a board, on which, in series with the contacts of the corresponding key elements of block 1, quanta outputs of the simulated parameters of the circuit under study are connected with ranges of variation that determine the boundaries of the health region of this circuit. The control unit 8 converts any output signal of the circuit under study into a form and value convenient for processing and analysis in the analyzer of 9 realizations. The analyzer 9 implementations characterizes each implementation, determines whether it is operational or not, in accordance with the previously selected performance criteria. The building block 10 of the working area of the health according to the control unit 4 and the analyzer 9 implements the section of the health area for each pair of parameters for each of the initial starting random points, converts this information into a form convenient for the subsequent work, and on the command of the control unit outputs it to computational unit 11. Computing unit 11 writes in each section of the operability area and in accordance with the developed algorithm, the optimal section of the tolerance region, performs processing a series of obtained cross sections of the tolerance region for each parameter, determines the maximum possible measurement range and its optimal value, and the command of the control unit reports this value to the unit 12 for setting nominal values, as well as based on the data received by the control unit command from the blocks 14 and 15, in accordance with the developed algorithm, determines the optimal tolerances for the parameters of the studied circuit. The nominal value setting unit 12 stops the operation of the entire device for a time which is a multiple of the arrival time of the clock pulses, during which it makes changes to the control unit's program of work, sets the optimum value obtained by previous processing in unit 7, and issues a command to continue the operation of the device. The block 13 for determining the matrix of influence coefficients realizes for each nominal vector of parameters obtained during the processing of two-dimensional sections for each initial random point, the column vector of the coefficients of the influence of the parameters of the studied circuit under the influence of a certain number of sets of random external influences on the studied circuit. The block 14 for determining the coefficient of influence modules realizes the modules of the influence coefficients for each vector of the influence coefficients resulting from the effect on a circuit composed of optimal nominal values of parameters obtained as a result of processing two-dimensional sections for each initial random point, random sets of external impacts. Correlation coefficient matrix determination unit 15 implements, by appropriate processing of the influence coefficient matrices corresponding to each initial random point, the corresponding correlation coefficient matrices.

The solution to the problem of optimizing the parameters of electronic circuits and the tolerances on them in terms of reliability is to make the state vector in the space of the internal parameters of the circuit be located as far as possible from the limits of the loss of efficiency.

The device works in the same way.

After starting the device, the control unit 4, which operates according to a predetermined program, sends a command to the sensor 3 random quanta, which randomly selects a quantum in the range of variation of each parameter. The circuit gives a signal about the coordinates of the initial random point in the block 2 of the realization edge to act. key elements of switching unit 1 to include selected representatives of quanta of internal parameters of the physical model

scheme. The input of the modeling unit 7 from the test signal boostering unit is supplied with a set of nominal values of the input signals, and the monitoring unit 8 and the analyzer 9 implementations, according to the accepted criterion, evaluate the implementation of the circuit for a given set of values of internal parameters. The signal from the analyzer 9 implementations arrives at the control unit 4, which

10 in case of dissatisfaction of the initial random point, the operability condition issues a command to the sensor 3 random quanta to search for a new initial random point, otherwise sends a command to the sensor 3 with the next clock pulses to conduct sequential pairwise random enumeration of the first and second internal quanta parameters of the circuit, and the remaining parameters are represented by their nominal values obtained for the initial random point, which satisfies the conditions of operability. The results of the evaluation of the operability of each situation of pairwise random search and the coordinates of the quanta of parameters involved in the implementation are given out in block 10 for constructing cross sections of the health domain.

0 The two-dimensional section of the health region obtained in this way is transmitted by the control unit command to the computing unit 11 in a form suitable for its operation. The calculator unit 11 enters into each two-dimensional sectional area of health an optimal two-dimensional section of the tolerance area. Parallel with the work of the computing unit, the random search of the quanta of the first and third internal parameters of the circuit, the first and fourth, etc., continues. Thus, a series of optimal two-dimensional sections of the tolerance region with respect to the first parameter is obtained. Computing unit 11 conducts joint testing of the entire series of section, determining the maximum allowable range of the first parameter and its optimal value. Upon receipt of the cross section of the operability area of the first and last parameters, the computing unit 11 stops the operation of the device until the issue

5 of the optimal value of the 5–5th value of the first parameter for the first initial random point, which satisfies the working conditions. At the end of the processing of a series of sections by the command of the control unit 4, this value is communicated to the nominal value setting unit 12. Block 12 converts the quantum number corresponding to the optimal value of the first parameter into a form convenient for the 5

The operation of the program of the block 4 of the board, and blocks the operation of the device during its work and turn on the representative of the quantum of the first parameter corresponding to a certain nominal value. Then issues a command to continue the operation of the device. In a similar way, the second internal parameter of the circuit is searched with all the others except the first one, and its optimal value is determined, then the third one with all the others except the first and second parameters, etc. Upon completion of a random enumeration of all parameters for the first initial random point, satisfying the operating conditions, and finding the optimal values of the parameters of the investigated block, the control unit issues a command to randomly search external influences, having previously blocked the search for the next random point for a time multiple of the clock pulse arrival period, and by giving permission to issue optimal but- and minal values in block 13 for determining the matrix of influence coefficients, where random combinations of external their impact with the clock generator 5. The data on the obtained matrix of influence coefficients by the control unit 4 signal goes to the determination coefficient modulus determination unit 14 to the correlation coefficient matrix determination unit 15, from which the information from the control control unit 4 in a form convenient for subsequent work goes to the computing unit 11 where the optimal tolerances for the parameters of the circuit are determined for the first initial random point.

Similarly, the device operates when searching for the following random source / points, after which the computing unit 11 selects the best vectors and tolerances for them from the series and produces its printing.

Claims (2)

Invention Formula A device for conducting matrix tests of electronic circuits containing a control unit whose output is connected to the first inputs of a random number sensor, blocks for generating test signals, modeling, monitoring, building sections of the health region, a computing unit and a unit for setting nominal values connected to the first output control unit input and other inputs to the output of the computing unit and the first output of the clock generator, the second and third outputs of which are connected s, respectively, with one input of the switching unit connected by another input through the search implementation block to the first output of the random number sensor, and the second input of the control unit, the third input of which is connected to one output of the implementation analyzer, connected to the output of the control unit and the other output to the second the input of the construction block of the working area, the output of which is connected to the second input of the computing unit, and the output of the switching unit is connected to the second input of the modeling unit connected an output with a second input of the control unit and a third input with one output of the test signal generating unit; the third input of the control unit is connected to the first output of the clock generator, which, in order to improve the accuracy of the device, contains the correlator matrix drivers and influence and the driver of the modules of the coefficients of influence connected by the output to the third input of the computing unit and the inputs to the output of the control unit and one output of the matrix of the coefficients of the influence coefficients The inputs of which are connected to another output of the test signal generation unit connected by the second input to the second output of the random number sensor, the output of the control unit and the other output of the nominal value setting unit, and the other output of the influence coefficient matrix maker connected via the correlation coefficient maker connected another input to the output of the control unit, to the fourth input of the computational unit. Sources of information,. taken into account in the examination 1, USSR author's certificate No. 516048, cl. G About F, 07.0,7 2. USSR Author's Certificate for Application No. 2630041/24, cl. G Obr, 06/15/78 (prototype).