RU2109329C1 - Digital block diagnosing device - Google Patents

Abstract

FIELD: computer engineering and automatic control; diagnosing radio electronic equipment. SUBSTANCE: device functions to reproduce algorithm for diagnosing digital electronic blocks by computer-aided sequential reduction of dimensionality of range of suspected troubles. Device can operate to handle single particular trouble to confirm its probability or improbability. Device has random-number generator connected to first interface and to standard in the form of electronic model. First interface is connected to diagnostic unit which is connected to second interface. Bit-by-bit comparison unit functions to compare data coming from standard and from second interface. Bit-by-bit comparison unit is connected to first and second registers. First register passes data to control and display units and to simulating unit. Data picked off second register goes to comparison unit which is connected to first register and to random-number generator. Simulating unit is connected to random-number generator. Control unit is connected to first and second registers, comparison and display units. EFFECT: enlarged functional capabilities, reduced diagnosing time, and improved ergonomic characteristics of diagnosing system. 1 dwg

Description

 The invention relates to computer technology and automation and can be used to build tools for monitoring and diagnosing discrete blocks of electronic equipment.

 A device for diagnosing discrete blocks containing a random number generator connected to the diagnosed discrete block and its physical (or software) standard, the outputs of which are connected to the bitwise comparison unit [1].

 The disadvantage of this device is the lack of guarantee that the implemented sequences of test commands constitute a complete diagnostic test, a probabilistic decision about the presence or absence of this malfunction, as well as the high expenditure of resources and time for diagnosis.

 Closest to the technical nature of the proposed device is a device for diagnosing discrete units, containing a power supply, a control unit, a first switch, a comparison and memory unit with an indication, a second switch, a third switch, AND elements, key elements, a decoder, a fourth switch, an encoder , diagnosed circuit, input switching unit, output switching unit, fault simulation unit, reference unit [2].

 The disadvantage of the device [2] is the impossibility of its use for diagnosing other classes of faults, except for breaks and short circuits, as well as significant difficulties when using the device for diagnosing complex discrete circuits.

 The aim of the invention is to expand the functionality of the device, reducing the time of diagnosis and resource costs while maintaining the ability to diagnose any, including multiple faults that have physical meaning, by sequentially excluding them from the list of suspects, improving the ergonomic characteristics of the diagnostic system.

 To solve this problem, the authors propose a device containing a control unit, a first register, a second register, a comparison unit, an information display unit, a fault simulation unit, a reference unit, a first interface device, a second interface device, a random number generator, a bitwise comparison unit, a diagnostic object . The random number generator with its outputs is connected to the first pairing device and the reference unit. The output of the first interface device is connected to the diagnostic object, the output of the diagnosis object is connected to the input of the second interface device, the output of the second interface device is connected to the input of the bitwise comparison unit, the output of the reference unit is connected to the input of the bitwise comparison unit, the outputs of the bitwise comparison unit are connected to the input of the first register and with the input of the second register, the fault simulation unit is connected to the reference unit and the random number generator, the first register is connected to the simulator faults control unit and information display unit, the control unit is connected with its outputs to the first register, second register, comparison unit and information display unit, the second register is connected to the comparison unit by its output, the comparison unit is connected to the random number generator and the first register.

 The device implements an algorithm for diagnosing a digital electronic circuit by sequentially improbable reduction in the dimension of many suspected faults.

 The block diagram of the device shown in the drawing. It contains a control unit 1, a first register 2, a second register 3, a comparison unit 4, an information display unit 6, a fault simulation unit 6, a reference unit 7, a first coupler 8, a second coupler 9, a random number generator 10, a bitwise block 11 comparison, the object of diagnosis 12.

 The control unit 1 is used to submit control commands to the first register 2, the second register 3, comparison unit 4, to the information display device 6.

 The first register 2 is used to store information about probable malfunctions in the diagnostic object 12 and to provide information to the control unit 1 that the entire set of alleged malfunctions has been processed.

 The second register 3 is used to store information about the required number of matches of the output signals received from the reference unit 7 and the diagnostic object, as well as to accumulate information about the number of matches.

 Comparison unit 4 is designed to supply control commands to the random number generator 10 in case the number of matches of the output sequences of the diagnostic object and the reference unit 7 is less than the specified one, and to send control commands to the first register 2 if the number of matches of the output sequences of the diagnostic object 12 and the reference block 7 is greater than the specified.

 The information display unit 5 is intended for issuing information in a user-friendly form about a subset of suspected malfunctions remaining after testing.

 Block 6 simulation of faults is intended for sequential automatic introduction of suspected faults in the reference block 7, information about which is stored in the first register 2.

 The reference unit 7 in the form of an electronic circuit is an electronic analogue of the diagnostic object 12.

 The first pairing device 8 is designed to pair a random number generator 10 and a diagnostic object 12.

 The second pairing device 9 is intended for pairing the diagnostic object 12 and the bitwise comparison unit 11.

 The random number generator 10 is intended for issuing test sequences by the number of inputs of the diagnostic object 12.

We introduce the notation. Let diagnostic object 12 have N inputs, n-input number, n-1, ..., N, K outputs, k-output number, k-1, ..., K. Denote by M the required number of bitwise matching output sequences of the object 12 diagnoses and the reference block 7. Denote by S the dimension of the set of suspected faults, i-number of the suspected fault, i-1, ..., S, M _i - the number of bitwise matching output sequences of the diagnostic object 12 and the reference block 7 in case of the i-th fault .

 Work algorithm. From the control unit 1, a command is sent to the first register 2 to initialize the sampling of the first suspected malfunction (i-1), information about this malfunction is sent to the malfunction simulator 6, which transforms the reference unit 7 in accordance with the i-th malfunction. After the conversion of the reference unit 7, the fault simulation unit 6 issues a command to start the random number generator 10, which generates a binary random sequence of dimension N, which, through the first coupler 8, is supplied to the diagnostic object 12 and to the reference unit 7, where it is converted to output signals. The output signal of the diagnostic object 12 through the second pairing device 9 is supplied to the bitwise comparison unit 11, where the output signal from the reference block 7 also arrives. In the bitwise comparison block 11, the output signals of the diagnostic object 12 and the reference block 7 are bitwise compared. In the case of coincidence of all the bits, the bitwise comparison unit 11 provides information about this to the second register 3, which accumulates information about the number of matches of the output signals of the diagnostic object 12 and the reference block 7. Information about the number of matches of the output signals of the diagnostic object 12 and the reference block 7 is sent to the block 4 comparison, where it is compared with the desired number of matches specified from the control unit 1.

 If the number of matches of the output sequences of the diagnostic object 12 and the reference unit 7 is less than the specified one, then the comparison unit 4 issues a command to the random number generator 10 to generate the next test sequence.

 If the number of matches of the output sequences of the diagnostic object 12 and the reference unit 7 is greater than the specified one, then the comparison unit 4 issues a command to the first register 2 to select i + 1 of the possible malfunction, information about which is received in the malfunction simulator 6 for entering into reference block 7 i + 1st fault. Further, the operation of the device is similar to work with the i-th malfunction.

 In case of mismatch of at least one bit in the output sequences of the diagnostic object 12 and the reference unit 7, the bitwise comparison unit 11 issues a command to the first register 2 to select the i + 1-st possible malfunction, information about which is received in the malfunction simulation device 6 for entering into the reference block 7 i + 1st fault. Of the many suspected faults, the i-th fault is excluded. Further, the operation of the device is similar to the work described above.

After viewing all the alleged faults, information about this goes to the control unit 1, which sends a command to the information display device 5, where information is displayed in a user-friendly form about the set of faults S ₁ that do not contradict the test results.

If, from the point of view of the user, the set S _{1 is} still large, then we can once again conduct a cycle to reduce the set of suspected faults.

 In order to increase the ergonomic characteristics of the device, it provides for work on one specific malfunction in order to probabilistically confirm its possibility or an incredible exception. In this case, only this suspected malfunction is entered in the first register 2. The operation of the device is similar to that discussed above. The advantage of the device over the known ones is that it allows the automated detection of any malfunction that has a physical meaning and its localization on the basis of a sequential improbable reduction of the set of suspected malfunctions.

 Literature.

 1. US patent N 3614608, CL. 324-73, published. 05/12/70 ..

 2. Copyright certificate of the USSR N 1160420, cl. G 06 F 11/22, 1985 (prototype).

Claims (1)

 A device for diagnosing discrete blocks, comprising a fault simulation unit, a reference unit, a control unit, characterized in that a random number generator, a bitwise comparison unit, a first register, a second register, a comparison unit, an information display device are inserted therein, and a random number generator is connected to the diagnostic object and the reference unit, the bitwise comparison unit is connected to the outputs of the diagnostic object and the reference unit, to the first and second registers, the control unit is connected n to the first register, second register, comparison unit, information display unit, the first register is connected to the failure simulation unit, the information display unit and the control unit, the second register is connected to the comparison unit, the comparison unit is connected to the first register and the random number generator, simulation unit faults connected to a random number generator and a reference unit.