RU198966U1 - A device for evaluating the probabilistic and temporal characteristics of signal formation in information management systems - Google Patents

Abstract

The utility model relates to automation and computer technology and can be used to assess the probability of generating a control signal according to the established rules in information control systems (IMS) in automatic systems based on data received from information systems by modeling the probability of receiving information signals. In the claimed device, the probabilistic-temporal characteristics of receiving signals from information systems about the occurrence of a dangerous situation are set, the input signals are simulated with specified probabilistic-temporal characteristics, in accordance with the formation rules specified by the logical function of the form F (A) = AA + AA + AA + ААА + ААА The number of generated control signals is counted for a time not exceeding the specified one and the probabilistic-temporal characteristics of the formation of the control signal are calculated, which makes it possible to assess the probability of formation of the control signal based on the rules specified by the logical function. 1 ill.

Description

The utility model relates to automation and computer technology and can be used to assess the probabilistic and temporal characteristics of the formation of a control signal according to established rules in information and control systems (IMS) based on data received from information systems.

The rules for generating a control signal in information management systems are set by a logical function of the form F (A) = A ₁ A ₂ + A ₂ A ₃ + A ₂ A ₄ + A ₅ A ₆ A ₇ + A ₅ A ₆ A ₈ . This function depends on Boolean logical variables Ai (i = 1, 2, ..., n), each of which corresponds to a single input information signal.

There is a known device for modeling failures and damages in complex systems [RF Patent for invention No. 2292583], containing a sensor for the primary flow of random pulses, an I element, a one-shot, a pulse counter, the first, second and third delay elements, a generator of uniformly distributed random numbers, the first and second memory registers, elements of the first, second and third groups, arithmetic unit, random number generator with a given distribution law, decoder, dial-up field, trigger group, OR element, random pulse stream generator, second AND element, noise generators, second groups of triggers, OR elements of the first group.

The disadvantage of this device is the impossibility of studying the probabilistic-temporal characteristics of signal formation in the I&C.

A device for statistical modeling of the state of the test object is known [RF Patent for invention No. 2010323], containing a random number sensor, a decoding unit, an I element, a pulse generator of a stable frequency, a tunable frequency divider, the first and second reversible counters, the first and second decoders, a block of switches , the first and second generators of random voltages, the first and second key elements, the first and second groups of threshold elements, the first, second and third OR elements, a pulse shaper, a NOT element, a trigger, an indication unit.

The disadvantage of this device is the impossibility of studying the probabilistic-temporal characteristics of signal formation in the I&C.

A device for simulating a multi-mode system is known [RF patent for invention No. 2246131], containing a control trigger, blocks of random pulse generators, a block for generating a program for the operation of a simulated multi-mode system, blocks of operating modes and technological mode, operating time counters, generators of random pulses, an OR block, counters bounce. The disadvantage of this device is the impossibility of studying the probabilistic-temporal characteristics of signal formation in the I&C.

The known method and device for checking the logic of work

information and control systems [RF patent for invention №259633]. The method for checking the logic of the operation of information and control systems provides for the formation of a special set of representative sequences of input signals for testing I&CS, which significantly reduces the volume of I&C tests and guarantees checking I&CS as well as a complete set of input signal sequences. The device for checking the logic of the information and control systems allows you to automate the process of testing the I&C The disadvantage of this method and device lies in the fact that it is designed to check the correct logic of the IMS and does not allow studies of the probabilistic-temporal characteristics of the formation of the control signal.

The closest in technical implementation to the claimed solution is a control signal generation device [RF Patent for PM No. 190908], which contains N triggers for input signals of dangerous situations, M signal conditioning units in accordance with the specified rules (where M is the number of signal generation rules), OR element, each signal shaping unit contains a positional register for setting the i-th (i = 1, M) rule consisting of triggers, a group of N AND elements, a group of N OR elements, an AND element. Information signal inputs are connected to single inputs of the corresponding registers , the single outputs of which are connected to the first inputs of the corresponding elements AND of all the signal conditioning units, to the second inputs of the AND elements of each signal conditioning unit, the single outputs of the triggers are connected, the zero outputs of which are connected to the second inputs of the OR group of elements, and the first inputs of which are connected to the outputs of the corresponding elements And, outputs of a group of elements OR, soe are connected with the corresponding input of the AND element of the signal forming unit, the output of the AND element of each signal forming unit is connected to the corresponding input of the OR element, the output of which is the output of the device.

In this device, the rules for generating a control signal are set by a logical function of the form F (A) = A ₁ A ₂ + A ₂ A ₃ + A ₂ A ₄ + A ₅ A ₆ A ₇ + A ₅ A ₆ A ₈ . However, this device does not allow researching the probabilistic-temporal characteristics of signal formation.

The purpose of creating a useful model is to ensure the possibility of assessing the probabilistic and temporal characteristics of the formation of a control signal in information control systems.

This goal is achieved by the fact that a device for assessing the probability of signal formation in information control systems, containing N triggers of input signals of dangerous situations, an OR element, M signal conditioning units in accordance with the specified rules (where M is the number of signal generation rules), each the signal generating unit contains a positional register for setting the i-th (i = 1, M) rule consisting of a group of N triggers, a group of N elements AND, a group of N elements OR, an AND element, and the outputs of the group of corresponding triggers of input signals are connected to the first inputs And the groups of elements of all signal shaping units, in each signal shaping unit, the single outputs of the trigger group are connected to the second inputs of the corresponding AND elements of the group, and the outputs are connected to the first inputs of the OR elements group, to the second inputs of which the zero outputs of the triggers of the group are connected, the outputs of the OR elements group , connected to the corresponding inputs of the AND element, the output of which is I the output of the signal conditioning unit, the output of each signal conditioning unit is connected to the corresponding input of the OR element, in order to expand the area of use of the device by assessing the probability of generating a control signal based on the rules specified by the logical function, a clock pulse generator, N random number sensors are introduced into the device , the AND element, the first and second delay lines, the first and second counter, a register of a given number of tests, a comparison circuit, a division unit, a group of AND elements, a result register, a display means, and the device start input is connected to the start input of the clock pulse generator, the output of which connected to the inputs of all random number sensors, to the input of the second counter, to the input of the first delay line, the output of which is connected to the second input of the AND element and the input of the second delay line, the output of which is connected to the inputs of the setting in the zero state of the triggers of the input signals, to the inputs of the installation in the single state of which under the outputs of the random number sensors are switched on, the output of the OR element is connected to the first input of the AND element, the output of which is connected to the input of the first counter, the information outputs of the first counter are connected to the inputs of the divisible division unit, the register outputs of the given number of tests are connected to the second inputs of the comparison circuit, the output of which is connected with the control inputs of the group of elements AND and the stop input of the clock pulse generator, the information outputs of the second counter are connected to the first inputs of the comparison circuit and to the inputs of the divider of the division unit, the outputs of which are connected through the group of elements And to the inputs of the result register, the outputs of which are connected to the inputs of the display means.

The essence of the utility model is that the proposed device sets the probabilistic-temporal characteristics of receiving signals from information systems about the occurrence of a dangerous situation, simulates the input signals with given probabilistic-temporal characteristics, in accordance with the formation rules specified by the logical function, the number of generated control signals for a time not exceeding the specified one and the probabilistic-time characteristics of the formation of the control signal are calculated.

In the figure of FIG. 1 shows a block diagram of the device.

The device contains a clock pulse generator 1, N random number sensors 2 ₁ -2 _N (where N is the number of input information signals), N triggers for input signals of dangerous situations 3 ₁ -3 _N , M signal conditioning units in accordance with the specified rules 4 ₁ - 4 _M (where M is the number of signal formation rules), OR element 9, AND element 10, first and second counters 11, 12, comparison circuit 13, register of a given number of tests 14, first and second delay lines 15, 16, dividing unit 17 , a group of elements AND 18, a result register 19, a display means 20, an input for starting the device 21, while each signal generating unit 4 ₁ -4 _M contains a positional register for setting the i-th (i = 1, M) rule, consisting of triggers 5 ₁ -5 _N , a group of N elements AND 6 ₁ -6 _N , a group of N elements OR 7 ₁ -7 _N , an element AND 8.

The device works as follows.

Let the rules for the formation of the control signal be specified by the logical function F (A) = A ₁ A ₂ + A ₂ A ₃ + A ₂ A ₄ + A ₅ A ₆ A ₇ + A ₅ A ₆ A ₈ .

For the case under consideration, eight information signals are used, i.e. N = 8 and five rules of signal formation, M = 5.

The signal at the output of the device will be generated when the input information signals are received:

1) either from the first and second information systems;

2) either from the second and third information systems;

3) either from the second and fourth information systems;

4) either from the fifth, sixth and seventh information systems;

5) either from the fifth, sixth and eighth information systems.

In the initial state, triggers 3 ₁ -3 ₈ are in the zero state. In the first block 4 ₁ of signal formation in accordance with the first rule for generating the control signal, triggers 5 ₁ and 5 ₂ are set to the single state, and the remaining triggers of the first block 4 ₁ of signal formation (triggers 5 ₃ -5 ₈ ) are set to the zero state. In the second block 4 ₂ of signal formation, in accordance with the second rule for generating the control signal, triggers 5 ₂ and 5 ₃ are set to a single state, and the remaining triggers of the second block 4 ₂ of signal formation (triggers 5 ₁ , 5 ₄ -5 ₈ ) are set to zero state ... In the third block 4 ₃ of signal formation, in accordance with the third rule for generating the control signal, triggers 5 ₂ and 5 ₄ are set to a single state, and the remaining triggers of the third block 4 ₃ of signal formation (triggers 5 ₁ , 5 ₃ , 5 ₅ -5 ₈ ) - to the zero state. In the fourth block 4 ₄ of signal formation in accordance with the fourth rule for generating the control signal, triggers 5 ₅ -5 ₇ are set to a single state, and the remaining triggers of the fourth block 4 ₄ of signal formation (triggers 5 ₁ -5 ₄ , 5 ₈ ) are set to zero ... And, finally, in the fifth block 4 ₅ of signal formation in accordance with the fifth rule for generating the control signal, triggers 5 ₅ , 5 ₆ , 5 ₈ are set to a single state, and the remaining triggers of the fifth block 4 ₅ of signal conditioning (triggers 5 ₁ -5 ₄ , 5 ₇ ) - to the zero state. In the register of a given number of tests 14, the required number of tests is entered, which is determined based on the required accuracy of the estimates. The random number sensors 2 ₁ -2 _{N are} configured in such a way that the output is a signal in accordance with the value of the probability of signal formation by the i-th (i = 1, N) information system. In this case, if an estimate of the probability of signal formation is required, then the sensors of random numbers 2 ₁ -2 _N generate signals in accordance with the value of the probabilities of signal formation by the i-th (i = 1, N) information system, if an estimate of the probability of false signal formation is required, then random number sensors 2 ₁ -2 _N generate signals in accordance with the value of the probabilities of false signal generation by the i-th (i = 1, N) information system.

When the device is started, the clock pulse generator sequentially starts the random number sensors 2 ₁ -2 _N , which for each pulse with a given probability set the corresponding triggers to a single state.

Consider the formation of a control signal when triggers 3 ₁ and 3 _{2 are set} to the single state. Since in the first block 4) of signal formation triggers 5 ₃ -5 _{8 are} set to zero, then from the zero outputs of these triggers, high potential will go through the OR elements 7 ₃ - 7 ₈ to the corresponding inputs of the AND element 8. At all inputs except the first and the second element AND 8 will have a high potential and when triggers 3 ₁ , 3 _{2 are set} to a single state, then from the single outputs of the trigger 3 ₁ , 3 ₂ through the elements AND 6 ₁ , 6 ₂ OR 7 ₁ , 7 _{2, the} high potential will go to the first and the second input of the element AND 8. Since at all inputs of the AND element 8 high potential, then from the output of the AND element 8 of the first block 4 ₁ signal generation high potential will go through the OR element 9 to the second input of the AND element 10.

Let's consider the operation of the device when triggers 3 ₂ and 3 _{3 are set} to a single state. Since the triggers 5 ₁ , 5 ₄ -5 _{8 are} set in the zero state in the second block 4 ₂ of the signal formation, then from the zero outputs of these triggers the high potential will go through the OR elements 7 ₁ , 7 ₄ -7 ₈ to the corresponding inputs of the AND element 8. At all inputs except the second and third element AND 8 there will be a high potential and when triggers 3 ₂ and 3 _{3 are set} to a single state, then from the single outputs of triggers 3 ₂ and 3 ₃ through elements I 6 ₂ and 6 ₃ , elements OR 7 ₂ and 7 ₃ high potential will go to the second and third inputs of the AND element 8. Since at all inputs of the element And 8 high potential, then from the output of the element And 8 of the second block 4 ₂ signal generation high potential will go through the element OR 9 to the input of the element I10.

Similarly, the device works when triggers 3 are set to a single state in accordance with rules 3, 4, 5.

The clock pulse will arrive at the input of the counter 12 and through the first delay element 15 (delay for the time of transient processes) in the case of a high potential (when the signal is generated according to any of the rules) at the input of the AND element 10, the clock pulse will arrive at the input of the first counter. From the output of the first delay element, the pulse passing through the second delay element (delay for the time of transient processes of the AND element 10 and the counter 11) will set the triggers 3 ₁ -3 _N to the zero state. On the second and subsequent pulses of the clock generator 1, the operation of the device will be continued in the manner described above until the value of the counter 12 equals the value written in the register 14.

When the counter value 12 reaches the value recorded in register 14 from the output of the comparison circuit 13, the signal will stop the clock pulse generator and open the group of elements 18. The value from the division unit L _field / L _Σ (where L _floor is the number of positive outcomes; L _Σ is the total number test) will enter register 19 and will be displayed in block 20. This will complete the device operation.

The technical result of the proposed technical solution lies in the fact that the device makes it possible to estimate the probability of forming a control signal in automatic systems based on the rules specified by a logical function. In this case, it is possible to assess the likelihood of both the correct formation of the control signal in automatic systems and the probability of the formation of the control signal in automatic systems as a result of false triggering of information tools.

Thus, the goal of creating a useful model to provide the possibility of assessing the probability of generating a control signal based on the rules specified by the logical function has been achieved.

Claims (1)

A device for evaluating the probabilistic and temporal characteristics of signal shaping in information control systems, containing N triggers of input signals of dangerous situations, an OR element, M signal shaping units in accordance with the specified rules (where M is the number of signal shaping rules), each signal shaping unit contains a positional register for setting the i-th (i = 1, M) rule, consisting of a group of N triggers, a group of N elements AND, a group of N elements OR, an AND element, and the outputs of the group of corresponding triggers of input signals are connected to the first inputs AND of the group of elements of all signal conditioning units, in each signal conditioning unit, single outputs of the group of triggers are connected to the second inputs of the corresponding elements AND of the group, and the outputs to the first inputs of the group of OR elements, to the second inputs of which the zero outputs of the triggers of the group are connected, the outputs of the OR group of elements are connected to the corresponding inputs of the AND element, the output of which is the output of the block signal forming, the output of each signal conditioning unit is connected to the corresponding input of the OR element, characterized in that the device contains a clock pulse generator, N random number sensors, an AND element, the first and second delay lines, the first and second counter, a register of a given number of tests, comparison circuit, division unit, group of elements AND, result register, display means, and the device start input is connected to the start input of the clock pulse generator, the output of which is connected to the inputs of all random number sensors, to the input of the second counter, to the input of the first delay line, the output which is connected to the second input of the AND element and the input of the second delay line, the output of which is connected to the inputs of the setting in the zero state of the triggers of the input signals, to the inputs of the setting in the single state of which the outputs of the random number sensors are connected, the output of the OR element is connected to the first input of the AND element, the output which is connected to the input of the first counter, information control outputs of the first counter are connected to the inputs of the divisible dividing block, the outputs of the register of a given number of tests are connected to the second inputs of the comparison circuit, the output of which is connected to the control inputs of the group of elements AND and the stop input of the clock pulse generator, the information outputs of the second counter are connected to the first inputs of the comparison circuit and to the inputs of the divider of the division unit, the outputs of which are connected through the group of elements AND to the inputs of the result register, the outputs of which are connected to the inputs of the display means.

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