SU913385A1 - Device for monitoring digital object state - Google Patents

Description

The invention relates to computing and can be used to encode the logical state of digital objects with a view to their subsequent control and search for faulty components (connecting elements, microcircuits, typical replacement elements, devices, etc.).

A device for detecting faulty modules in digital objects is known [£ 1].

However, the known device provides coding of signals taken automatically from only some predetermined and limited list of control points of the object. Therefore, it cannot be used for diagnostics with an accuracy of a typical replacement element in digital objects built on the element base with medium and low degree of integration, the diagnostics of which requires an analysis of relatively

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.g. .

large and not always predictable list of control points.

The closest to the invention to the technical essence is a device containing a display unit, a shift register with feedback, a modulo two adder and a control unit (in a known device, the control unit is a set of input devices for receiving a digital signal from a certain section of a digital electronic circuit, trigger device, device, stop ^. This device, endowed with a probe for manual removal of encoded signals, can be used for objects built on the element base with any degree of integration [21.

However, the device requires relatively large hardware costs> which reduces its reliability,

increases weight, size and cost. This is significant

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a disadvantage for a device designed to encode, monitor and search for faulty components in digital objects.

The purpose of the invention is to simplify the device while maintaining the reliability of coding.

This goal is achieved by the fact that the device for monitoring the state of digital objects, containing the shift register, adder, control unit and display unit, the first and second inputs of the shift register are connected respectively to the output of the adder and the first output of the control unit, the second output of which is connected to the first input the adder, the second input of the adder is connected to the first output of the shift register, the second output of which is connected to the input of the display unit, the first, second, third and fourth inputs of the control unit are connected to the control panel by the object being located, the fifth input of the control unit is connected to the third input of the shift register and is the device input, contains a switch, a group of inputs of which is connected to the group of outputs of the shift register, a group of outputs of the switch, is connected to a group of inputs of the adder.

In addition, the control unit contains four amplifiers, a trigger and the elements of the input of each amplifier are respectively the first, second, third and fourth inputs of the device, the output of the third fourth amplifier is connected respectively to the first and second inputs of the trigger, the third input of which is the fifth input of the control unit , the trigger output is connected respectively to the first inputs of the first and second elements And, the second input of the first element And connected to the output of the first amplifier, the second input of the second element And connected to the output m of the second amplifier, the output of the first and second elements And are respectively the first and second outputs of the control unit.

Using a switch, they can vary in number and combination of feedback and shift register. 'Experimentally, it was found that different switch modes, different number and combination of feedback, correspond to different combinations of encoded

binary sequences that make up the list of error combinations (by the error combination is meant such a coded binary

5 sequence, as a result of the conversion which is obtained on the shift register the same residue as when converting the reference binary sequence). It is obvious that if each of the possible input binary sequences is encoded, first in one switch mode, and then in the other (dual-mode coding)

, 5, and the resulting residues of one and another coding of each input binary sequence are used as a kind of single residue, then the corresponding combination of dual-mode coding will be smaller than the corresponding list of each single-mode coding. It is clear that the list of error combinations of two-way simulation will include only general error combinations that are included in the lists of error combinations of single-mode coding for the two modes under consideration, i.e. with a double-shift conversion, the average value increases, the coding confidence in relation to the corresponding value of any single-mode conversion. With a three,

₃ $ four- etc. - mode conversion reliability of coding continues to increase in accordance with the increase in the number of simultaneously used-. coding modes.

₄₀ In addition, it is known that an increase in the digit capacity of the shift register entails an increase in the confidence value of the control and vice versa. Thus, the use of an additional mode (additional control modes) provided by a switch allows, at the same bit width of the shift register and the display unit, to increase the coding accuracy or, with constant coding accuracy, to reduce the bit width of the shift register and the display unit, i.e., to simplify the device .

The switch represents the collect

in general, input / H1-output

a key scheme connecting in each of the modes m from η input sig5

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cash with GP exits. In this case, a higher degree of simplification of the device requires the use of a larger number of switch modes.

Figure 1 presents the block diagram <device coding binary sequences in digital objects; Fig, 2 is an example implementation of the control unit.

The device contains a register 1 to

shift, adder 2, control unit 3 and display unit 4, as well as switch 5 (digital object 6 is not included in the device and is provided only to explain the operation and device).

The first and second inputs of the shift register I are connected respectively to the output of the adder. 2 and the first output of the control unit 3. The second output 20 of the control unit 3 is connected to the first input of the adder 2. The second input of the adder 2 is connected to the first output of the shift register 1. The second output of the shift register 1 is connected to the input 25 of the display unit 4. The first, second, third and fourth inputs of the control unit 3 are the corresponding inputs of the device. The fifth input of the control unit 3 is connected to the third input of the shift register 1 and is the fifth input of the device. The group of inputs of the switch 5 is connected by P-connections to the group of outputs of the shift register 1. The group of outputs of the switch 5 is connected by y-connections to the group of inputs of the adder 2. The connection of the second input of the adder 2 to the first output of the shift register 1 indicates the expediency of direct connection of the output of the high digit of the register 1 shift with the input of the adder 2 (ie, not through the switch 5), while not reduced with different modes of switch 5

shift register 1. ι · · '-

The control unit 3 is designed to receive. amplification and formation of control signals and the input dynamic sequence. In accordance with the purpose of the control unit 3 contains four unlinked. 7,8,9 and 10 recorded amplifiers, trigger 11, to the output of which two controlled elements I 12 and I 13 are connected, and to the inputs of which through the amplifiers 9 and 10 respectively the control signals “start” 14 and “stop” are fed

15. When receiving the start signal

14, the trigger 11 opens the controlled elements And 12 and 13, upon receipt of the signal "stop" 15 - closes ..

Through the element And 12 passes the input dynamic sequence 16, and through the element And 13 - the clock signals 17. The trigger II has an input 18 of the installation to zero. An open element And 12 passes dynamic sequence 16 through line 19 to the second output of control unit 3 at a time interval that begins at the start signal 14 and ends at a stop signal 15, And time element 13 skips the synchronization signals 17 at the same time interval through line 20 to the first output of the control unit 3.

The display unit 4 is designed to decrypt the binary code received (as a result of converting the input dynamic sequence on the shift register 1 into a seven-segment decimal code convenient for human visual perception. In accordance with the purpose, the display unit 4 contains a decoder, to the input of which a binary code is received from the second output of the shift register 1, and seven-segment LEDs, which are connected to the output of the specified decoder on the input. Instead of the seven-segment LEDs, other and dikatsionnye elements such decatrons et al.

Switch 5 is generally η - input ^ - output key circuit, where the U inputs of switch 5 are connected to various outputs of the shift register 1,

Depending on the position (mode) of switch 5, various outputs of the shift register and in various combinations can be received through the center> outputs of switch 5 to the input of adder 2. Increasing the modes of switch 5 allows for the same bit width of shift register 1, adder 2 and display unit 4 increase the reliability of coding of binary sequences or, with constant coding accuracy, reduce the digit capacity of the register 1 ^ of the shift of the adder 2 and the display unit 4, i.e. simplify the device. In the example below, switch 5 is the simplest switching element for two positions and one

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but direction. As a key element can be used electronic key, relay, toggle switch or other similar element.

The device works as follows ₅ times.

The coding of the technical state of a digital object 6 is carried out by converting binary [signals taken from the characteristic points of a digital object 6. The removal of binary signals is carried out alternately for each point from the final list of characteristic points of a digital object 6. The process of converting binary signals into some arbitrary point of digital object 6 is as follows. Switch 5 is set to the position corresponding to the first coding mode of the technical state. The second, third and fourth inputs of the control unit 3 are connected to the second, third and fourth outputs of the digital object 6, which are assigned to output control signals "start" 14,

“stop” 15 and “synchronization” 17. The first input 16 of the control unit 3 is connected by means of an auto probe or a hand probe equipped with a needle, with the first output of a digital object 6. To the fifth input 18 of the control unit 3, to the input of a digital object 6 and to the third the input of the shift register 1 is given a signal to set them to zero, then allowing the start of the stimulation of the digital object 6, while it is assumed that the stimulation of the digital object 6

carried out in the same way as when using „40

using a known device using a stimulator embedded in the object 6.

As a result of the excitation of the digital object 6 at its chosen point in time, a completely definite, corresponding to the stimulating, excitation, takes place. The dynamic process is a binary sequence of signals of the digital object that is fed to the first input 16 of the control unit 3. In the control unit 3, this binary dynamic sequence is amplified, formed and limited by the signals "start" 14 and "stop" 15, and then from the second output 19 of the control unit 3 it enters the first input of the adder 2, where it is summed by

I double the values of the selected bits of the shift register 1, which flow directly to the second input of the adder 2 and through the switch 5 to its group of inputs.

For clocking control pulses arriving at the second input of the shift register 1 from the first output 20 of the control unit 3, the contents of the shift register 1 are shifted for each pulse by one bit from the low bits to the high ones, and the result of the sum from the output of the adder 2 to the first input of the register 1 shift. The clock control pulses from the first output 20 of the control unit 3 are output only in the time interval between the start and stop pulses 15, which determine the binary sequence conversion interval. Thus, at the end of the conversion interval, the reception of information into the shift register 1 is stopped and the information shifts stop. The contents of the shift register 1, the result of the conversion of the binary sequence comes from the second output of the shift register 1 to the display unit 4 ', where the key word is displayed. Then the switch 5 is set to the position corresponding to the second coding mode, and for the selected point of the digital object 6, the coding of the technical state is repeated as in the first mode. The resulting four characters on the display unit 4 (two characters in the first encoding mode and two characters in the second encoding mode) together represent the key word corresponding to a certain technical state of the digital object 6.

Similarly, keywords can be obtained for the entire list of characteristic points of a digital object 6 necessary for its monitoring and diagnostics. The reference keywords are removed at the characteristic points of a working digital object 6 and are recorded either on a corresponding scheme, or on a special graph or table, or directly near the contacts of the digital object 6. Digital object 6 is monitored, and the faulty component is searched for using the proposed device

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by the described process of coding the dynamics of a digital object 6 and comparing real keywords with reference ones. A faulty component has at its input the License keys ₅

Chevy words that match the reference, and the output - not the same. The process of obtaining a keyword at some arbitrary point of a digital object 6, with its characteristic points (contacts) available, takes several seconds to connect the first input 16 of control unit 3 with the selected point (touch the point with a needle _{15 of the} probe), set the switch 5 in the desired mode and readings on the display unit 4.

The use of the proposed device allows to obtain two types of effect to one degree or another: simplification of the device and Improving the coding confidence * Therefore, the device can be realized threefold 25 depending on the requirements.

By requiring the greatest possible simplification of the device and maintaining the reliability of coding no worse than a certain value by increasing the number of operating modes of switch 5, the width of the shift register 1, the adder 2 and the display unit 4 is reduced.

When the maximum possible increase in the reliability of coding is required at a certain acceptable complexity of the device corresponding to a certain bitness of the register 1 shift, the adder 2 and the display unit 4 by increasing the number of modes of operation of the switch 5 and at the same bit capacity the device increases the reliability of the coding.

When an optimal combination of the coding confidence value and the bit depth of the device is demanded due to a certain number of switch 5 modes used, a partial increase in the coding confidence and a partial decrease of the device depth are achieved.

Claims (2)

Claim 1. A device for monitoring the state of digital objects, containing a shift register, an adder, a control unit and a display unit, the first and second inputs of the shift register are connected respectively to the output of the adder and the first output of the control unit, the second output of which is connected to the first input of the adder, the second input of the adder is connected to the first output of the shift register, the second output of which is connected to the input of the display unit, the first, second, third and fourth inputs of the control unit are connected to the controlled object ohm, the fifth input of the control unit is connected to the third input of the shift register and is a device input, characterized in that, in order to simplify the device while preserving the coding accuracy, the device contains a switch, a group of inputs of which are connected to the output register group of the shift register, switch output group connected to the group of inputs of the adder. 2. The device according to claim 1, characterized in that the control unit contains four amplifiers, a trigger and elements And, the input of each amplifier is respectively the first, second, third and fourth input of the device, the output of the third and fourth amplifier is connected respectively to the first and second inputs trigger, the third input of which is the fifth input of the control unit, the trigger output is connected respectively to the first inputs of the first and second elements And, the second input of the first Element And connected to the output of the first amplifier, the second input of the second The first element And is connected to the output of the second amplifier, the output of the first and second elements And are respectively the first and second outputs of the control unit.