RU2097827C1 - Automatic system for diagnostics of digital devices - Google Patents

Abstract

FIELD: computer engineering, instruments, in particular, detection of faults in digital instruments. SUBSTANCE: device has personal computer 1, interface unit 10, contact unit 21, tested article 22. First decoder 8 and programmable parallel input- output port 9 are introduced to computer 1. Interface unit 10 has bus generators unit 11, address bus 12, data bus 13 and control bus 14, second decoder 15, selector 16, three groups of programmable input- output ports 17, 18, 19 ad N buffer elements 20.1-20.N. This results in possibility to transmit test actions to tested article and read its responses in n-bit parallel code (where n is bit-length of input-output port of computer). EFFECT: increased speed, increased reliability. 2 dwg

Description

 The invention relates to computing and instrumentation and can be used to test performance and search for faulty elements of digital devices.

 A well-known automated system for monitoring and diagnosing digital nodes [1] contains a test driver, a programmable power supply for the control object, a strobe pulse generator, an operator panel, a control object connected by an internal system trunk, a programmable interface unit whose inputs are connected to a computer and the outputs to an internal highway devices, and the programmable interface unit contains bus drivers, data and address registers, address and command decoders, clock multiplexer, amyat and firmware microinstruction control unit.

 The main disadvantage of the system is its complexity, due to the large amount of equipment, and low reliability.

 Closest to the technical nature of the claimed invention is an automated system for monitoring and diagnosing malfunctions of electronic digital blocks [2] selected as a prototype and containing a digital computer, a registration unit, a matching unit, a conversion unit, the inputs of which are connected to the terminals for connecting the outputs of the monitoring object of the contacting unit , the input of the registration unit is connected to the output of the digital computer, the terminals for connecting the inputs of the monitoring object of the contacting unit are connected to the inputs of the conversion unit , the matching unit contains a synchronization unit, an address decoder, an input unit, an output unit, N matching cells, where N is the number of outputs of the control object, each of which contains a 2I element, 3I element with an open collector, a D-trigger, and an element NOT with an open collector moreover, the first input of each element 2H is connected to the corresponding first inputs of the address decoder and to the first input of the 3I element with an open collector, the output of each of which is connected to the corresponding inputs of the digital computers, to the first inputs of the address decoder and with the information input of the corresponding D-trigger, the synchronizing input of which is connected to the output of the corresponding element 2I, the second input of each of which is connected to the output of the output unit, the input of which is connected to the first control output of the digital computer and the first input of the synchronization unit, the second input of which is connected to the second the control output of the digital computer and the input of the input unit, the output of which is connected to the second input of the 3I element with an open collector, the third input of which is connected to the output of the element NOT with an open collector, conductive input conversion unit, an output D-flip-flop is connected to the input of NOT circuit with open collector output DCM synchronizing input coupled to a second address decoder, a second output connected to the third input of the synchronization unit, the output of which is connected to the control input of the digital computer.

 Significant disadvantages of this system are the low speed due to the algorithm of sequential recording and reading of information into each of the N matching cells, the limited number of terminals for connecting the terminals of the monitoring object of the contact block, determined by the channel width of the digital computer, a large number of discrete elements and, as a consequence, low reliability. In addition, the device contains a conversion unit, a matching device.

 The purpose of the invention is the increase in speed and reliability of the device.

выбора порта ввода-вывода, устройство сопряжения, включающее блок шинных формирователей, с соответствующими входами которых соединены выходы каналов порта ввода-вывода ПЭВМ, шины адреса, данных и управления, подключенные к соответствующим выходам блока шинных формирователей, второй дешифратор, селектор, три группы портов ввода вывода, адресные входы которых соединены с соответствующими линиями шины адреса, управляющие входы селектора и всех трех групп программируемых портов ввода-вывода соединены с соответствующими линиями шины управления, линии шины данных подключены к соответствующим входам трех групп программируемых портов ввода-вывода, первый выход селектора соединен с входом выбора второго дешифратора, выходы которого соединены с соответствующими входами выбора трех групп программируемых портов ввода-вывода, выходы селектора соединены с соответствующими входами выбора и направления передачи блока шинных формирователей, N буферных элементов с тремя состояниями, i-й (i 1, N) выход первой группы программируемых портов ввода-вывода соединен с информационными входами i-го буферного элемента, с входом выбора которого соединен i-й выход второй группы портов ввода-вывода, выход i-го буферного элемента соединен с i-м выходом третьей группы портов ввода-вывода, устройство контактирования, i-й вход которого соединен с i-м выходом третьей группы портов ввода-вывода, объект диагностирования, i-й вход которого соединен с i-м выходом устройства контактирования.This goal is achieved by the fact that in an automated system for diagnosing digital devices containing a digital computer, a pairing device, a contacting device, a diagnostic object, the outputs of the contacting device are connected to the terminals of the diagnostic object, according to the invention, the digital computer is made in the form of a PC including a processor, keyboard, display , memory, printer, respectively connected to the system bus, the first decoder and programmable input-output port, the inputs of which are connected to the corresponding iniyami system bus, and the output of the first decoder connected to the input

selection of an input-output port, an interface device including a bus former unit, the outputs of the PC I / O channel channels, address, data and control buses connected to the corresponding outputs of the bus former unit, a second decoder, selector, three groups of ports input I / O, the address inputs of which are connected to the corresponding bus lines of the address, the control inputs of the selector and all three groups of programmable input / output ports are connected to the corresponding bus lines of the control lines, data bus lines are connected to the corresponding inputs of three groups of programmable I / O ports, the first selector output is connected to the selection input of the second decoder, the outputs of which are connected to the corresponding inputs of the selection of three groups of programmable I / O ports, the selector outputs are connected to the corresponding selection inputs and transmission directions of the bus former unit, N buffer elements with three states, i-th (i 1, N) output of the first group of programmable I / O ports is connected to information input the i-th buffer element, with the selection input of which the i-th output of the second group of I / O ports is connected, the output of the i-th buffer element is connected with the i-th output of the third group of I / O ports, the contact device, whose i-th input connected to the i-th output of the third group of input-output ports, a diagnostic object, the i-th input of which is connected to the i-th output of the contacting device.

 Comparative analysis with the prototype shows that the inventive device is characterized by the presence of fundamentally new circuit elements (input-output ports, bus drivers, selector, buffer elements with three states) and connections.

 Thus, the claimed device meets the criteria of the invention of "novelty."

 Comparison of the proposed solution with other technical solutions in this area shows that the construction of the proposed structure of the interface device based on the use of LSIs as bus shapers and programmable input / output ports, as well as buffer elements with three states, allows the transfer of test actions to the diagnostic object and reading responses from it in n-bit (where n-bit capacity of the PC I / O port register) parallel code, which provides significant ( e less than n times) increase system speed, its simplification by maximizing the uniformity of the principle components used and reduce their connections, and improving reliability. In addition, the use of programmable input-output ports in conjunction with buffer elements with three states ensures the adaptability of the system to the diagnostic object due to the task of the program through various modes of transmission and reading of information. The inventive device is not critical to the type of PC used.

 Thus, the proposed technical solution for a specialist does not explicitly follow from the prior art and meets the criterion of "inventive step".

 The invention can be used in various fields of industry, namely in electronics, computer engineering and other areas of the national economy, therefore, meets the criterion of "industrial applicability".

 In FIG. 1 shows a functional diagram of a device; in FIG. 2 is a flowchart of a functioning algorithm.

выбора программируемого порта ввода-вывода 9, устройство сопряжения 10 (фиг. 1), включающее блок шинных формирователей 11, с соответствующими входами которых соединены выходы каналов программируемого порта ввода-вывода 9, шины адреса 12, данных 13 и управления 14, подключенные к соответствующим выходам блока шинных формирователей 11, второй дешифратор 15, селектор 16, три группы программируемых портов ввода-вывода 17, 18 и 19, адресные входы которых соединены с соответствующими линиями шины адреса 12, управляющие входы селектора 16 и трех групп программируемых портов ввода-вывода 17, 18 и 19 соединены с соответствующими линиями шины управления 14, линии шины данных 13 подключены к соответствующим входам трех групп программируемых портов ввода-вывода 17, 18 и 19, первый выход селектора 16 соединен с входом выбора второго дешифратора 15, выходы которого соединены с соответствующими входами выбора трех групп программируемых портов ввода-вывода 17, 18 и 19, выходы селектора 16 соединены с соответствующими входами выбора и направления передачи блока шинных формирователей 11, N буферных элементов 20.1 20.N с тремя состояниями, i-ый (i 1, N) выход первой группы программируемых портов ввода-вывода 17 соединен с информационным входом i-го буферного элемента, с входом выбора которого соединен i-ый выход второй группы программируемых портов ввода-вывода 18, выход i-го буферного элемента соединен с i-ым выходом третьей группы программируемых портов ввода-вывода 19, устройство контактирования 21 (фиг. 1), i-ый вход которого соединен с i-ым выходом третьей группы программируемых портов ввода-вывода 19, и объект диагностирования 22 (фиг. 1), i-ый выбор разъема которого соединен с i-ым выходом устройства контактирования 21.The system (Fig. 1) contains a PC 1, which includes a processor 2, a keyboard 3, a display 4, a memory 5, a printer 6, connected accordingly to the system bus 7, a first decoder 8 and a programmable input-output port 9, the inputs of which are connected with the corresponding lines of the system bus 7, the output of the first decoder 8 is connected to the input

selection of programmable input-output port 9, the interface device 10 (Fig. 1), including a block of bus shapers 11, with the corresponding inputs of which the outputs of the channels of the programmable input-output port 9, address bus 12, data 13 and control 14 are connected to the corresponding the outputs of the bus formers block 11, the second decoder 15, the selector 16, three groups of programmable input-output ports 17, 18 and 19, the address inputs of which are connected to the corresponding bus lines of address 12, the control inputs of the selector 16 and three groups of programs adjustable input-output ports 17, 18 and 19 are connected to the corresponding control bus lines 14, data bus lines 13 are connected to the corresponding inputs of three groups of programmable input-output ports 17, 18 and 19, the first output of the selector 16 is connected to the input of the choice of the second decoder 15 , the outputs of which are connected to the corresponding inputs of the selection of three groups of programmable input-output ports 17, 18 and 19, the outputs of the selector 16 are connected to the corresponding inputs of the selection and transmission direction of the block of bus formers 11, N of the buffer elements 20.1 20.N with three states, the i-th (i 1, N) output of the first group of programmable I / O ports 17 is connected to the information input of the i-th buffer element, the input of the selection of which is connected to the i-th output of the second group of programmable I / O ports 18, output i of the nth buffer element is connected to the i-th output of the third group of programmable input-output ports 19, the contacting device 21 (Fig. 1), the i-th input of which is connected to the i-th output of the third group of programmable input-output ports 19, and the diagnostic object 22 (Fig. 1), the i-th choice of the connector of which is connected to the i-th output of the contacting device 21.

 The device operates as follows.

 The object of diagnosis (OD) 22 is connected to the contacting device (UK) 21, which provides electrical communication between the terminals of the OD connector and the interface device (US) 10. Using a diagnostic program stored in memory 5 of PC 1, processor 2 generates input influences (BB) that come through the system bus 7, programmable I / O port 9, DC 10, UK 21 to the inputs of OD 22. Responses (OR) from the outputs of OD 22 to these explosives arrive through UK 21 to the DC 10. At the right times, the processor 2 reads the PR with CSS 10 and processes them in co sponds to a predetermined algorithm. After entering on K 22 all K input actions provided by the diagnostic program, and reading with subsequent processing of responses, a corresponding message on the technical condition of the OD is displayed on the display screen 4, which can be printed in the required format on printer 6.

 In FIG. 2 shows a block diagram of the algorithm of the system. At the beginning of the diagnostic program, the system is initialized, which includes programming the input-output port 9 for outputting information, programming three groups of input-output ports 17, 18, and 19 of the USB 10, and the groups of input-output ports 17 and 18 are programmed for outputting information, and the third group of I / O ports 19 is programmed to enter information, the logs are set at the outputs of the second group of I / O ports 18. "1", due to which all buffer elements 20.1 20.N are closed and are in the third state. Using the first decoder 8, I / O port 9 is selected, and using the second 15, any of the ports in each of the three groups of I / O ports 17, 18 and 19 is selected. The bus shaper is selected from the block of bus shapers 11 and the direction of transmission, and the choice of the second decoder 15 is carried out by the selector 16.

 Next, the system is self-monitored. If it is in good condition, OD 22 is connected to UK 21, otherwise, a message about the system malfunction is displayed on the display screen and the operation of the diagnostic program ends.

 After connecting the OD 22 to the UK 21 at the instructions of the processor 2, a code is entered into the second I / O group 18 of the switching code of the inputs and outputs of the OD 22 with the outputs and inputs of the DC 10. As a rule, this code is recorded once for a specific OD and provides unhindered passage of input effects on the inputs of OD and reading responses to these effects from its outputs. Then, the index j is assigned a value of zero (j 0), where j is the serial number of the input of the diagnostic program. Reprogramming the input-output port 9 to the output of information. In the general case, channel A of this port is used to output address information to the DC 10, channel B for input and output of data, channel C for output of control signals. Information is transmitted on each channel of the input-output port 9 in n-bit parallel code. The input of the explosive (j) is recorded in the port of the first group 17 and then through the buffer elements 20.1 - 20. N, previously opened by the switching code recorded in the ports of the second group 18, and the contacting device 21 is fed to the inputs of the OD 22.

 To read the response, the OD channel B of the I / O port 9 is reprogrammed to enter information. After that, according to the instructions of the processor 2, the response OP (j) of the OD 22 through the UK 21, the ports of the third group 19, the data bus 13, the bus driver 11, the channel B of the input-output port 9, the system bus 7 is recorded in memory 5. Next, the comparison is carried out RR (j) with a reference reaction ER (j) stored in the memory of a PC. If the comparison result is positive, the next input action is output to the OD. In the case of a negative result, the error message is recorded in a specially designated program file and the next input action of the explosive (j + 1) is displayed on the diagnostic object 22. After all K input actions provided by the diagnostic program are output to the OD, a message about the technical state of the OD 22 is displayed on the display screen 4. This message is generated based on the results of comparing the OP (j) and the ER (j), if all the K comparisons of the OD are valid, and if at least one j-th response does not coincide with the j-th reference reaction, information on the OD malfunction and the number of the i-th output of the OD, from which the erroneous response is read, is included in the message. If necessary, this message can be calculated on the printer 6.

 I / O ports and a bus former unit can be implemented on the BIS 580 series, and decoders, selector, and buffer elements on the 533 series IS.

 Thus, the introduction of a programmable input-output port and the first decoder to the PC, as well as the construction of the proposed structure of the interface device based on the use of LSI as a block of bus formers and programmable input-output ports, buffer elements with three states, allows the transmission of test actions to the diagnostic object and reading responses from it in n-bit (where n is the bit width of the PC I / O port register) parallel code, which provides a significant formatting (not less than n times) increase system speed, its simplification by maximizing the uniformity of the principle components used and reduce their connections, which increases the reliability. In addition, the use of programmable input-output ports in conjunction with buffer elements with three states ensures the adaptability of the system to the diagnostic object due to the task of the program through various modes of transmission and reading of information.

Claims (1)

 An automated system for diagnosing digital devices containing a digital computer, an interface device, a contact device, a diagnostic object, the outputs of the contact device are connected to the terminals of the diagnostic object, characterized in that the digital computer is designed as a personal computer containing a processor, keyboard, display, memory, printer, connected to the system bus, the first decoder and programmable input-output port, the inputs of which are connected to the corresponding lines of the system bus, the output of the first decoder connected to the input of the selection of the programmable input-output port, the interface device, including the block of bus drivers, with the corresponding inputs of which the outputs of the channels of the programmable input-output port, bus address, data and control are connected to the corresponding outputs of the block of bus drivers, the second decoder, selector , three groups of programmable I / O ports, the address inputs of which are connected to the corresponding bus lines of the address, the control inputs of the selector and three groups of programmable ports I / O are connected to the corresponding control bus lines, data bus lines are connected to the corresponding inputs of the three groups of programmable I / O ports, the first output of the selector is connected to the selection input of the second decoder, the outputs of which are connected to the corresponding inputs of the choice of three groups of programmable I / O ports, the selector outputs are connected to the corresponding inputs of the choice and direction of transmission of the bus former unit, N buffer elements with three states, i-th (1, N) output of the first group of programs controlled input / output ports is connected to the information input of the i-th buffer element, the i-output of the second group of programmable input / output ports is connected to the selection input, the output of the i-th buffer element is connected to the i-th output of the third group of programmable input and output ports output and i-th input of the contacting device.

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