RU2617982C1 - Device for signaling deviations of parameters for tolerance control - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: device parameter deviations alarm for limit test consists of: "Start" button; RS-flip-flop; three AND gates and one OR gate; two blocks and elements; Counting frequency generator; two pulse counters; encoder and decoder; switch; Sensor-controlled channels; shapers of signals "a deviation upward" and "downward deviation"; period pulse sequence generator; two pulse generators; two single pulse generators; a shift register; memory units, display, reverse registers, a reset state, an alarm identification, analysis, the two-step search signal; controller. The new device is a controller for periodical monitoring of the observed variable for controlling the parameters of objects and consisting of a divider, counter, memory element, an element of comparison, coefficients setting element, the multiplication element, clock generator controlled by a divider, as well as the aggregate of new connections.

EFFECT: device will increase the speed of a two-stage Search alarm system in a multi-channel control by controlling the parameters of the frequency depending on the speed of change and adaptive change preview channel length in the first phase Search alarm.

2 cl, 3 dwg

Description

The invention relates to the field of relay protection and automation and can be applied, for example, in multi-channel monitoring and tele-signaling systems for various technological processes.

A device for tolerance control of parameters is known, consisting of a control control unit, an operational amplifier, a scaling unit, a voltage measuring unit, first and second programmable current generators, a registration and indication unit, and a switch (see RF patent No. 1440240, IPC G06F 11/36, publ. 07.27.2004).

The disadvantage of this device is the lack of quality control of dynamically changing processes with a random nature of assessments of measurements of quality indicators, as well as the lack of accounting for the changing measurement error.

A device is known for signaling deviations of a parameter during tolerance control, consisting of sensors, a switch, signal generators "Deviation Up" and "Deviation Down", pulse generators, decoders, pulse counters, OR-NOT elements, a buffer cascade, and indication elements (see copyright USSR certificate No. 1357991, class G08B 23/00, published on December 7, 1987 in Bulletin No. 45).

The disadvantage of this device is the relatively large time delay of the alarm when multi-channel signal control. This is due to the fact that the analysis of each channel is carried out until a decision is made on the presence or absence of deviations of the parameter from the established tolerances. If a device element characterized by such a parameter is located in the channels with the latest numbers, then the content of its parameter can be detected only after viewing all the channels, which requires considerable time and is not always acceptable in real-time systems.

A device for signaling deviations of a parameter during tolerance control, which contains the Start button in series, an RS-trigger, a counting frequency generator, a pulse counter, a decoder, a switch, sensors according to the number of channels being monitored, a “Deviation up” signal conditioner, a “Deviation down” signal conditioner ", Three AND elements, two pulse generators, a block of reversible registers, an OR element, two formers of a single pulse, an initialization unit, a shift register, two blocks of AND elements, a cipher ator, a memory unit and a display unit (see. the patent for utility model, RF №68736, IPC G08 23/00, published on 27.11.2007, Bul. №33).

The disadvantage of this device is the relatively large delay in generating an alarm at the stage of preliminary control of channels.

The closest analogue (prototype) in technical essence to the proposed device is an alarm device for tolerance control according to the patent for a utility model of the Russian Federation No. 140746, IPC G08 23/00 (published on 05/20/2014), containing the Start button connected in series, RS trigger , counting frequency generator, two pulse counters, decoder, switch, sensors according to the number of monitored channels, “Deviation up” signal conditioner, “Deviation down” signal conditioner, three I elements, two pulse generators, the unit is reversible registers, OR element, two pulse shaper of the unit, the unit setting to the initial state, a shift register, two block elements and interposer, a memory unit, a display unit, an alarm signal identification unit, a two-stage search unit analyzing the signal generator and pulse period sequence.

The disadvantage of this device is the relatively large delay in generating an alarm at the stage of preliminary control of channels.

The technical result achieved using the claimed device for signaling deviation of parameters during tolerance control is to increase the speed of a two-stage search for an alarm in a multi-channel control system by adaptively changing the duration of channel previews at the first stage of an alarm search.

In the claimed device for signaling deviations of parameters during tolerance control, the technical result is achieved by the fact that in a known device for signaling deviations of parameters during tolerance control, containing N≥2 sensors, the output of each n-th of which, n = 1, 2, ..., N , connected to the corresponding nth information input of the switch, the control input of which is connected to the output of the decoder, the first input of which is connected to the first output of the first pulse counter, the signal shaper "Deviation up" and the shaper the “Deviation down” needle, the combined inputs of which are connected to the switch output, the “Start” button, the first contact of which is connected to the device’s power source, and the second is connected to the first input of the OR element and S input of the RS-flip-flop, the direct output of which is connected to the control input the first pulse counter and the second input of the shaper of the pulse sequence period, the second output of the first pulse counter is connected to the second input of the first pulse generator and the inputs of the second pulse generator and the second For a single pulse, the output of which is connected to the information input of the shift register, the second output of which is connected to the R input of the RS flip-flop, the inverse output of which is connected to the second input of the OR element, the first input of the third AND element, the control input of the second block of AND elements, and the second input of the generator counter frequency, the output of which is connected to the information input of the first pulse counter and the second input of the third element And, the output of which is connected to the second input of the second pulse counter and with the control input and the memory, the output of which is connected to the second input of the decoder, the output of which is connected to the first control input of the reversible register block, the summing information input of which is connected to the output of the first element And, the control input of which is connected to the output of the signal shaper "Deviation up", subtracting the information input of the block reverse registers connected to the output of the second element And, the control input of which is connected to the output of the shaper signal "Deviation down", and the information inputs of the first and second of the first AND element is connected to the output of the first pulse generator, the first input of which is connected to the input of the installation unit to the initial state and connected to the output of the first driver of a single pulse, the input of which is connected to the output of the OR element, and the output of the installation unit to the initial state is connected to the second control input block of reverse registers, the output of which is connected to the information input of the first block of elements AND, the first input of the display unit is connected to the input of the alarm identification block, the output of which о is connected to the first input of the second pulse counter, the output of which is connected to the input of the two-stage signal search analysis unit, the output of which is connected to the first input of the pulse sequence period former, the output of which is connected to the first input of the counter frequency generator, the second input of the display unit is connected to the output of the second block AND elements, the information input of which is connected to the output of the memory block, the first input of which is connected to the output of the encoder, the input of which is connected to the output of the first block of AND elements, the control input of which is connected to the first output of the shift register, the clock input of which is connected to the output of the second pulse generator, an additional controller is introduced, the input of which is connected to the output of the reversible register block, and the output is connected to the first input of the display unit. The controller consists of a divider, the input of which is the input of the controller, and the first output is connected to the input of the counter, the output of which is connected to the input of the memory element, the output of which is connected to the first input of the comparison element, the second input of which is connected to the output of the coefficient setting element, and the output connected to the second input of the multiplication element, the first input of which is connected to the second output of the divider, and the output of the multiplication element is connected to the first input of the controlled divider, the second input of which is connected to the output of the generator ora clock, and the output is the output of the controller.

Thanks to the above-mentioned new set of essential features of the claimed device for signaling deviation of parameters during tolerance control, it is possible to increase the speed of the two-stage procedure for searching for an alarm in the multi-channel control system by changing the frequency of monitoring parameters depending on the speed of their drift, as well as adaptive changing the duration of the preview of channels at the first stage alarm search.

The claimed device is illustrated by drawings, which show:

in FIG. 1 is a block diagram of a device for signaling deviations of a parameter during tolerance control;

in FIG. 2 - functional diagram of the controller;

in FIG. 3 - dynamics of the speed of the controlled parameter going beyond the permissible limits: a) with a deviation of "Up"; b) with a deviation of "Down."

The claimed device for signaling deviations of parameters during tolerance control, shown in FIG. 1, contains: start button 1; RS trigger 2; counting frequency generator 3; first 4 and second 27 pulse counters; decoder 5; switch 6; sensors of monitored channels 7.1, 7.2, ..., 7.n, ..., 7.N; shapers of the signal "deviation up" 8 and the signal "deviation down" 9; the first 10, second 11 and third 23 elements And; first 12 and second 18 pulse generators; block of reverse registers 13; element OR 14; first 15 and second 17 formers of a single pulse; initialization unit 16; shift register 19; the first 20 and second 25 blocks of AND elements; encoder 21; memory unit 22; display unit 24; alarm identification unit 26; a two-stage signal search analysis unit 28; a shaper of the period of the pulse sequence 29; controller 30.

Moreover, the outputs of the sensors of the monitored channels 7.1, ..., 7.n, ..., 7.N are connected to the corresponding information inputs (6.1, ..., 6.n, ..., 6.N) of the switch 6, the control input 6.N + 1 of which connected to the output of the decoder 5, the first input 5.1 of which is connected to the first output of the first pulse counter 4, the combined inputs of the signal generator "Deviation up" 8 and the signal generator "Deviation down" 9 are connected to the output of the switch 6, the first contact of the Start button 1 is connected to the device’s power source, and the second to the first input 14.1 of the OR element 14 and S the input of the RS-flip-flop 2, the direct output of which is connected to the control input 4.1 of the first pulse counter 4 and the second input 29.2 of the pulse generator of the pulse sequence 29, the second output of the first pulse counter 4 is connected to the second input 12.2 of the first pulse generator 12 and the inputs of the second pulse generator 18 and the second driver of a single pulse 17, the output of which is connected to the information input 19.1 of the shift register 19, the second output of which is connected to the R input of the RS-trigger 2, the inverse output of which is connected to the second input ohm 14.2 of the OR element 14, the first input 23.1 of the third element And 23, the control input 25.2 of the second block of elements And 25 and the second input 3.2 of the generator of the counting frequency 3, the output of which is connected to information input 4.2 of the first pulse counter 4 and the second input 23.2 of the third element And 23 the output of which is connected to the second input 27.2 of the second pulse counter 27 and to the control input 22.2 of the memory unit 22, the output of which is connected to the second input 5.2 of the decoder 5, the output of which is connected to the first control input 13.1 of the block of the reverse registers 13, su a troubling information input 13.2 which is connected to the output of the first element And 10, the control input 10.1 of which is connected to the output of the signal generator "Deviation up" 8, subtracting the information input 13.3 of the block of the reverse registers 13 is connected to the output of the second element And 11, the control input 11.1 of which is connected to the output of the signal shaper "Deviation down" 9, and the information inputs 10.2 and 11.2 of the first 10 and second 11 elements And are connected to the output of the first pulse generator 12, the first input 12.1 of which is connected to the input of the unit and to the initial state 16 and is connected to the output of the first driver of a single pulse 15, the input of which is connected to the output of the OR element 14, and the output of the installation unit to the initial state 16 is connected to the second control input 13.4 of the block of the reverse registers 13, the output of which is connected to the information input 20.1 the first block of elements And 20 and the input of the controller 30, the output of which is connected to the first input 24.1 of the display unit 24 and connected to the input of the alarm identification unit 26, the output of which is connected to the first input 27.1 of the second counter pulses 27, the output of which is connected to the input of the analysis block of the two-stage signal search 28, the output of which is connected to the first input 29.1 of the pulse generator of the pulse train 29, the output of which is connected to the first input 3.1 of the generator of the countable frequency 3, the second input 24.2 of the display unit 24 is connected to the output of the second block of elements And 25, the information input 25.1 of which is connected to the output of the memory block 22, the first input of which 22.1 is connected to the output of the encoder 21, the input of which is connected to the output of the first block of elements And 20, the control input which 20.2 is connected to the first output of the shift register 19, the clock input of which 19.2 is connected to the output of the second pulse generator 18.

The “Start” button 1 is designed to supply voltage to the RS-trigger 2 and turn on the device from the power source.

The RS-trigger 2 is designed to start the counter frequency generator 3.

The generator of the counting frequency 3 is designed to generate counting pulses with a period of τ, necessary for the interrogation of the analyzed channels and the decision on the presence of alarms in them.

The first pulse counter 4 is designed to count the number of pulses and assign them the corresponding number, for the subsequent decision on the presence of an alarm in the analyzed channel.

The decoder 5 is designed to convert the code combination into a certain number of "units" proportional to the number of pulses (corresponding numbers), i.e. supplying the enable signal to the control input of the corresponding block register 13.

The switch 6 is designed to alternately connect the sensors to the signal generator "upward deviation" 8 or the signal generator "downward deviation" 9, depending on the signal received from the decoder 5 coming to the control input.

Sensors of controlled channels (7.1, ..., 7.n, ..., 7.N) are designed to measure (record and transmit) the physical value of a parameter in various technological processes.

The signal generator "upward deviation" 8 is intended to compare the value of the signal parameter with the level X of the upper threshold x _i .

The “deviation down” signal generator 9 is intended to compare the signal parameter value with the level X of the lower threshold x _j .

The first element And 10 is designed to pass pulses from the output of the first pulse generator 12 to the summing information input of one of the registers of the block of reverse registers 13, in case X> x _i .

The second element And 11 is designed to pass clock pulses from the output of the first pulse generator 12 to the subtracting input of one of the registers of the block of reverse registers 13, in case X <x _j .

The first pulse generator 12 is designed to supply to the information inputs of the first and second elements And clock pulses.

The block of reverse registers 13 is designed to record a certain number of logical units, starting with the first triggers of these registers.

The OR element 14 is designed to supply voltage from the inverse output of the RS-trigger 2 to the input of the first shaper of a single pulse 15.

The first driver unit pulse 15 is designed to generate a single pulse.

The initialization block 16 is intended for initialization of the reverse registers of the block of reverse registers 13.

The second shaper of a single pulse 17 is designed to re-generate a single pulse, depending on the signals from the pulse counter 4 and the first pulse generator 12.

The second pulse generator 18 is designed to generate a signal and transmit it to the clock input of the shift register 19, in the case of a signal from the second output of the first pulse counter 4 to the input of the generator.

The shift register 19 is intended for the formation of “interrogating” pulses generated as a result of the interaction of the output pulse coming from the second pulse generator 18 and the pulse coming from the second shaper of a single pulse 17.

The first block of elements And 20 is designed to compare the "interrogating" pulses coming from the output of the shift register 19 pulses with a different number of logical units coming from the block of reverse registers 13, as a result of the analysis of triggers.

The encoder 21 is designed to generate information (code combination) about the numbers of sensors that have measured signals from maximum to minimum levels.

The memory unit 22 is designed to record information (about the number of sensors) coming from the encoder in the memory cell, as well as access to the recorded information in the memory cells of the decoder 5.

The third element And 23 is designed to pass pulses from the output of the generator of the counting frequency 3 to the control input of the memory unit 22, designed to provide a sequential connection of memory cells of the memory unit 22 to the second input of the decoder 5.

Indication unit 24 is designed to display the result of the current monitoring of the state of information transmission channels analyzed in the second stage, and to indicate the numbers of monitored channels from sensors 7.1, ..., 7.n, ..., 7.N.

The second block of elements And 25 is designed to pass pulses of sensor numbers to the display unit 24, depending on the signal from the inverse output of the RS-trigger 2.

The alarm identification block 26 is designed to recognize a signal that has exceeded a predetermined threshold level.

The second pulse counter 27 is designed to count the number of channels, the probability of finding alarms in which is maximum, analyzed at the second stage of control.

The analysis block two-stage signal search 28 is designed to select a signal to control the duration of the preliminary stage of control.

The generator of the period of the pulse sequence 29 is intended to form a repetition period T (T >> τ), which is equal to the time sufficient for a complete analysis of the signal measured by any of the sensors 7.1, ..., 7.n, ..., 7.N.

Schemes for constructing logical elements AND (10, 11, 23), OR (14), blocks of elements AND (20, 25), RS-trigger (2), pulse counters (4, 27), encoder (21) and decoder (5 ), a switch (6), a shift register (19), and a block of reverse registers (13) are known and described, for example, in the book [1].

Schemes for constructing countable frequency generators (3) and pulses (12, 18); sensors of controlled channels (7.1, ..., 7.n, ..., 7.N); shapers of signals (8, 9), single pulses (15, 17) and the period of the pulse sequence (29); memory units (22), indications (24), alarm identification (26), initialization (16) and analysis (28) can be implemented in various ways, for example, as described in books [2, 3].

The controller 30 is designed to periodically monitor the observed changing parameters of the control object. It can be implemented in various ways, for example, as shown in FIG. 2.

The controller 30 consists of a divider 30.1, a counter 30.2, memory elements 30.3, a comparison 30.4, setting coefficients 30.5, multiplication 30.6, as well as a clock generator 30.7 and a controlled divider 30.8.

The input of the divider 30.1 is the input of the controller 30, the first output 30.1.1 of the divider 30.1 is connected to the input of the counter 30.2, the output of which is connected to the input of the memory element 30.3, the output of which is connected to the first input 30.4.1 of the comparison element 30.4, the second input of which 30.4. 2 is connected to the output of the coefficient setting element 30.5, and the output is connected to the second input 30.6.2 of the multiplication element 30.6, the first input of which 30.6.1 is connected to the second output 30.1.2 of the divider 30.1, and the output is connected to the first input 30.8.1 of the controlled divider 30.8 the second input of which 30.8.2 is connected to the output of the clock generator 30.7, and the output is the output of the controller 30.

для Δt_ij времени, необходимого для достижения параметра сигнала допустимого предела, где i=1, 2, …, Y - принимаемые им значения при отклонении вверх, a j=1, 2, …, М - принимаемые им значения при отклонении вниз (фиг. 3).The divider 30.1 is designed to obtain the frequency of the polling signal (application)

for Δt _{ij the} time necessary to reach the signal parameter of the allowable limit, where i = 1, 2, ..., Y are the values that he accepts when he deviates upward, aj = 1, 2, ..., M is the values he accepts when he deviates downward (Fig. 3).

Counter 30.2 is designed to count signals with rapidly changing parameters.

The memory element 30.3 is designed to store the next result of the summation of signals with rapidly changing parameters.

Comparison element 30.4 is intended for comparing the absolute values of the time that signals of various priorities go beyond acceptable levels.

The coefficient setting element 30.5 is intended for supplying constant values (constants) of threshold levels to the comparison element 30.4.

The multiplication element 30.6 is designed to multiply the signal obtained in the process of dividing from the divider 30.1, and the result of comparing the absolute values of the output time of signals of various priorities for the acceptable levels from the comparison element 30.4.

The clock generator 30.7 is designed to generate a signal that sets the sequence of information processing, and synchronize the operation of the nodes of the device.

The controlled divider 30.8 is intended for the formation of control pulses of the periodicity of control of various parameters of the object.

Schemes for constructing a divider 30.1, counter 30.2, a comparison element 30.4, a multiplication element 30.6, and a controlled divider 30.8 are known and described, for example, in the book [1].

Schemes for constructing a clock generator 30.7, as well as memory elements 30.3 and setting coefficients 30.5 can be implemented in various ways, for example, as described in books [2, 3].

The claimed device for signaling deviation of parameters during tolerance control works as follows.

When the “Start” button 1 is pressed (see Fig. 1), voltage is applied to the S input of the RS-flip-flop 2 and the RS-flip-flop 2 is put into the state of a logical unit. The voltage from the direct output of the RS-flip-flop 2 through the shaper of the period of the pulse sequence 29 is supplied to the first input of the generator of the counting frequency 3 and the control input of the first pulse counter 4 to ensure its operation. From the output of the generator of the counting frequency 3 through the period former of the pulse train 29, the information input of the first pulse counter 4 receives pulses with a period τ, which is much less than the time required for the final decision on the presence of an alarm signal in the analyzed channel.

The signal corresponding to the number of the incoming pulse from the first output of the first pulse counter 4 through the decoder 5 is fed to the control input of the switch 6 for connecting sensors 7.1, ..., 7.n, ..., 7.N to signal conditioners 8 and 9, respectively, "Deviation up "And" Deviation down. " The signal with level X measured by one of the sensors 7.1, ..., 7.n, ..., 7.N is compared with the signal parameter of the upper threshold level x _i in the signal conditioner “Deviation up” 8 and with the signal parameter of the lower threshold level x _j in the signal conditioner "Deviation down" 9.

In the event that X> x _i , then from the output of the shaper “Deviation up” 8, the signal opens the first element And 10 for the receipt of pulses from the output of the first pulse generator 12 to the summing information input of one of the registers of the block of reversible registers 13; when X <x _{j the} signal from the output of the shaper of the signal "Deviation down" 9 opens the second element And 11 to ensure the passage of clock pulses from the pulse generator 12 to the subtracting information input of one of the reverse registers of the block of reverse registers 13; if x _i ≤X≤x _i , then there are no signals at the outputs of the signal conditioners “Deviation up” 8 and “Deviation down” 9. In this case, the output of the elements And 10 or elements And 11 is connected to that register of the block of reverse registers 13, the number of which corresponds to the number of the analyzed sensor 7.n. This is achieved by supplying an enable signal to the control input of the corresponding from the registers of the block of reverse registers 13 from the output of the decoder 5.

The initial state of the reverse registers of the block of reverse registers 13 is provided by pressing the "Start" button 1 and applying voltage through the OR element 14 to the input of the first single pulse shaper 15. The pulse from the output of the single pulse shaper 15 is fed to the input of the installation block to the initial state 16, which provides writing to the reverse registers of the block of reverse registers 13 a certain number of logical units, starting with the first triggers of these registers. In addition, the pulse from the shaper of a single pulse 15, supplied to the first input of the first pulse generator 12, ensures its inclusion.

If the pulses from the first pulse generator 12 are fed to the summing information input (in the case X> x _i ), then the number of logical units in the corresponding reverse register of the block of reverse registers 13 increases if the pulses arrive at the subtracting information input (for X <x _j ), then the number of logical units in the register of the block of reverse registers 13 decreases, with the ratio x _j ≤X≤x _{i the} number of logical units does not change (since in this case both elements And 10 and 11 will be closed). Thus, by the end of the first stage of control, in all the reverse registers of the block of reverse registers 13, the number of logical units proportional to the signal levels at the output of the corresponding sensors 7.1, ..., 7.n, ..., 7.N will be recorded.

After counting the nth pulse by the first pulse counter 4, from its second output, a signal will arrive at the second input of the first pulse generator 12 to stop it, as well as at the inputs of the second driver of a single pulse 17 and the second pulse generator 18. The output pulse of the second driver of a single pulse 17 to the information input of the shift register 19 in the form of a logical unit, which, when applied to the clock inputs of this pulse register from the output of the second pulse generator 18, moves along the triggers of the register 19.

Interrogating pulses from the output of the triggers of the shift register 19 are sequentially fed to the control input of the first block of elements And 20, the information input of which is connected to the outputs of the triggers of the corresponding reverse registers of the block of reverse registers 13. The survey of the registers of the block of reverse registers 13 begins with an analysis of the state of the last triggers simultaneously block of reverse registers 13, then the penultimate triggers of the registers of the block of reverse registers 13, etc. are analyzed. The encoder 21 through the block of elements And 20 will initially receive a pulse from the reverse register of the block of reverse registers 13, in the triggers of which the largest number of logical units, which corresponds to the maximum signal level from the number measured at the first stage of control.

From the output of the encoder 21 to the input of the memory unit 22, information on the number of the sensor 7.n that measured the signal with the maximum level is first received and recorded in the first memory cell. In the second cell of the memory unit 22, the number of the sensor 7.n is recorded, which measures the signal with a slightly lower signal level, etc. Thus, the first stage of control ends with the ranking of the numbers of channel sensors 7.1, ..., 7.n, ..., 7.N in the memory block 22, depending on the probability of the presence of alarms in the monitored channels.

When a single pulse passes through all the triggers of the shift register 19, a signal appears on its second output, which goes to the R input of the RS-trigger 2 and throws this trigger to the state of logical zero. The first pulse counter 4, connected to the direct output of the RS-trigger 2, is turned off. In addition, the voltage from the inverse output of the RS-flip-flop 2, supplied through the OR element 14 to the first unit of pulse generator 15, provides the formation of a single pulse, including the first pulse generator 12 and sets (using the installation unit in the initial state 16) reversible registers of the block reversible registers 13 to its original state.

The voltage from the inverse output of the RS-flip-flop 2 is also supplied to the second input of the counter-frequency generator 3. From the output of the counter-frequency generator 3, pulses are sent to the control input of the memory block 22 through the open input 23 and the pulse period T (T >> τ) is equal to the time sufficient for a complete analysis of the signal measured by any of the sensors 7.1, ..., 7.n, ..., 7.N. These pulses provide a serial connection of the memory cells of the unit 22 to the second input of the decoder 5, while ensuring control of the state of those channels, the probability of finding alarms in which is maximum.

By analogy with the first stage of control, the switch 6 connects the sensors 7.1, ..., 7.n, ..., 7.N to the signal conditioners “deviation up” 8 and “deviation down” 9. In this case, the sensor whose number is recorded is first connected in the first memory cell of unit 22, since the signal from its output has the greatest probability of alarming information, then a sensor whose number is recorded in the second cell of memory unit 22 is connected to the signal generators “deviation up” 8 and “deviation down” 9, etc. d.

In the shapers of the signals “deviation up” 8 and “deviation down” 9, the levels X of the measured signals are compared with threshold levels: the upper x _i and the lower x _j . If X> x _i , then from the “Deviation up” signal shaper 8, the signal supplied to the control input of the And 10 element will ensure the passage of clock pulses from the output of the first pulse generator 12 to the summing information input of one of the reverse registers of the block of the reverse registers 13. Number logical units at the same time in the register of the block of reverse registers 13 will be increased by the number of received clock pulses. The choice of the reverse register corresponding to the number of the analyzed channel is ensured by supplying a signal to the first control input of the block of reverse registers 13 from the output of the decoder 5, the second input of which receives information from the output of the memory unit 22.

When X <x _{j, the} signal supplied from the signal shaper "Deviation down" 9 to the control input of the element And 11 will reduce the number of logical units in the register of the block of reverse registers 13 by the number of clock pulses from the first pulse generator 12 to the subtracting input of the reverse register block of reverse registers 13.

с первого выхода делителя 30.1 поступают на вход счетчика 30.2, в котором в течение периода T₀ осуществляется подсчет

.Clock pulses, in accordance with the rate of change of the parameter, from the block of reverse registers 13 enter the divider 30.1 (see Fig. 2) of the controller 30. The calculation results

from the first output of the divider 30.1 enter the input of the counter 30.2, in which during the period T ₀ is counted

.

At the end of the duration of the period T _0, the summation result from the counter 30.2 is supplied to the memory element 30.3. In this case, the counter 30.2 is reset and ready to receive the next information.

.The output of the memory element 30.3 is connected to the first input of the comparison element 30.4, which compares the absolute values of the output time of signals of various priorities for acceptable levels (see Fig. 3). A comparison of these values shows that the less time it takes to reach an acceptable limit by a controlled parameter of a signal, the higher its priority. The second input of the comparison element 30.4 receives a signal from the element for setting coefficients 30.5. The multiplication element 30.6 is controlled by the output of the comparison element 30.4 connected to the second input of the multiplication element 30.6, the first input of which is fed from the second output of the divider 30.1 the current value

.

The calculation results from the output of the multiplication element 30.6 are fed to the information input 30.8.1 of the controlled divider 30.8 to generate control pulses of the periodicity of control of various parameters, and a control signal specifying the information processing sequence is supplied to its control input 30.8.2 from the output of the clock pulse generator 30.7, and synchronization of the operation of device blocks. Thus, the controller 30 allows you to control the dynamics of the output speed of variable parameters of various priorities beyond the permissible limits already at the first stage of control.

The result of the current monitoring of the state of the channels analyzed in the second stage is reflected in the display unit 24, the first input of which is connected to the output of the controller 30. The number of the monitored channels (sensors 7.1, ..., 7.n, ..., 7.N) is provided by feeding information to the second input of the display unit 24 from the output of the second block of elements And 25, the information input of which is connected to the output of the memory unit 22, and the control input to the inverse output of the RS-trigger 2.

Thus, at the second stage of monitoring, first of all, the state of those channels is analyzed, the probability of finding alarms in which is maximum (according to the results of the first stage of monitoring). The number of channels analyzed at the second monitoring stage is counted by a second pulse counter 27, the information input of which is connected to the output of the third element And 23. The alarm signal is identified by the alarm identification block 26 (for example, in case of exceeding a predetermined threshold level), from the output of which to the control the input of the second pulse counter 27 receives a signal to stop it. The result of the counting from the output of the second pulse counter 27 is fed to the input of the two-stage signal search analysis unit 28. The two-stage signal search analysis analysis unit 28 selects a signal for controlling the duration of the first stage, which is supplied to the control input of the period former of the pulse train 29.

The more channels were watched in the second stage of monitoring before the alarm was detected, the more the duration of the first (preliminary) stage should be increased in order to increase the probability of finding the measurement result in the specified tolerance interval x _j ÷ x _i , and therefore, the probability of the presence of the alarm in the first (after ranking) channel, the number of which is recorded in the memory block 22. If the second stage is regularly limited to monitoring only the first (after ranking) channel, this may indicate excessively long duration of the first phase control.

The implementation of the second stage of control, during which the state of those channels in which the probability of finding alarms is maximum is analyzed first of all. which is in the worst conditions (or with a minimum value of the permissible error probability p _er.dop ) can be represented mathematically.

, гдеOn the set {X}, it is required to find such a matrix of distribution of alarms among the channels

where

for which:

- вероятность обслуживания (идентификации тревоги) сигналов по верхнему или нижнему пределу), то естьprovided that all L alarms in N channels are subject to distribution, and each type of alarm (when the parameter exceeds a specified level) can be assigned to one channel (

- the probability of servicing (identifying an alarm) signals according to an upper or lower limit), i.e.

When introducing the notation

solving the problem is equivalent to finding the matrix X ^* such that

Thus, the claimed device for signaling deviations of parameters during tolerance control, in comparison with the known one, will improve the speed of a two-stage search for an alarm signal (by determining the priority of an incoming signal) in a multi-channel control system with a varying measurement error by periodically monitoring the observed changing parameters depending on the rate of change Δt _ij and thereby timely detect the pre-emergency situation of various objects.

Literature

1. Shilo V.L. Popular Digital Chips: A Guide. 2nd ed. - Chelyabinsk: Metallurgy, Chelyabinsk Department., 1989. - 352 p.

2. Titz U., Schenk K. Semiconductor circuitry: in 2 vols. with him. - T. 1. - M .: Dodeka - XXI, 2008. - 832 p.

3. Titze U., Schenk K. Semiconductor circuitry: in 2 volumes: trans. with him. - T. 2. - M .: Dodeka - XXI, 2008 .-- 942 p.

Claims (2)

1. A device for signaling parameter deviations during tolerance control, containing N≥2 sensors, the output of each n-th, n = 1, 2, ..., N, of which is connected to the corresponding nth information input of the switch, the control input of which is connected to the output of the decoder, the first input of which is connected to the first output of the first pulse counter, the signal generator "Deviation up" and the signal generator "Deviation down", the combined inputs of which are connected to the output of the switch, the "Start" button, the first contact of which is connected to the source device power supply, the second one is connected to the first input of the OR element and the S input of the RS-flip-flop, the direct output of which is connected to the control input of the first pulse counter and the second input of the pulse train period former, the second output of the first pulse meter is connected to the second input of the first pulse generator and inputs a second pulse generator and a second shaper of a single pulse, the output of which is connected to the information input of the shift register, the second output of which is connected to the R input of the RS trigger, and the versioned output of which is connected to the second input of the OR element, the first input of the third AND element, the control input of the second block of AND elements, and the second input of the counter frequency generator, the output of which is connected to the information input of the first pulse counter and the second input of the third AND element, the output of which is connected to the second the input of the second pulse counter and with the control input of the memory block, the output of which is connected to the second input of the decoder, the output of which is connected to the first control input of the reversible register block s, the summing information input of which is connected to the output of the first element And, the control input of which is connected to the output of the “Deviation up” signal conditioner, the subtracting information input of the reverse register block is connected to the output of the second element And, the control input of which is connected to the output of the “Deviation down” signal ", And the information inputs of the first and second elements And are connected to the output of the first pulse generator, the first input of which is connected to the input of the installation unit in the initial state and It is connected to the output of the first driver of a single pulse, the input of which is connected to the output of the OR element, and the output of the installation unit in the initial state is connected to the second control input of the block of reverse registers, the output of which is connected to the information input of the first block of elements AND, the first input of the display unit is connected to the input an alarm identification unit, the output of which is connected to the first input of the second pulse counter, the output of which is connected to the input of a two-stage signal search analysis unit, the output of which о is connected to the first input of the pulse sequence period generator, the output of which is connected to the first input of the counter of frequency generator, the second input of the display unit is connected to the output of the second block of elements And, the information input of which is connected to the output of the memory block, the first input of which is connected to the output of the encoder, input which is connected to the output of the first block of AND elements, the control input of which is connected to the first output of the shift register, the clock input of which is connected to the output of the second pulse generator, ex sistent in that additionally introduced a controller having an input coupled to output of the reversible registers, and an output coupled to the first input of the indication unit. 2. The device according to p. 1, characterized in that the controller consists of a divider, the input of which is the input of the controller, and the first output is connected to the input of the counter, the output of which is connected to the input of the memory element, the output of which is connected to the first input of the comparison element, the second input which is connected to the output of the coefficient setting element, and the output is connected to the second input of the multiplication element, the first input of which is connected to the second output of the divider, and the output of the multiplication element is connected to the first input of the controlled divider, the second input to orogo connected to the output of the clock, and the output is the output of the controller.

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