RU2010323C1 - Device for static modelling condition of test object - Google Patents

Abstract

FIELD: computer technology. SUBSTANCE: device has random number detector, decoding unit, AND gate, stable frequency pulse generator, tuneable frequency divider, the first and the second reversible counters, the first and the second decoders, unit of commutators, the first and the second random voltage generators, the first and the second switch members, the first and the second groups of threshold members, the first, the second and the third OR gates, pulse former, NOT gate, flip-flop, indication unit, Process of recovery is modelled accounting for consumed time and probability of searching of trouble as well as accounting for reaction of test object to amount and intensity of work done. EFFECT: widened functional capabilities. 3 dwg

Description

 The invention relates to computer technology and can be used in statistical modeling of controlled and restored test objects under conditions of loads of varying intensity and exposure to external factors.

 A device is known for modeling the process of controlling objects having stochastic characteristics. The device contains a random function generator, a key, a functional converter, a block for setting initial conditions, an integrator, a delay element, an AND element, an OR element, a differentiating block, a key, counters, a division block, a comparison circuit [1].

 The disadvantage of this device is the inability to simulate various states of the test object, control and recovery of the object when it does not reach the value of the objective function.

 The closest technical solution to the invention is a device for statistical modeling of complex systems, containing a memory register, a result trigger, a composing field, a group of key elements, a single vibrator, a pulse shaper, a random pulse flow generator, a decoder, a random recovery time generator, a delay element, And element, two prohibition elements and a random number generator of the failed element [2].

 The purpose of the invention is the expansion of functionality by modeling the recovery process, taking into account the time spent and the probability of finding a malfunction and taking into account the reaction of the test object to the quantity and intensity of the work performed.

 In FIG. 1 shows a block diagram of a device; in FIG. 2 - embodiment of a block of switches; in FIG. 3 - decryption unit.

 The device contains a random number sensor 1, decryption unit 2, element 3, a stable frequency pulse generator 4, a frequency divider 5, a first 6 and a second 7 reverse counters, a first 8 and a second 9 decoders, a block of 10 switches, a first 11 and a second 12 generators random voltages, the first 13 and second 14 key elements, the first 15 and second 16 groups of threshold elements, the first 17, the second 18 and the third 19 OR elements, a pulse shaper 20, an element NOT 21, a trigger 22, an indication unit 23.

 The block 10 of the switches (Fig. 2) is two switches 10-1 and 10-2 with m keys 24 in each. The control inputs of the keys are connected to the output of the decoder 9, the information inputs of the keys of the switch 10-1 are connected to the output of the key element 13, and the switch 10-2 to the output of the key element 14. The outputs of the first m-1 keys of the switch 10-1 are connected to the inputs of the corresponding threshold elements of group 15, and the output of the last key to the input of the shaper 20 pulses. The outputs of the last m-1 keys of the switch 10-2 are connected to the inputs of the threshold elements of the 16th group, and the output of the first key is connected to the zero input of the trigger 22.

 The decryption unit 2 (Fig. 2) consists of a key 25 and a decoder 26. A parallel binary code from the sensor 1 is sent to block 2, the first bit of the parallel code being sent to the control input of the key 25, the remaining bits are supplied to the decoder 26, the output of which is connected to the control input of the divider 5. At the input of the key 25, "1" or "0" is applied, depending on whether the "rest" or "work" of the object is simulated, respectively. If the input of the key 25 receives "0" - "work", then at the first output of the key 25 connected to the control input of the key element 13 and the single input of the trigger 22, a high level is set, the key element 13 is opened, at the direct output of the trigger 22 is set high level. If the input of the key 25 receives "1" - "rest", then at the output of the key 25 connected to the reversible counters 6 and 7 and the key element 14, a high level appears, the counters 6 and 7 are rebuilt, the key element 14 opens.

 The threshold elements of group 15 correspond to m-1 states of the object from working 15-1 to non-working 15- (m-1), the voltage level set on the i-th threshold element corresponds to the probability of transferring the object from the i-th to (i + 1) state under the influence of random factors. The threshold elements of group 16 are used in the simulation of system recovery, the threshold set on the i-th element 16 corresponds to the depth of control of the object and the likelihood of system recovery from the i-th to the (i-1) -th state.

 To simulate the reaction of an object to various modes of operation, a tunable frequency divider 5 is used in the device. Sensor 1 gives binary codes corresponding to different levels of work intensity. Block 2, in accordance with the incoming code, changes the frequency division coefficient of the divider 5 so that the higher the intensity with which the object operates, the lower the frequency of the generator 4 divided by the frequency divider 5, the more pulses per unit of time are recorded in counter 6.

 The frequency of change of the codes of the sensor 1 is much lower than the frequency of the pulses generated by the generators 4, 11, 12. Sensor 1 gives binary codes of the operating mode and intensity levels to the decryption unit 2 according to a given time program. Block 2 reconstructs, in accordance with the received code, a frequency divider 5, the input of which receives stable frequency pulses from the generator 4 through the And 3 element, and also either opens the key element 13 at the first output (the key element 14 is locked, the counters 6 and 7 sum the pulses) or opens the key element 14 at the second output and rearranges the reverse counters 6 and 7 for subtraction (key element 13 is locked).

 From the output of the frequency divider 5, the pulses arrive at the counter 6, where they are summed. At the output of counter 6, a decoder 8 is connected, which, in accordance with the number of pulses accumulated in counter 6, sends a signal through counter OR 19 to counter 7, which controls through switching to decoder 8 the switching unit 10 of the switches. Through block 10, a pulse of a random voltage level is transmitted from the generator 11 through the open key element 13 to the threshold element 15-i (i = 1,2, ..., m-1) or from the generator 12 through the open key element 14 to the threshold element 16-i (i = 2,3, ..., m), the ith number of the threshold element corresponds to the state of the simulated object at a given time. Key elements 13 and 14 are controlled from decryption unit 2. The key element 13 is open, and the key element 14 is closed during the simulation of the operation of the object, while the pulse from the generator 11 through the block 10 is supplied to one of the threshold elements 15. At the time of modeling the recovery of the system, the key element 13 is closed, the key element 14 is open, the pulses from generator 12 through block 10 enter one of the threshold elements 16 of the group. Block 10 is switched in such a way that one i-th element from groups 15 and 16 is simultaneously connected to the output of key elements 13 and 14, respectively. Moreover, in order to avoid overflow of the counter 7 upon reaching the mth state of the switch 10-1 of block 10, the output of the mth key of the switch 10-1 is connected to the input of the pulse shaper 20, which generates and transmits pulses of duration 21 to the input of the element HE 21 exceeding the repetition period of the pulses of the generator 11. At the same time, the output of the element HE 21 is set to a low level and the element And 3 is closed to follow the pulses of the generator 4.

 In order to avoid overflow of the reverse counter 7 upon reaching the first state of the switch 10-2 of block 10, the output of the first key 24 of the switch 10-2 is connected to the zero input of the trigger 22.

 At the output of the threshold elements of groups 15 and 16 are OR elements 17 and 18, respectively, for separating the signals at the inputs of the threshold elements and generating pulses at the input of the counter 7. If the signal level of the generators 11 and 12 is higher than the level of the i-th threshold element of groups 15 and 16, respectively, then the signal passes through the threshold element 15 or 16, goes to the inputs of the OR elements 17 or 18, then to the OR element 19 and the counter 7. The signal of the decoder 9 controls the state of the block 23, which can be performed by any known circuit. In the simplest case, it can be a set of m bulbs corresponding to m states of the object so that the experimenter can conduct a statistical analysis of the operation of the object.

 The device operates as follows.

 The "Start" signal simultaneously turns on sensor 1 and generators 4, 11, 12. Sensor 1 gives a code to block 2 that corresponds to the intensity of the simulated object. With the receipt of the code, block 2 opens the key element 13, issues a high level to the single input of trigger 22 and adjusts the frequency divider 5 in accordance with the intensity of the object. Since the test simulation begins with a working state, the signal from the generator 11 does not pass to the input of the pulse shaper 20 and a low level is set at the input of the element HE 21, respectively, a high level is output from the output of the element HE 21 to the third input of the element And 3. At the direct output of the trigger 22, connected to the second input of the And 3 element, there is also a high level, therefore, the stable frequency pulses from the generator 4 through the And 3 element are fed to the input of the frequency divider 5. The pulses from the generator 4 change the frequency, passing through the frequency divider 5, and are summed by the counter 6. Upon reaching the counter 6 values determined by the researcher, corresponding to the time and intensity of work to transition to the next state, the decoder 8 gives a pulse through the element OR 19 to the counter 7. Decoder 9 with an increase in the unit of content of the counter 7 shifts the switch unit 10 by one position, connecting the threshold element 15-2 to the output of the key element 13, and changes the indication on the block 23. Simultaneously with the start of the sensor 1 and g generator 4, the generator 11 generates signals through the key element 13 and the block 10 to the threshold element 15-1 (before switching from the counter 6). If the signal level is higher than the level of the threshold element 15-1, then the pulse passes to the OR element 17, and from it the signal through the OR element 19 is recorded in the counter 7. With the pulse recorded, the decoder 9 shifts the position of the block 10 by connecting the threshold element to the output of the key element 13 element 15-2, and changes the indication of block 23.

 If the last m-th state of the switch 10-1 is reached during the simulation of the “operation” mode, then, according to the first signal from the generator 11, the pulse shaper 20 delivers a high level to the input of the element HE 21, a low level is established at the output of the element HE 21, respectively, at the third input And 3 element appears a low level and pulses from the generator 4 do not pass to the frequency divider 5 and counter 6.

 Suppose that during the simulation of an object, the object has reached the last m-th state. Sensor 1 generates a code corresponding to the idle state of the object (in the first bit of the parallel code "1"). Block 2 rebuilds the frequency divider 5, closes the key element 13 at the first output, opens the key element 14 at the second output, counters 6 and 7 switch to subtract the incoming pulses from the values accumulated during the simulation. At the moment of closing the key element 13, the signals from the generator 11 do not arrive at the pulse shaper 20, therefore, pulses do not enter the output of the pulse shaper to the input of the element HE 21, the output of the element HE 21 is set to a high level, which is transmitted to the third input of the element And 3.

 When writing off a certain number of pulses from the counter 6, the decoder 8 outputs a signal through the OR element 19 to the counter 7, reducing its value by one. The decoder 9 switches the block 10, connecting to the output of the key element 14 (m-1) th threshold element. This simulates the time required to work on troubleshooting and restoring the object to the (m-1) state. At the same time, the generator 12 generates signals that through the open element 14 and block 10 are fed to the m-th threshold element 16 of the group (before switching from the counter 6). If the signal level of the generator 12 is higher than the level of the m-th threshold element, the signal through the OR elements 18 and 19 enters the counter 7, decreasing by one its value. The decoder 9 transfers block 10 from the mth to the (m-1) th threshold element and changes the indication of block 23. This simulates the depth of the object’s control and the probability of finding a malfunction and restoring the object from the i-th to the (i-1) -th state .

 If during the recovery mode the first state is reached (the first switch key 10-2), then the first pulse of the generator 12 through the open key element 14 and block 10 is fed to the zero input of the trigger 22. A low level appears on the direct output of the trigger 22, the And 3 element is closed and pulses from the generator 4 do not pass to the frequency divider 5 and counter 6. This state is removed when the “work” code arrives at block 2, and a high level is issued from the first output of block 2 to the single input of trigger 22, the output of trigger 22 is set highlevel, element And 3 opens.

 Thus, the device simulates the cycle of the object with various intensities and recovery, while simulating how the object reacts to the duration and intensity of work, and to random external influences. During the “rest”, the restoration of the object is simulated both in terms of the time required for restoration and in the depth of the object’s control and the probability of finding a malfunction and restoration of the object. (56) 1. USSR author's certificate N 1325505, cl. G 06 F 15/20, 1986.

 2. Copyright certificate of the USSR N 1282155, cl. G 06 F 15/20, 1985.

Claims (1)

 DEVICE FOR STATISTICAL SIMULATION OF THE STATE OF THE TEST OBJECT, containing the first generator of random voltages, the first decoder, the first and second key elements, the first group of threshold elements, which is important for the purpose of the time and likelihood of finding a malfunction and taking into account the reaction of the test object to the number and intensity of the work performed, a random number sensor, a generator are introduced into it stable frequency pulses, decryption unit, frequency divider, first and second reversible counters, second decoder, second random voltage generator, switch block, second group of threshold elements, three OR elements, a pulse number generator and an indicator block, , a stable frequency pulse generator, the first and second random voltage generators are combined and are the input of the device start, the output of the random number sensor is connected to the input of the decryption unit, the first output of which it is connected to the control input of the first key element and the unit input of the trigger, the second output of the decryption unit is connected to the control inputs of the second key element, the first and second reverse counters, the third output of the decryption unit is connected to the control input to the control input to the control input the output of which is connected to the information input of the first reversible counter, the output of which is connected to the input of the first decoder, the output of the first and second elements OR is connected respectively, to the first and second inputs of the third OR element, the third input of which is connected to the output of the first decoder, the outputs of the first and second random voltage generators are connected to the information inputs of the first and second key elements, respectively, the outputs of the outputs which is connected to the inputs of the threshold elements of the first group, respectively, the outputs of which are connected to the inputs of the first OR element, the second group of outputs of the block of switches is connected is connected to the inputs of the threshold elements of the second group, respectively, the outputs of which are connected to the inputs of the second OR element, the first output of the switch unit is connected to the input of the pulse shaper, the output of which is connected to the input of the element NOT, the output of which is connected to the first input of the AND element, the output of which a frequency divider, the second output of the switch unit is connected to the zero input of the trigger, the output of which is connected to the second input of the And element, the third input of which is connected to the output of the stable frequency pulse generator.

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