RU2009518C1 - Method of checking quality of contact of outputs of kmos-lsi and device for realization - Google Patents

Abstract

FIELD: electric engineering. SUBSTANCE: checking of quality of contact is performed by means of application of specific current pulse sequence to specific outputs of object under testing. To detect outputs of KMOS-LSI which have no contacts the output of voltage/current converter which is connected to output which connects voltage of object under control. Current pulses are applied in such a manner that ordinal number of the pulse should correspond to number of output. Device for checking quality of contacts of outputs of KMOS-LSI has control unit 1, multichannel control unit 2, commutation unit 3, reference levels source 4, power supply 5, commutation member 6, registration unit 7, voltage/current converter 8. EFFECT: improved reliability of operation. 4 dwg

Description

 The invention relates to a control and testing technique and can be used to verify contact during monitoring CMOS-BIS.

 Currently, large integrated circuits (LSIs) tend to increase the number of external terminals (48, 56, 64 or more) and reduce the step between the terminals from 2.5 and 1.25 to 0.625 mm, which makes increased demands on the contact node of the object control in terms of its reliability, and contact verification becomes an urgent task.

 A device for controlling the contacting of integrated circuits containing a control unit, a switch, a power source, an analog-to-digital converter, a code converter. The monitoring principle is based on the analysis of the voltage drop during current flowing through the measuring resistor, for which each control channel has an additional switch for connecting an analog-to-digital converter in addition to the measuring resistor. The disadvantage of this device is its complexity, due to the need for analog-to-digital conversion, the use of measuring resistors and switches to compare the control result with the standard.

 A device is known for monitoring the contacting of the outputs of electronic blocks, containing a series of contact heads with a pair of contacts on each contact pad of the test object, the disadvantage of this device is the high complexity of the contact node, since it is necessary to ensure the flow of current due to double contacting, and this is for control objects with a large number conclusions and a small step between them is very difficult.

 The closest technical solution is an LSI monitoring device containing a control unit, terminals for connecting the terminals of the monitoring object and an N-channel (by the number of signal outputs) control unit. The known device allows you to control LSI in two modes: contact control and the actual LSI control. In the contact monitoring mode, the presence of a semiconductor junction between each of the LSI outputs and the common bus is checked; the presence of this junction is classified by the device as the presence of contact. The disadvantage of this device is the complexity of the multi-channel control unit, since in each control channel it is required, in addition to current generators, the introduction of additional keys and logic elements, and this complicates the implementation of the contact control mode in the existing control equipment.

 The purpose of the invention is to simplify the implementation of contact verification, it is achieved by the fact that the power output of the CMOS-BIS is connected to the current-voltage converter, the test current is supplied in the form of a pulse supplied to each signal output with a relative shift of the position of the pulse in time depending on the order of the signal numbers conclusions, and as an informative signal choose a sequence of pulses taken from the output of the current-voltage converter, which is compared with the reference sequence In which the number of pulses equal to the number of signal pins CMOS LSI with incomparably missing sequence number in the controlled pulse sequence used to identify the noncontacting output numbers.

 The proposed technical solution uses the properties of the CMOS-BIS structure, in which there are protective diodes on the signal (inputs and outputs) outputs.

 The practical implementation of the proposed technical solution is easier in relation to the known, since it does not require refinement of the multi-channel control unit. In the known technical solutions, features other than the prototype are not found, which allows us to conclude that the proposed device has significant differences.

 The set of essential features of the proposed solution, when implemented, will achieve a positive effect - the ability to implement the contact verification phase during CMOS-LSI monitoring at a lower cost.

 In FIG. 1 shows a functional diagram of a device that implements the proposed control method; in FIG. 2 - a preferred embodiment of the main functional blocks and the device itself; in FIG. 3 is a timing chart explaining the operation of the device; in FIG. 4 - the algorithm of the device at the stage of contact verification.

 A device that implements the proposed CMOS-BIS contact control method comprises a control unit 1, a multi-channel control unit 2, a connection unit 3, a source of 4 reference levels, a power source 5, a switching element 6, a recording unit 7, a current-voltage converter 8. The control unit 1 controls its first group of information outputs, the first input and the first output respectively connected to the first group of information inputs, the output and input of the multi-channel control unit 2, the second group of information outputs is connected to the second group of information inputs of the multi-channel control unit 2 and the group of signal inputs of node 3 connectivity. The source of 4 reference levels by its group of reference signals is connected to the third group of inputs of the multi-channel control unit 2, the output of the reference signal is connected to the third input of the control unit 1, and the input is connected to the first output of the power supply 5, the first input of the connection unit 3, the first input of the current converter 8 -voltage and the third input of block 7 registration. The switching element 6 by a common contact is connected to the second input of the connection unit 3, the closed contact is connected to the second output of the power supply 5, the open contact is connected to the second input of the current-voltage converter 8, and the control input is connected to the third output of the control unit 1, the second input, the first and the second output of which is connected respectively to the output, the first and second input of the registration unit 7, the fourth input of which is connected to the output of the current-voltage converter 8. The control unit 1 contains a programming unit 13, including fifteen switching elements 14, each of which contains a key 15 and a load resistor 16, the outputs of which are connected to the output of the switching element 14, and the inputs are separately connected to the first 17 and second 18 buses of the programming unit 13, generator 19, first 20 and second 21 switching units, first 22 and second 23 standby multivibrators, first 24, second 25, third 26 and fourth 27 inverters, first 28 and second 29 indicator, first 30 and second 31 element AND, element 32 AND -NOT counter 33, delay element 34, the first 35, second 36 and third 37 block of the storage device, trigger 38, first 39 and second 40 register, multiplexer 41, block 42 shapers, including N shapers 43 signals, the outputs of which are the second group of information outputs of the control unit 1, and each shaper 43 the signal contains the first 44 and second 45 AND-NOT element, the first inputs of which are connected to the first input of the signal shaper 43, the second input of the first 44 AND-NOT element is the second input of the signal shaper 43 and connected to the second input of the second through the inverter 46 about 45 of the AND-NOT element, the output of which is the output of the signal former 43 and connected to the collector of the transistor 47, the emitter of which is connected through the first 48 resistor to the third input of the signal former 43, the third input of the control unit 1 and the first output of the second 49 resistor, and the base is with the second output of the second 49 resistor and through the third 50 resistor - with the output of the first 44 element AND NOT.

 The installation input of trigger 38 is connected to the first output of the first 22 waiting multivibrator, the first zeroing input - to the output of the second 23 waiting multivibrator, the first input of the first 30 And elements and the zeroing inputs of the first 39 and second 40 registers, the second zeroing input - with the output of the 32 And - element NOT, the third nulling input - with the first input of the control unit 1, the fourth nulling input - with the second input of the first 30 AND elements and the first output of the counter 33, and the output - with the input of the first 28 indicator and the first input of the second 31 And elements, the second input of which connected to the output of the first 20 switching unit, and the output to the input of the delay element 34 and the counting input of the counter 33, the installation input of which is connected to the output of the first 30 of the And element, the group of data inputs is connected to the output of the first 14-7 group of switching elements, and the second the output is connected to the input of the second 29 indicator and the first input of the second 21 switching unit, the second input of which is connected to the output of the second 14-8 group of switching elements, the third input is connected to the output of the first 14-6 switching element and through the third 26 inverter is connected to even The second input of the second 21 switching unit, the output of which is connected to the address inputs of the first 35, second 36, and third 37 blocks of the storage device, the RECORD-READ inputs of which are connected to the output of the second 25 inverter, the input of which is connected to the output of the second 14-5 switching element, outputs the third 14-9, the fourth 14-11 and the fifth 14-14 switching elements are connected respectively to the sampling inputs of the first 35, second 36 and third 37 blocks of the storage device, the information outputs of the first 35 and third 37 blocks of the storage device under lyucheny respectively to the data inputs of the first 39 and second register 40, 37 sample the output of the third storage device 27 via the fourth inverter connected to the first input of the AND-32.

 The information outputs of the second 36 block of the storage device are connected to the first group of data inputs of the multiplexer 41, the second group of data inputs of which is connected to the high logic level bus 60, the gating input to the output of the sixth 14-12 switching element, and the outputs to the first inputs of signal shapers 43 the second inputs of which are connected to the outputs of the first 39 registers and to the first group of information outputs of the control unit 1, the third output of which is the output of the seventh 14-15 switching element, the outputs of the eighth 14-13, nine of that 14-3, tenth 14-2 and eleventh 14-1 switching elements are connected respectively to the data input of the third 37 block of the storage device, the input of the second 23 waiting multivibrator, the input of the first 22 waiting multivibrator and the input of the first 24 inverter, the output of which is connected to the first input of the first 20 of the switching unit, the second input of which is connected to the output of the generator 19, the third input is connected to the second output of the first 22 standby multivibrator, and the fourth input is connected to the output of the eleventh 14-1 switching element.

 The outputs of the third 14-10 and fourth 14-4 groups of switching elements are connected respectively to the data inputs of the second 36 and first 35 block of the storage device.

 The second input and second output of the control unit 1 are connected respectively to the second input of the AND-NOT element 32 and the output of the second 40 register.

 In control unit 1, the programming unit 13 can be made, for example, in the form of a dial-up field of toggle switches, it is preferable to perform it as a terminal communication node with a control computer, in this case, microchips with an open collector can be used as keys 15, and the value of the load resistor 16 about 1 kOhm is selected. The first 17 and second 18 buses are respectively low and high logic level buses.

 As a generator 19 can be used, for example, a chip 119 GG1, with pick-up resistors and capacitors to form a frequency of the order of hundreds of kilohertz. As the first 22 and second 23 standby multivibrator and delay element 34, for example, AG3 microcircuit 133 can be used. As the first 28 and second 29 indicators, for example, LEDs of the AL 307B type with a key transistor of the KT201A type at the input can be used. In the first 35, second 36 and third 37 block of the storage device can be used chips 541 RU1. As the multiplexer 41 can be used microcircuit type 533 KP13.

 In the driver 43 of the signals as a transistor 47, it is preferable to use a high-frequency transistor, for example, CT 361G. The remaining blocks and elements of the control unit 1 can be performed on typical circuits of the series 133 and 533. 1 The multi-channel control unit 2 contains N control units 51, a delay element 58, and an OR element 59, which acts as a wired OR and equipped with a control input connected to the first output of the element 58 delays for gating the output of information from the output of the OR element 59 connected to the output of the multi-channel control unit 2.

 Each control unit 51 includes a first 52 and a second 53 comparators, an inverter 54, a switching unit 55, a D-flip-flop 56 and an indicator 57, the input of which is connected to the output of the D-flip-flop 56 and the output of the control unit 51, which make up the group of information inputs of the element 59 OR .

 The gate input of the D-flip-flop 56 is the input of the control unit 51 and is connected to the second output of the delay element 58, the input of which is connected to the input of the multi-channel control unit 2.

 The D-input of the D-flip-flop 56 is connected to the output of the switching unit 55, the first and second inputs of which are connected to the outputs of the first 52 and second 53 comparators, and the third and fourth inputs are connected respectively to the output and input of the inverter 54.

 The input of the inverter 54 is the control and constitutes the first group, the first inputs of the first 52 and second 53 comparators are combined and make up the second group, and the second inputs of the first 52 and second 53 comparators are the third group of inputs of the multi-channel control unit 2.

 The implementation of the multi-channel control unit 2 is equivalent to a technical solution. The connection node 3 to the CMOS-LSI has a fixed mechanism, in one position of which the conclusions of the CMOS-LSI in the satellite packaging are set to the contacts, and in the other they are pressed to them. CMOS-LSI can be of various combinations that are part of a set (series) of structural units with the same connecting dimensions, numbers of power leads and the maximum total number of signal leads (arbitrarily distributed inputs and outputs) equal to N.

 As a source of 4 reference levels and a power source 5 can be used standard programmable power sources, for example, B5-47. As a switching element 6, for example, a typical electromagnetic relay can be used.

 The registration unit 7 serves to compare the informative signal P (I) with the reference Rat (I) and record the result in the form of a GODEN-BRAC and contains an indicator 9, a delay element 10, an NAND element 11 and a multiplexer 12 with a memory, the output of which is connected to indicator 9, and the first, second, third and fourth inputs are connected respectively to the output of the delay element 10, the first input of the AND-NOT element 11, the output of the 11 AND-element and the third input of the registration unit 7, the first, second and fourth inputs of which are connected respectively, to the input of the delay element 10, the second input of multiplexer 12 with memory and the second input of element 11 AND NOT, and the output is connected to the output of multiplexer 12 with memory. Typical microcircuits of series 133 and 533 can be used as elements 10, 11 and multiplexer 12 of registration unit 7, and indicator 11 can be made on the basis of an AL 307B LED with a key transistor of type KT 201A at the input.

 The current-voltage converter 8 acts as a current-voltage converter and can be made in the form of a typical variable resistor, included as a potentiometer, the preferred resistance value of which is about 1-3 kOhm, the potentiometer engine is regulated so that the output level of the converter 8 is an informative the signal was 10-15% higher than the response threshold of typical TTL-microcircuits, this condition is necessary for pairing the informative signal taken from the output of converter 8 with the input 7 registration unit.

 The control device CMOS-BIS operates as follows.

 Before monitoring the CMOS-LSI, its contact with the CMOS-LSI connecting node 3 is checked, for which purpose, in the control unit 1, the STOP command sets the initial state and the initial load address of the memory resources I = 2N, where: N is the number of outputs of the CMOS-LSI, Fig. 2, FIG. 5.

 The control input of the switching element 6 from the control unit 1 receives a signal through which the CMOS-LSI power output connected to the second input of the CMOS-LSI connecting node 3 is disconnected from the power supply 5 and connected to the second input of the current-voltage converter 8.

 Then, the control Pk (I) and the reference Rat (I) information are recorded in 2N memory resource addresses of the control unit 1, for which operation I - 1 is performed, and when the value is I = 0, the download stops. The code pattern form of the recorded information Pk (I) and Rat (I) is shown in FIG. 4, at the same time the logical “0” information is written to even addresses - the logical “1” information for those N pin numbers that are subject to control, for the pin numbers that are not subject to control (power leads, idle), the logical “ 0 ", this recording order ensures during monitoring the receipt at the output of the converter 8 of an informative signal P (I) in the form of a sequence of N pulses and eliminates the rejection of conclusions that are not subject to control.

 After loading the memory resources in the control unit 1, a signal is sampled of the CMOS-BIS signal outputs as inputs, i.e., the group of signal inputs of the connection unit 3 becomes receivers of signal information Pk (I).

 According to the START command generated in the control unit 1, the memory resource address counter starts operation I - 1 from the initial address I = 2N, while the signal outputs of the CMOS-LSI begin to receive pulse signals from the second group of outputs of the control unit 1 with a relative position offset pulse in time depending on the arrangement of the numbers of signal terminals. From the source of 4 reference levels, the reference voltage level is supplied to the third input of the control unit 1, which forms the upper level of the pulse signals supplied to the CMOS-BIS signal outputs, and the reference levels supplied to the third group of inputs of the multi-channel control unit 2 serve to form reference comparing levels that provides control of low and high levels, supplied by pulse signals to CMOS-LSI at each step of operation I - 1.

 Since the inputs of the current-voltage converter 8 using the switching element 6 are connected to the power output of the CMOS-BIS, then the output of the current-voltage converter 8 during the entire duration of operation I - 1 to the value I = 0 will see a sequence of pulses P (I ), which in block 7 of registration will be compared with the reference sequence Rat (I) coming from the second output of control unit 1, in which the number of pulses is equal to the number of signal outputs of the CMOS-LSI, in case of violation of the contacting of the signal outputs of the CM OP-BIS the number of pulses in the sequence P (I) will decrease by the number of non-contacting outputs, while in the registration unit 7 the BRAC command is generated, which is transmitted from its output to the second input of the control unit 1, to form a stop in it and display the current address of the address counter memory resources.

, где: I - номер адреса останова счетчика.The number of non-contact output is determined using the expression N =

where: I is the number of the stop address of the counter.

 If the cause of non-contact can be eliminated, for example, contamination of the contacts of the connection node 3, insufficient clamping of the CMOS-BIS terminals, etc., then the verification of the contact monitoring stage can be repeated, for which, after eliminating the non-contact, the starting address I is set to = 2N, and then the START command is generated, upon successful verification, the counter stop address number should be I = 0, which indicates the presence of CMOS-LSI contact and the possibility of switching to the CMOS control mode itself EC. In this case, the switching element 6 using the control unit 1 is set to the initial state, in which the output of the power supply 5 through the closed contacts of the switching element 6 is connected to the second input of the connection unit 3.

 Using the proposed technical solution in relation to the known does not require the introduction into each channel of a multichannel unit 2 of the control of the current generator, key and logic elements. By introducing the switching element 6, the registration unit 7, and the current-voltage converter 8, as well as arranging the supply of pulse signals to the CMOS-BIS signal outputs and analyzing the informative signal on its power bus using the current-voltage converter 8, non-contact conclusions are determined.

 The economic effect is achieved by reducing the cost of manufacturing control equipment during the implementation of the monitoring of contacting the conclusions of CMOS-BIS. (56) Copyright certificate of the USSR N 1550444, cl. G 01 G 31/28, 1990.

 USSR author's certificate N 1193608, cl. G 01 R 31/28, 1985.

Claims (4)

 1. CMOS-BIS contact control method, according to which the signal outputs are selected as inputs, they are connected to current generators, a test current is supplied, the informative signal on the signal outputs is compared with reference reference levels, contact identification is made, characterized in that the output CMOS-BIS power supply is connected to the current-voltage converter, the test current is supplied in the form of a pulse supplied to each signal output with a relative offset of the pulse position in time, depending on the order of the numbers of the signal outputs, and as an informative signal, a sequence of pulses taken from the output of the current-voltage converter is selected, which is compared with a reference sequence in which the number of pulses is equal to the number of signal outputs of the CMOS-BIS, if the sequence number is absent a controlled pulse sequence is used to identify the number of non-contact output.  2. A device for controlling contacting CMOS-BIS, containing a control unit, a first group of information outputs, the first input and the first output of which are connected respectively to the first group of information inputs, the output and input of the multi-channel control unit, the connection node, the group of signal inputs of which is connected to the second the group of information outputs of the control unit and the second group of information inputs of the multi-channel control unit, the source of reference levels, the group of outputs of the reference signals of which is connected to to a group of inputs of a multi-channel control unit, the output of the reference signal is connected to the third input of the control unit, and the input is connected to the first output of the power source and the first input of the connection unit, characterized in that, in order to simplify the implementation of the contact check, a switching element, a converter are introduced into it current - voltage and registration unit, output, the first and second inputs of which are connected respectively to the second input, the first and second output of the control unit, the third input is connected to the first input of the conversion Firing current - voltage with the first output of the power source, and the fourth input - with the output of the current-voltage converter, the second input of which is connected to the open contact of the switching element, and the control input of the switching element is connected to the third output of the control unit, and the common and closed contacts are connected respectively, to the second input of the connection node and the second output of the power source.  3. The device according to p. 2, characterized in that the registration unit contains an indicator, a delay element, an AND element - NOT, and a multiplexer with a memory, the output of which is connected to the indicator input, and the first, second, third and fourth inputs are connected respectively to the element output delay, the first input of the AND element is NOT, the output of the AND element is NOT and the third input of the registration unit, the first, second and fourth inputs of which are connected respectively to the input of the delay element, the second input of the multiplexer with memory and the second input of the AND element is NOT, and the output is union of a yield multiplexer with memory.  4. The device according to claim 2, characterized in that the control unit comprises a programming unit including fifteen switching elements, each of which contains a key and a load resistor, the outputs of which are connected to the output of the switching element, and the inputs are separately connected to the first and second buses programming unit, generator, two switching units, two standby multivibrators, four inverters, two indicators, two AND elements, AND element - NOT, counter, delay element, three memory units, trigger, two registers, multipl Xor and a shaper unit, including N signal conditioners, the outputs of which are the second group of information outputs of the control unit, each signal conditioner contains the first and second element AND - NOT, the first inputs of which are connected to the first input of the signal conditioner, the second input of the first element AND - NOT is the second input of the signal conditioner and through an inverter is connected to the second input of the second element AND is NOT, the output of which is the output of the signal conditioner and connected to the collector of the transistor, the emitter through the first resistor is connected to the third input of the signal conditioner, the third input of the control unit and the first output of the second resistor, and the base is connected to the second output of the second resistor and through the third resistor to the output of the first element AND is NOT, moreover, the trigger input is connected to the first output the first waiting multivibrator, the first zeroing input - with the output of the second waiting multivibrator, the first input of the first AND element and the zeroing inputs of the first and second register, the second zeroing input - with the output of the AND element - NOT , the third nulling input - with the first input of the control unit, the fourth nulling input - with the second input of the first AND element and the first output of the counter, and the output - with the input of the first indicator and the first input of the second And element, the second input of which is connected to the output of the first switching unit, and the output - with the input of the delay element and the counting input of the counter, the installation input of which is connected to the output of the first element And, the group of data inputs is connected to the output of the first group of switching elements, and the second output is connected to the input of the second indicator and the first input of the second switching unit, the second input of which is connected to the output of the second group of switching elements, the third input is connected to the output of the first switching element and through the third inverter is connected to the fourth input of the second switching unit, the output of which is connected to the address inputs of the first, second and third storage units, the control inputs of which are connected to the output of the second inverter, the input of which is connected to the output of the second switching element, the outputs of the third, fourth and fifth elements of comm utilities are connected respectively to the sampling inputs of the first, second and third memory blocks, information outputs of the first and third memory blocks are connected respectively to the data inputs of the first and second registers, the sampling input of the third memory block is connected through the fourth inverter to the first input of AND - NOT , the information outputs of the second block of the storage device are connected to the first group of data inputs of the multiplexer, the second group of data inputs of which are connected on the bus of a high logic level, the gate input to the gate inputs of the first and second registers, the output of the delay element and the first output of the control unit, the control input to the output of the sixth switching element, and the outputs to the first inputs of signal conditioners, the second inputs of which are connected to the outputs of the first register and the first group of information outputs of the control unit, the third output of which is the output of the seventh switching element, the outputs of the eighth, ninth, tenth and eleventh switching elements are connected respectively to the data input of the third block of the storage device, the input of the second standby multivibrator, the input of the first standby multivibrator and the input of the first inverter, the output of which is connected to the first input of the first switching unit, the second input of which is connected to the output of the generator, the third input is connected to the second output of the first standby multivibrator, and the fourth input is connected to the output of the eleventh switching element, the outputs of the third and fourth group of switching elements are connected respectively to the data inputs the second and first block of the storage device, and the second input and second output of the control unit are connected respectively to the second input of the AND element - NOT and the output of the second register.

Images