SU851414A1 - Device for carrying out of microelectronic circuit matrix tests - Google Patents

Description

(54) DEVICE FOR CARRYING OUT MATRIX TESTS OF MICROELECTRONIC CIRCUITS

one

The invention relates to automation and computing technology and is intended to study and optimize the parameters of the microcircuits and the tolerances on them according to the criterion of the percentage of the output of the microcircuits of any instantaneous circuits in the static mode.

Devices are known for conducting matrix tests of electronic circuits.

Matrix tests in these devices are aimed at determining the quantitative characteristics of the parametric reliability of the devices under study, determining two-dimensional sections of the health region, optimal sections of the tolerance region, the maximum possible ranges of variation of each parameter, their optimum values, and fixing these values in a physical model.

PI and G23.

The disadvantages of these devices are the lack of analysis of the intermediate results of the matrix tests and the lack of optimization of the internal parameters of the studied circuits, as well as lack of accuracy due to the possibility of studying the effect on output parameters /

Schemes of simultaneous change of only two parameters of components. Under actual conditions, the deviations of the output parameters of the circuit are a function of the simultaneous change of all the parameters of the components. In addition, this device does not take into account the laws of distribution of input and output parameters, the correction links between component parameters that always exist for integrated circuits, as well as the degree of influence of deviation of each input parameter on output parameters.

The closest to the present invention is a device containing a control unit, the output is cheaply connected to the control inputs of the sensor of random numbers, blocks for generating test signals, modeling, monitoring, building sections of the health area of computing blocks, drives,

The 25 elements And, of the nominal value setting unit and the parameter-effect detector, the first input of which is connected to the first output of the clock, the remaining outputs of which are connected to

thirty

the first inputs of the switching, monitoring and setting of nominal values, the second input of the switching unit is connected to the output of the implementation enumeration unit whose input is connected to the output of a random number sensor, the output of the switching unit is connected to the first input of the modeling unit, the second input of which is connected to the output of the unit forming test signals, and the output - with the second input of the control unit, the output of which is connected to the input of the implementation analyzer, the first output of which is connected to the input of the building section block of the operable area connected via the output of the first computing unit to the second input of the nominal value setting unit connected by the outputs to the second input of the control unit and the parameter influence detector associated with the output to the first input of the second visualization unit, the second 4} of which connected to the outputs of the accumulators connected by the inputs to the outputs of the element I, the inputs of which and the third input of the control unit are connected, respectively, to the second and the outputs of the unload generator of the WD. :

However, such a device has insufficient speed, since the required number of initial random vectors, for which it is defined. the fulfillment of the conditions of regional sporacity is done and is carried out in pairs. random search of all parameters; to find the nominal values of the parameters, determined by the formula

. l e-1 n hfc

N 2-g7-en -

where n is the number of quantized circuit parameters;

t is the number of quanta into which the range of possible changes of each parameter is broken; (1-ck-) - preset reliability

the fact that the data obtained during tests of the volume N .. would differ from the true ones (i.e., with full enumeration of all combinations of quanta of parameters N) by no more than t

 - The specified test error is excessively large.

In contrast to circuits on discrete elements in integrated circuits, the level of technology determines only the probability that the value of the component parameter falls into a given region for the selected nominal values of the parameters of the circuit components.

Thus, the parameters of the components are random variables whose characteristics can only be given statistically. Therefore, the stage of functional synthesis should be performed by statistical synthesis. The device takes into account the random distributions of the parameters of the individual components and the correlations between them - and their effect on the distribution of the output parameters of the integrated circuits, i.e. their variation from scheme to, allows us to conclude that the requirements for the components may be less stringent and, consequently, the percentage of usable schemes for their production is higher. However, in addition to the aforementioned disadvantage of such a device, consisting in the need to use a large number of initial random vectors, it should be noted that this device also does not take into account the interconnectedness of the nominal parameters of the studied circuits, tolerances on them and the percentage of usable chips .

The purpose of the invention is to increase the speed and accuracy of the device.

The goal is achieved by the fact that a device for conducting matrix tests of microelectronic circuits, containing a control unit connected by a first output to an input of an influence factor determination unit through a random number sensor connected in series, a brute force unit of implementations, a switching unit, a modeling unit, a control unit, an analyzer implementations, the unit forming the sections of the health region, the first computing unit, the unit for setting the nominal values of parameters, the second output of which is connected to n the first input of the control unit, and the second input - with the first output of the pulse generator connected by the second output to the second input of the switching unit, and the third output - to the third input of the control unit connected by the first output to the second input of the modeling unit. forming test signals, the third input of the unit for setting nominal values of parameters, the second input of the first computing unit, the second input of the influence coefficient determination unit, or the second input of the form block of the working area, the first input of the second computing unit, the first inputs of the drives and the first inputs of the matching blocks, the second inputs of which are connected to the second output of the analyzer, and the outputs with the second inputs of the corresponding matching blocks whose outputs are connected to, the second inputs of the second computing unit, connected by the third input to the third input of the control unit and to the first input of the pulse generator, the fourth input to the output of the influence factors determination unit, And the first output is from a quarter in the input of the control unit, the fifth input of WHICH is connected to the third output of the analyzer implementation, a memory block, a setting block, a maximum selection block of ADMISSIBLE realizations, a difference block, a comparison block and a series-connected control are entered. valid implementations counter, comparator, key and block of settings, connected to the second input from the first output of the pulse generator, and output to the sixth input of the control unit, the seventh input of which is connected to the output of the difference block connected by the first input to the first block ca. the maximum allowable implementations, and the second input - with the output of the memory unit connected by the first input to the first output of the control unit, and the second input - to the second output of the maximum selector unit, allow the implementations, the first input of which is divine implementations, and the third output with the second input of the comparator connected by the third input with the second input of the counter of suitable implementations, with the second input of the block for selecting the maximum of allowable realizations and with the first output of the control unit, the comparison unit being the first in odes connected to the output of a random number, the second input - to the second output of the second calculation unit, and outputs - to the inputs of the element J. In the figure is a functional diagram of the proposed device. The device contains a switching unit 1, a brute force block 2 of implementations, a random number sensor 3, a control block 4, a pulse generator 5, a test signal generation block b, a modeling block 7, a control block 8, an implementation analyzer 9, a match block 10, accumulators 11, a block 12 forming sections of the health area, the first computing unit 13, the unit 14 for setting nominal values of parameters, the unit 15 for determining the coefficients of the ali and the second computing unit 16, the comparison units 17, element 18, counter 19 are realizable, com: parator 20, memory block 21, key 22, setting block 23, block 24 for selecting the maximum of allowable realizations, difference block 25. Switching unit 1 represents a group of key elements, both representatives of quanta of quanta of the studied elements of the physical model 7 and controlled by the brute force block 2 of implementations, Block 2 of the brute force implements to control the switching keys. The random number sensor 3 serves to find the required number of initial random vectors distributed according to a uniform law and satisfying the operating conditions on a command from the control unit to conduct a successive pairwise random search of a pair of physical models of the block 7 for the initial random vector, for the formation of random vectors having the specified mathematical Dani's life expectancy corresponding to the components of the initial random vector, the variance and the coefficient correlation coefficients and distributed according to given distribution laws. The control unit 4 through the sensor 3 random quanta controls the unit for enumeration of realizations, find the required number of initial random points that satisfy the conditions of operability, and, conducting a consecutive pairwise search of the parameters of the physical model, examine my circuit of unit 7 for each initial random point , issues to the block 12 of the formation of the sectioned area of health, the current numbers of parameters and their quanta participating in the enumeration, at the command of the unit 14 for the installation of nominal values of parameters includes the corresponding The current quantum number of the parameter of the physical model of the circuit provides in the block 15 for determining the coefficients of the influence the nominal values of the parameters of the components obtained for each initial random vector that satisfies the conditions of operability, and in the second computing unit 16 the data from the accumulators 11 to determine the distribution law of the output parameter, issues a command to the sensor 3 random numbers to form random normally distributed vectors with correlated components, allows the issuance of certain in the second computational block, 16 limits of nag tolerances, the first whops of the corresponding coincidence schemes, on his command, the data from the output of the valid implementations counter go to the inputs of the comparator 20 and the maximum allowable realizations selection unit 24, allows the signal from the comparator 20 to enter the key 22, the signals from the block 24 selection of the maximum allowable realizations in the memory block 21 and the difference block 25, as well as the signal from the memory block 21 in

block 25 of the difference and coordinates the work of the other blocks,

The clock pulse generator 5 is used to synchronize the switching unit 1, the control unit 8, the nominal parameter setting unit 14, the second computing unit 16 and the setting unit 23 with the control unit according to a predetermined

rhythm

A BLOCK B of forming test signals generates a complex of input signals for each particular physical model.

The modeling unit 7 is designed as a board on which the quanta outputs of the simulated parameters of the studied circuit are connected sequentially with contacts of the corresponding key elements of the switching unit 1 with initial ranges of variation that determine the limits of the cross sections 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, it determines whether it is operational or not in accordance with the selected performance criteria. The co-fall units 10, represented in an amount determined by a given number of output deviation levels, cover the entire possible range of variation of this output signal — in digital equivalent.

Drives 11 are designed to accumulate the number of implementations in which the value of the output signal (in digital equivalent) coincides with the setting of the corresponding block 10.

The section 12 of the formation of the section of the health area according to the data of the control unit 4 and the analyzer 9 implementations receives a section of the health area for each pair of parameters, converts this information into a form convenient for subsequent work, and issues it to the first computational unit 13 at the command of the control unit.

The computing unit 13 inserts in each section of the working area the optimal section to the starting area, processes a series of the received sections of the starting area for each parameter, determines the maximum possible range of change and its optimal value, and reports the value to the unit 14, ning values of parameters.

Block 14 stops the operation of the entire device for a time that is multiple to the period of arrival of the clock pulses, during which it makes changes to the program of operation of the control unit, sets in block 7-5 the resulting value of the previous processing, and issues a command to continue the operation of the device. The parameter influence determination unit 15 on the basis of the nominal values of the circuit parameters issued by the control unit for each of the initial random vectors satisfying the operability conditions, determines the influence coefficients of the corresponding parameters and converts them into a form suitable for subsequent operation. work.

The second computing unit 16,

where by the control unit signal

the values of the influence coefficients and data from the accumulators are received, determines the law of distribution of the output parameter and, using CJH information about the laws of the distribution of input parameters and correlations between them, determines the optimal tolerances on the parameters of elements for the initial random vector, i.e. . The boundaries of permissible values for each of the parameters of the circuit under study, which, after a signal from control unit 4, arrive at the first inputs of the respective comparison units 17, and 5 determine the standard deviations of the components of each initial random vector based on the known coefficient of variation. Then it stops the operation of the device for a time that is a multiple of the period of arrival of the clock pulses, during which it makes changes to the program of operation of the control unit 4. and issues a command to continue the operation of the device.

5 Comparative blocks 17, presented in an amount determined by the number of schelch elds, when the random values of the components of the correlated vectors coincide with the corresponding intervals of permissible values, the corresponding impulses are output.

Element And 18 evaluates each implementation and in the case of signals on all its inputs produces a pulse arriving at the counter 19 suitable implementations.

The counter 19 of valid implementations is designed to accumulate the number of implementations in which the aggregate of random values of the corresponding components of each initial random vector (in the digital equivalent) coincide with the corresponding limits of permissible intervals

the values of the comparison blocks 17, which it transmits to the nomparator 20 and the block 24 for the selection of the maximum of allowable realizations on command from the control block 4.

The comparator 20 compares the current value of the number of valid implementations of the UE (percentage of suitable microcircuits) with some predetermined (lower allowable) threshold and, in case of a positive difference, outputs a signal from the control unit 4 to the key 22.

The memory unit 21 serves to store the lower allowable value of the number of suitable implementations and the subsequent values after each next step of reducing the ranges of allowable values of the parameters of the studied circuit, which are received by the signal from the control unit 4 from the maximum suitable selections unit 24. The command of control unit 4 transmits to difference unit 25.

Key 22 has the number of inputs and outputs, corresponding to the number of parameters of the circuit under study. When a signal appears at its control input, it skips the signals that it receives from block 14 of setting the nominal values of parameters to the inputs of block 23 of the set limits of acceptable values.

Block 23 of the setpoints of permissible values is a logical block with the number of pairs of states corresponding to the number of parameters of the circuit under study. Each pair of states characterizes the lower and upper limits of the permissible values of one pargshetra. The components of the first initial random vector, arriving at its inputs, overturn both its borders to the position, in numerical equivalent, to the corresponding nominal value of each parameter of the studied c & ma. The components of the second random vector overturn one of each pair of its boundaries, with the left (lower) or right (upper) depending on whether the corresponding component of the second initial random vector is smaller or larger than the corresponding component of the first initial random vector. The components of each successive random vector vector will overturn one of its corresponding boundaries only if they are either less than the corresponding lower or greater than the corresponding upper bound, obtained after the arrival of the corresponding components of the first two initial random vectors. Then the block 23 of the set limits of acceptable values stops the operation of the entire device on

the time, multiple to the period of arrival of clock pulses, during which it makes changes to the work program of control unit 4, sets new limits for permissible parameter changes obtained as a result of the previous step, and issues a command to continue operation of the device.

The maximum allowable realizations selection unit 24 has, at its first and second outputs, a signal, in digital equivalent, equal to the lower permissible value of the number of valid implementations, which after each step of the matrix tests, concludes with discarding the set of initial random vectors, is replaced by the maximum number of valid realizations, obtained for one of these vectors, which is transmitted to control unit 21 by the signal from control unit 4 and set as a threshold for supplying to unit 25 different STI, and a comparator 20.

Difference unit 25 compares the values obtained during the next step of the matrix tests, the maximum number of valid implementations with the maximum number of valid implementations in the previous step.

0 and in the case when this difference is greater than some predetermined number of valid implementations, issues a command to carry out the next step of the matrix tests, otherwise

5 issues a command to stop the operation of the device and allows printing of vector components (nominal values) and tolerances on them of the vector, which in the current step gives a maximum

0 the number of suitable implementations. ,

The device works as follows.

After the device is started up, the control unit 4, which works according to a given program, issues a command to the sensor

5 3 random numbers, which randomly selects quanta in the corresponding initial range of each parameter, scheol, allows the issuance of signals about the coordinates of the first

O accidental vector in block 2 of enumeration of re-detection for triggering the corresponding key elements of switching unit 1 to include selected representatives of quanta of internal

5 parameters of the physical model of the scheme in block 7 modeling. A set of input signals is input to the input physical model of the circuit and block of formation of test signals, and block 8 of the control and analyzer of the 9 implementations, in accordance with the specified restrictions on the output parameters of the circuit, evaluates the implementation (performance of the circuit with a given set of internal values).

THEM parameters). The signal from the analyzer 9 implementations enters the control unit 4, which, if the first random vector does not satisfy the conditions, sends a command to the random number sensor 3 to select the next random vector, otherwise gives the sensor 3 random numbers permission with the arrival of the clock pulses sequential pairwise random enumeration of the quanta of the first and second internal parameters of the circuit, the remaining parameters being represented by their nominal values, is -expandable random vector coordinates, satisfied the conditions of efficiency.

The control unit 4 gives permission for parallel reading of the results of evaluating the health of each situation in a pairwise random iteration from the analyzer 9 implementations to 10 coincidence blocks, each of which is set to a specific number, numerically equivalent to the corresponding quanta, which is divided into the entire possible range of output parameter variation the tested device. At the output of the And element, in which the number coincides with the 9 implementations from the analyzer, appears a matching feature allowing the addition of one to the drive 11 associated with this element.

The results of the evaluation of the performance of each situation of pairwise random enumeration and the coordinates of the parameters Kvaits participating in the implementation are also displayed in block 12 of the formation of cross sections of the working area. The two-dimensional section of the operability area obtained in this way is transmitted to the first computational unit 13 by a command of the control unit 4 in a form suitable for its operation, and the first computational unit 13 inserts an optimal two-dimensional section of the tolerance region into each two-dimensional section of the operability area. In parallel with the operation of the first illustrative unit 13, the random search of the quanta of the first and third internal parameters of the circuit, the first and fourth, and so on, continues. Thus, we obtain a series of optimal two-dimensional sections of the tolerance-domain with respect to the first parameter. The first computing unit 13 performs joint processing of the entire series of sections and determines the maximum allowable range of the first parameter and its optimum nominal value for this series of sections. Upon receiving the cross section of the operability area of the first and last parameters, the first computational unit 13 stops the operation of the device until the optimal nominal value of the first parameter is issued for the first random vector that satisfies the conditions of operability. After processing the series of sections of the first parameter with the rest by the command of the control unit 4, this value is reported to the parameter setting unit 14, which converts the quantum number corresponding to the optimal value of the first parameter into a form convenient for changing the program of control unit 4 and blocks the operation device at the time of its operation and the time of the representative of the quantum of the first parameter corresponding to a certain nominal value (the blocking time is a multiple of the period received audio clock), then following the receipt of clock pulses gives a command to continue operation of the device.

Similarly, a pairwise random search of the second internal parameter of the circuit with all the others, except the first, is carried out, and its optimal nominal value is determined, then the third with all the others, except the first and second parameters, etc.

Upon completion of the pair random search of all parameters for the first random vector satisfying the operating conditions, and finding the optimal nominal values, the latter, at the command of the control unit 4, arrive at the influence coefficient determination unit 15, where the influence coefficients of each input circuit parameter are on the output parameter and at the command of control unit 4 are transmitted to the second computational unit 16. as a result of all the test cycles for the first random vector, accumulators 11 collect Isla representing a whole-gistoh Rammu, i.e. the differential function of the output signal of the device under test, the information from the accumulators 11 by the signal of the control unit 4 enters the second computational unit 16, which determines the distribution law of the output parameter and, based on the data on the influence factors of the input parameters, the distribution of input parameters and correlation parameters the zone between them determines the optimal tolerances for the circuit parameters for the first random vector that satisfies the working conditions, and based on g nnyh the coefficient of variation determines the standard deviation of the first components of the random vector which arrive in blocks 4, control for changing of its operation program. The control unit 4 outputs 1 Lemand to the sensor 3 random numbers to form random normally distributed vectors with correlated components, and the components of these vectors have specified from the second computational unit: 16 standard deviations and related known correlation coefficients. The signals of random quanta of pars meters from the output of the random number sensor arrive at the first inputs of the respective comparison blocks 17 to the second inputs of which are fed from the second computing unit 16 certain tolerances there, i.e. the value of the boundaries of the intervals of valid values for each of the parameters. When the random value of the parameter coincides with the interval of acceptable values, a signal appears at the output of the corresponding Comparative Blocks 17. In the presence of such signals at all inputs of the element And 18 last generates a pulse arriving at the counter 19 suitable implementations. As a result, a series of tests for the first random vector in the counter of 19 realizations accumulates a certain number, reflecting the percentage of available chips, which in the form convenient for subsequent work, on command from the control unit 4 is fed to the first input of the comparator 20 , to the second input of which a certain predetermined. the initial value of the percentage of the output of the YEAR ICs (valid implementations from the block 24 for the selection of the maximum allowable realizations corresponding to the lower allowable threshold) is received. In the case of a positive difference Between the signals at the first and second inputs of the comparator, the signal that opens the key 22 appears at the output of the last one. The nominal values of the first initial random vector coming from the nominal parameter setting unit 14 pass through the key element to the corresponding inputs of the boundary setpoint block 23 permissible values and overturn the corresponding pairs of states, characterizing its boundaries for each parameter, in the position, corresponding to the numerical equivalent of the nominal values. Comp The second random initial vector overturns one of the pairs of its boundaries, with the left (lower) right or upper (upper) depending on whether the corresponding component of the second initial random vector is smaller or larger than the corresponding component of the first random vector. The data on the nominal values of each subsequent initial random vector with a positive difference in the comparator 20 and the appearance of a signal at the control input of the key 22 pass through the key 22 and overturn one of each pair of its boundaries only if the corresponding components or less lower or greater than the corresponding upper bound obtained after the arrival of the previous vector. After testing M initial case vectors for kg1 of KOTOpfcuc, n implementations were carried out in accordance with the prescribed distribution law of its components, dispersions and correlation coefficients in block 23 of the setpoints of permissible element values, new boundaries are formed, which are already previous . Then, the block 23 of the setpoints of permissible values stops the operation of the entire device for a time multiple of the period of arrival of clock pulses, during which it makes changes to the work program of control unit 4, sets new limits for permissible values of parameters obtained as a result of the last step of the matrix tests, and a command to continue the operation of the device. Along with the formation of new boundaries of permissible values of parameters, the signal from counter 19 suitable realizations for each initial random vector comes in addition to comparator 20 also to the input of block 24 for selection of maximum permissible realizations and overturns it if the subsequent value is greater than the previous one. Then, according to the signal from control block 4, the maximum value of suitable realizations is set as a threshold for the next series of N initial random vectors (the next step of the matrix tests) and fed to the second input of the comparator 20 and simultaneously sent to the difference block 25 and block 21, where the signal From control block 4, the previous threshold value of block 24 for selecting the maximum of allowable realizations is fed to the second input of difference block 25. In case the difference between the signals on the first and second inputs of the difference block 25 is greater than some predetermined number of valid implementations, reflecting the accuracy and error of the matrix tests, the output of the last is the signal at the input of the control unit 4, where with the arrival of the next clock The pulses received during the previous step of the matrix tests are new.

The limits are narrower than the permissible changes in the parameters, and the test cycle of the studied circuit continues. When the difference in block 5 of the difference is less than the predetermined Islamic implementations, at the output of the last one, another signal appears that goes to control block 4 and allows printing of nominal values and tolerances of components of that initial random vector tests gives the highest value of the number of suitable implementations (the percentage of the yield of good chips) and stops the operation of the device.

Thus, the introduction of a device for conducting matrix tests of microelectronic circuits of an element I, a counter of suitable realizations, a comparator, a key, a block of settings, a comparison block, a memory block, a block for selecting the maximum of permissible realizations and a difference block favorably distinguishes the proposed device for conducting matrix tests of microelectronic schemes from the well-known one, because, firstly, it allows reducing the required number of initial random vectors and thereby increasing the device’s performance and, secondly, about It takes into account the uninterrupted connection of nominal values, tolerances on them and the percentage of yield of microcircuits, which is manifested during complex matrix tests, and also allows to obtain an optimal vector of nominal values of parameters of the studied circuit and tolerances on them, which increases the accuracy of the device.

Claims (3)

1. USSR author's certificate number 383510, cl. G 06 F 15/46, 1968. 2. USSR author's certificate number 516048, cl. G 06 F 15/46, 1976. 3. USSR author's certificate according to the application 2630041 / 18-24, cl. G 06 F 15/46, 1978 (prototype.