RU2187142C1 - Device for monitoring of parameters - Google Patents

Abstract

FIELD: automatic equipment and computing machinery, applicable in automated checkout systems, in particular, in check-out systems of digital and analog units of radio electronic equipment. SUBSTANCE: device has a control unit, two commutators, analysis unit, stimulating signal unit, normalizer unit, maximum and minimum signal separation unit, analog-to-digital converter, information output unit. EFFECT: enhanced speed of response of the device due to the use of optimum procedures of fault finding in the objective of monitoring, taking into account both the probability of failure of separate components, and the time spent for check-out operations, as well as simplified construction of the device. 2 cl, 6 dwg, 2 tbl

Description

 The invention relates to automation and computer technology and can be used in automated control systems, in particular in control systems for digital and analog components of electronic equipment.

 A well-known automated control system for parameters of electronic circuits containing an operator panel, a control computer, a block of address registers, registers of input and output information, a synchronization block, a block of stimulating signals, a block of meters, the first and second switches, a block of reference signals (AS USSR 1010602, CL G 05 B 23/02, B.I. 13, 1983). The disadvantage of the system is its low performance.

 Closest to the technical nature of the proposed device is a parameter control device containing an information output unit, a control computer, a terminal, an address register block, first and second switches, a stimulating signal block, a meter block, input information registers, output information registers, a control unit modes and synchronization unit, the first information inputs-inputs of the control computer are connected to the information inputs of the address register block and the inputs of the input registers one information, with the outputs of the second switch, the mode control unit and input information registers, the second information inputs and outputs - with the control inputs and outputs of the synchronization unit and the address register block, interrupt inputs and outputs - with the inputs and outputs of the mode control unit, the third and fourth information inputs and outputs - with inputs and outputs of the information output unit and the terminal, respectively, the outputs of the address register block are connected to the control inputs of the second switch and synchronization unit, the outputs are connected input to the synchronization inputs of the output information registers, the meter block, the input information registers, the stimulating signal block, the second switch and the mode control block, the input information register outputs are connected to the information inputs of the stimulating signal block, the second switch and the first information inputs of the first switch, to the control the inputs of the first switch, the first information inputs and outputs of which are the inputs and outputs of the device for connecting to the inputs and outputs of the control object , the first and second outputs to the first information inputs of the output information registers and to the information inputs of the meter block, respectively, the second information inputs to the outputs of the stimulus block, the first and second outputs of the meter block are connected to the second and third information inputs of the output information registers, respectively, the analysis block and a comparison unit, the first and second inputs connected respectively to the outputs of the registers of input information and to the first outputs of the meter unit, respectively, and passages - to the inputs of the first information analysis unit, second information input connected to the second output of the block gauges, control inputs - outputs the input information to the register, the clock - to the outputs of synchronizing unit, and outputs - to the data inputs of mode control unit (AS USSR 1513418, class G 05 B 23/02, b.i. 37, 10/07/89 - prototype).

 The disadvantage of the device is its complexity, since the increase in speed in it is achieved by increasing the number of meters and devices issuing stimulating effects, which allows you to organize control of several parameters in the control object at the same time. At the same time, the device lacks the ability to implement optimal troubleshooting procedures, which reduces its performance.

 The technical result is to simplify the device and improve performance by applying optimal troubleshooting procedures in the control object.

 The technical result is achieved by the fact that in the device for controlling parameters, containing the information output unit, the first and second switches, stimulating signal unit, analysis unit, register unit, control unit, the first outputs of which are connected to the first information inputs of the information output unit, second outputs - to the information inputs of the block of registers, the first outputs of which are connected to the inputs of the block of stimulating signals, the first information inputs and outputs of the second switch are information inputs ami outputs of the device for connecting to the inputs and outputs of the monitoring object, the second information inputs are connected to the outputs of the stimulating signal block, a normalizer block, a maximum signal extraction block, a minimum signal extraction block, an analog-to-digital converter, the information outputs of which are connected to the second information inputs, are introduced information output unit, the analog input is connected to the output of the maximum signal extraction unit, the control input is connected to the control input of the information output unit and the third output of the control unit, the second outputs of the register block are connected to the control inputs of the second switch, the third outputs are connected to the control inputs of the first switch, the fourth outputs are connected to the control inputs of the normalizer block, the information inputs of which are connected to the second information outputs of the second switch, and the outputs are connected to information inputs of the first switch, the first and second outputs of which are connected to the inputs respectively of the maximum signal allocation unit and the minimum allocation unit signal, the outputs of which are connected respectively to the first and second inputs of the analysis unit, the output of which is connected to the first input of the control unit, the second and third inputs of which are the control inputs of the device, the fourth output is connected to the first control input of the register block, the third input to the second control input block registers.

 The control unit comprises a pulse generator, a single vibrator, a trigger, a subtracting counter, a register, an AND element, a read-only memory, the first address input of which is the first input of the control unit, the second address inputs are connected to the information outputs of the register, the first and second outputs are respectively the first and the second outputs of the control unit, the third outputs are connected to the information inputs of the register, the fourth outputs to the information inputs of the subtracting counter, and the fifth output to the first input element And, and to the first control input of the trigger, the second control input of which is the second input of the control unit, the output is connected to the control input of the pulse generator, the output of which is connected to the first control input of the subtracting counter, the second control input of which is connected to the first control input of the register and is the third input of the control unit, the output is connected to the input of a single vibrator, the output of which is the fourth output of the control unit and connected to the second control input of the register, the third directs input of the subtracter counter third control input of the flip-flop and the second input of AND gate whose output is the third output of the control unit.

 The structural diagram of the proposed device differs from the known one in that it includes blocks for extracting the maximum and minimum signals, a block of normalizers, an analog-to-digital converter, which are standard units of analog and digital computing equipment. In addition, the structure of the control unit has been changed. However, despite the fact that the introduced blocks are standard nodes of analog and digital computing, their introduction, as well as the emergence of new functional relationships between them and existing blocks, makes it possible to manifest a new property in the device. Namely: the device allows to reduce the time for troubleshooting in the control object due to the application of optimal search procedures that take into account both the probability of failure of individual elements of the control object and the time spent on individual control operations - tests. The construction of an optimal procedure for troubleshooting can be done using methods known in the theory of automatic control and troubleshooting (G. Pashkovsky, Problems of Optimal Detection and Search for Failures in CEA / Edited by I. A. Ushakov. - M .: Radio and communication, 1981. - 280 p.). Application of the optimal troubleshooting procedure allows to reduce the time spent on determining the true state of the monitoring object, and, therefore, to increase the speed of the device for monitoring parameters. In addition, a fairly simple structure of the control unit is proposed, which ensures the implementation of optimal troubleshooting procedures (in the prototype, a control computer is used as the control unit). Changing the operation algorithm of the device is done by replacing the read-only memory (ROM) included in the control unit.

 The structural diagram of a device for monitoring parameters is shown in figure 1, where 1 is a control unit; 2 - information output unit; 3 - analog-to-digital Converter (ADC); 4 - block registers; 5 - block stimulating signals; 6 - analysis unit; 7 - block allocation of the maximum signal; 8 - block selection of the minimum signal; 9, 10 - respectively, the first and second switches; 11 - block normalizers; 12 - object of control. The control unit 1 includes: 13 - a pulse generator; 14 - one-shot; 15 - trigger; 16 - subtracting counter; 17 - register; 18 - element And; 19 - read-only memory (ROM). The analysis unit includes: 20, 21 - respectively, the first and second comparison units; 22 is an OR element.

 The control unit 1 is designed to control the troubleshooting process in the control object 12. The pulse generator 13 is designed to synchronize the operation of the control unit 1 and the entire device. The one-shot 14 is designed to generate a pulse when zeroing the subtracting counter 16, the signal from the output of which is fed to the input of the one-shot. On the trailing edge of the pulse from the output of the one-shot, a record is made in the subtracting counter 16, the information register 17 from the corresponding outputs of the ROM 19. The trigger 15 on the "Start" signal goes into a single state and from this moment the troubleshooting procedure begins in the monitoring object. When a faulty element is detected, the logical unit level is set at the fifth output of the ROM 19, and upon the arrival of a pulse from the one-shot 14 to the third control input of the trigger 15, it goes to the zero state, and the troubleshooting process is suspended. Before subtracting the next control operation, a number proportional to the time it takes to execute this operation is written into the subtracting counter 16. Upon receipt of the first control input of the subtractive counter 16 pulse from the pulse generator 13, the contents of the subtractive counter 16 decreases by one. When zeroing the subtracting counter 16 at its output, the level of the logical unit is established, which is a sign that the current control operation is completed. Register 17 is designed to store the number of the current control operation (test). At the output of element And 18, a pulse appears when a faulty element is detected (when the level of the logical unit appears at the fifth output of the ROM 19 and the pulse arrives from the output of the pulse generator 13). On the leading edge of this pulse, the number of the failed element is recorded in the information output unit (from the first outputs of the ROM 19) and the ADC 3 is started to measure the signal at the output of the failed element. ROM 19 is intended for storing digital codes used in the process of performing the optimal troubleshooting procedure in the monitoring object. As a control unit 1, a general-purpose computer may also be used.

 The information output unit 2 is designed to display the number of the failed element and the signal level at its output.

 ADC 3 is designed to convert analog signals into a digital code.

 The block of registers 4 is designed to store the current control codes for the block of stimulating signals 5, the first and second switches 9, 10, the block of normalizers 11.

 Block stimulating signals 5 is intended for the issuance of effects on the control object 12 during the implementation of a control operation. The type and level of stimulating signals is set using codes coming from the first outputs of the block of registers 4.

 The analysis unit 6 is intended to determine whether or not one or another parameter of the control object is within the tolerance. The first comparison unit 20 is used to compare the input signal with the upper tolerance on the parameter (voltage U1 corresponds to the upper tolerance), and the second comparison unit 21 is used for comparison with the lower tolerance (voltage U2 corresponds to the lower tolerance). If the signals supplied to the inputs of the analysis unit do not correspond to one of the tolerances, the logical unit level is set at the output of the corresponding comparison unit 20, 21, then the OR element 22 is triggered, which leads to the appearance of the logical unit level at the output of the analysis unit 6.

 Blocks highlighting the maximum and minimum signals 7, 8 respectively determine the value of the maximum and minimum among the signals supplied to their inputs. Blocks for extracting maximum and minimum signals of high accuracy can be built on operational amplifiers (Alekseenko A.G., Kolombet E.A. Starodub G.I. Application of precision analog ICs. - M.: Radio and communication, 1981. - p. 193 , Fig. 7.24).

 Using the first switch 9, the necessary outputs of the normalizer block 11 are connected to the inputs of the allocation blocks of maximum 7 and minimum 8 signals.

 Using the block of normalizers 11, the preliminary processing of signals coming from the object of control 12 (amplification, conversion, etc.) is performed. The operating modes of the normalizers (for example, the gain) are set using codes from the fourth outputs of the register block 4.

 The second switch 10 is designed to supply stimulating effects to the control object 12 from the output of the block of stimulating signals 5 and connect the control points of the control object to the corresponding inputs of the block of normalizers 11. The circuit of the second switch 10 is shown in Fig.2. To expand the switching capabilities, a special key connection scheme is used, which differs from the commonly used fully accessible switches, which are a combination of vertical and horizontal buses connected at the intersection points with a controlled key (Baida N.P., Mesyura V.I., Roik A.M. REA self-learning analyzers of manufacturing defects. - M .: Radio and communications, 1991. - p. 65, Fig. 2.17). As can be seen from figure 2, in the second switch 10, the vertical and horizontal buses are interconnected by a system of two independently controlled switched contacts. If necessary, make numerous connections both between the block of stimulating signals, the block of normalizers and the control object, as well as the switching of individual outputs of the control object, the proposed switch construction scheme, as will be shown below, can significantly reduce the number of switching elements. In figure 2, the dashed arrows show the signal paths between the individual units of the device.

 The optimal procedure for troubleshooting in the control object, as a rule, is based on the so-called functional-logical model of the control object (G. Pashkovsky, Problems of Optimal Detection and Search of Failures in CEA / Edited by I. A. Ushakov. - M. : Radio and Communications, 1981. - p. 9, Fig. 1.1), which represents the control object in the form of a set of blocks connected by functional links. Figure 3 shows an example of a functional-logical model of the control object 12, consisting of five blocks connected by functional relationships.

A prerequisite for constructing optimal troubleshooting procedures that reduce the time to identify all failed elements is the ability to conduct so-called multi-element tests. For example, in FIG. 3, applying signals x ₁ and x ₂ to the inputs of the control object 12 and measuring the signal level at the output of the third element at ₁ , when this signal is within the specified limits, we can conclude that all five elements of the control object are in good condition. Applying successively different tests, it is obviously possible to determine the true state of all elements of the object of control.

However, functional connections between individual elements do not always exist in the control object. Moreover, in some cases, it is possible to implement multi-element tests by introducing artificial connections between the individual elements of the control object using a switch. Figure 4 shows an example of the implementation of a multi-element test in such a way when, using the second switch 10, functional connections are introduced between the output of the element 12 ₁ and the input of the element 12 ₂ , as well as between the output of the element 12 ₂ and the input of the element 12 ₃ of the control object 12. Note that to implement such a connection scheme (Fig. 4), a switch with a 16th relay having one switchable contact is needed. When using a fully accessible switch to implement such a connection scheme, a switch with 32 relays with one make contact would be required. Thus, the proposed design of the switch allows you to reduce the number of used switching elements (relays).

The disadvantage of the method of constructing multi-element tests shown in FIG. 3, there is also the possibility of a “compensation” effect when a failure of one element is compensated by failures in other elements. Figure 3 shows an example of building a multi-element test, free from this drawback, and the implementation of which is possible using the proposed device. Its essence lies in the fact that when a certain input action is applied, for example, x ₁ and x ₂ , then the signals at the outputs of the fourth, fifth and third elements of the control object 12 are simultaneously analyzed. These signals are fed through the second switch 10, the block of normalizers 11 and the first switch 9 to the inputs of the extraction blocks with a maximum of 7 and a minimum of 8 signals, the output signals of which are fed to the corresponding inputs of the analysis block 6. At the output of the analysis block 6 (or element OR 22), obviously, there will be a zero level only if when all the signals in the monitoring object (fed to the input of the blocks for extracting the maximum and minimum signals 7, 8) will be within the specified limits. The advantage of this method of organizing multi-element tests is also that it does not require the presence of functional relationships between the individual elements of the control object. Note also that for the correct operation of blocks 7 and 8, the unused inputs of the maximum signal extraction unit 7 must be supplied with a certain voltage level U _min , which is less than any possible signal coming from the control object, and the level must be supplied to the unused inputs of the minimum signal 8 extraction unit voltage U _max , which is greater than any possible signal coming from the control object 12. This is ensured by the use of 9 switching contacts in the first switch.

 Thus, the proposed device allows you to implement three methods for implementing multi-element tests (they are shown in figure 3, 4, 5), which is quite enough for many practical applications.

Functional-logical model of the control object is also presented in tabular form. For the control object of five elements depicted in FIG. 3, the functional-logical model may have the form shown in Table 1 (G. Pashkovsky, Problems of Optimal Detection and Search of Failures in CEA / Ed. By I. A. Ushakov. - M.: Radio and Communications, 1981. - p. 126, table 3.5). (Since in this case it is implied that it is possible that the control object is in good condition, a dummy sixth element is introduced into the functional-logical model). The tabular model describes the tests (t ₁ -t ₁₃ ), the use of which is possible in the process of troubleshooting. Each test consists of a set of 1 and 0, depending on whether or not this test controls the corresponding element. Each test corresponds to the time spent on it (the last column in table 1). It is assumed that the failure probabilities Q of the individual elements of the control object are also known (the last row in Table 1).

When determining the true state of all elements of the control object for a given case, as shown in (G. Pashkovsky, Problems of Optimal Detection and Search of Failures in CEA / Ed. By I.A. Ushakov. - M.: Radio and Communication, 1981. - p. 127, Fig. 3.8), the optimal search procedure for the functional-logical model of Table 1 should have the form shown in Fig. 6. The optimal search procedure is displayed as a graph. The t ₉ test should be applied first. If the test outcome is negative (among the elements controlled by this test, there are faulty elements), transition along edge 1 occurs and the next test t ₁₂ is applied. With a positive outcome of the test, the transition occurs along the edge 0. Upon reaching the hanging vertex, a faulty element is determined, the number of which in Fig. 6 is enclosed in a rectangle. The search procedure ends with a test t ₁ .

 The troubleshooting procedure is recorded in the ROM 19 of the control unit 1. The contents of the ROM 19 for the search procedure shown in Fig.6, are given in table.2.

 The troubleshooting program is recorded in the ROM 19 as a sequence of words. Addresses of words are given in the second column "Address". The address value is given both in decimal and in binary (in brackets). In binary form of address recording, the most significant bit is selected, it is formed by a signal from the output of analysis block 6. Each word written in ROM 19 has three fields. The first field "Test number" contains the test code in accordance with Table 1 (the table shows the decimal value of this code and in brackets its binary representation).

 The “Runtime” field contains a number corresponding to the runtime of this test (it consists of the time for switching the signals, the time of the establishment of the signals at the output of the stimulating signal block, the time of the establishment of the signals at the output of all elements of the control object 12, etc.) The “Failed item” field contains the code of the item, the malfunction of which is detected when the corresponding test fails. The "End sign" field indicates that when the last test was performed, a failed element was detected. The execution of the search program is suspended if this field contains one. The seventh column of Table 2 contains the control codes that must be recorded in the block of registers 4, when implementing this test. From the output of the block of registers 4, these codes go to the control inputs of the block of stimulating signals 5, the first and second switches 9, 10, the block of normalizers 11. The values of these codes depend on the specific implementation of blocks 5, 9, 10, 11 and therefore, in Table 2, they not shown.

 Consider the operation of the device when performing the troubleshooting procedure in accordance with FIG. 6. Assume also that in the control object, the functional-logical model of which corresponds to the table. 1, the fourth and second elements failed.

The operation of the device begins with the supply to the third input of the control unit 1 (input "Reset") of a pulse, by which the register 17 is reset, and a unit is written into the subtracting counter 16. The block of registers 4 is also reset. The zero code from the output of register 17 is supplied to the second address inputs of the ROM 19. As follows from Table 2, regardless of what will be on the first address input of the ROM 19 (1st or 17th line in table 2), at the third outputs the code of number 9 is set, i.e. the test number t ₉ , which should be performed at the beginning of the search procedure (top vertex in Fig.6).

Next, a pulse is supplied to the second input of the control unit 1 (input "Start"), so that the trigger 15 will be transferred to a single state. The level of a logical unit from its output will go to the control input of the pulse generator 13, and from its output pulses will begin to arrive at the first control (subtracting) input of the subtracting counter 16. Since the unit was written to it by the “Reset” signal, after the first pulse the contents of the subtracting counter 16 will become equal to zero, and at its output the level of the logical unit will be established, according to which the one-shot 14. The pulse from the output of the one-shot 14 will go to the inputs of the register register 17 and the subtracting counter 16. In this case, the register 17 s 9 written code number (number of the first test performed) from the third output of ROM 19, and in the down counter 16 can be written with the fourth unit of the ROM 19 outputs (to conduct the test costs t ₉ are equal to one, see. Table 1).

On a pulse from the output of the one-shot 14, the control codes for the block of stimulating signals 5, the first and second switches 9, 10 and the block of normalizers 11 will be written from the second outputs of the ROM 19 to the block of registers 11. From the first outputs of the block of registers 4 a code corresponding to the test t ₉ will be sent to the inputs of the block of stimulating signals 5, in accordance with which the necessary level of stimulating signals will be set. From the second outputs of the block of registers 4, a corresponding code will be supplied to the control inputs of the second switch 10, in accordance with which the outputs of the block of stimulating signals 5 and the inputs of the block of normalizers 11 will be connected to the control points of the control object in such a way as to ensure the execution of test t ₉ . From the third and fourth outputs of the block of registers 4 codes will also be sent to the control inputs of the first switch 9 of the block of normalizers 11, and thus the modes of operation of these blocks corresponding to the test t ₉ will be set.

The test t _{9 starts} . Test t ₉ controls the 1st, 3rd, 4th and 5th elements of the object of control 12 (see table 1). Accordingly, using the first and second switches, the outputs of the elements 1, 3, 4, 5 of the control object 12 will be connected to the inputs of the allocation blocks of maximum 7 and minimum 8 signals (Fig. 5). Since we assumed that the 4th element is faulty in the control object 12, this means that the signal at its output has left the tolerance zone (and has the largest deviation from the nominal value). If the signal from the output of this element exceeds the upper tolerance, then it will be detected using the maximum signal extraction unit 7, and if it is less than the lower tolerance, it will be selected by the minimum signal extraction unit 8. The first 20 or second 21 comparison unit will work, incoming analysis block 6 (depending on which tolerance has been exceeded). Next, the OR element 22 will work, and at the output of the analysis unit 6, the level of the logical unit will be set, which will go to the first address input of the ROM 19. Given that the code number 9 is installed on the second address inputs of the ROM 19 (from the outputs of the register 17), at the third outputs of the ROM 19, the code of number 12 will appear (26th row, third column of Table 2), i.e. the number of the next test to be performed is t ₁₂ . After zeroing the subtracting counter 16, the one-shot 14 will work and the code of the number 12 will be written into the register 17, and the code of the number 7 will be written into the subtracting counter (the cost of the test is t ₁₂ ). In the block of registers 4 will be written the control codes necessary for the test t ₁₂ for blocks 5, 9, 10, 11 from the second outputs of the ROM 19. From the outputs of the block of registers 4, the codes will go to the control inputs of the first 9 and second 10 switches, the block of stimulating signals 5 and normalizer block 11. Test t ₁₂ starts.

Since the fourth element of the control object is conditionally faulty, after the test t _{13 is completed} , the level of the logical unit is set at the output of the analysis unit, and taking into account that the number 12 code is set at the second address inputs of the ROM 19, the number 4 code is set at the first outputs of the ROM 19, t .e. the number of the faulty element (row 29, column 5 of table 1). At the same time, the logical unit level will appear on the fifth output of ROM 19 (row 29, column 6 of table 1). After zeroing the subtracting counter 16, the single-shot 14 will work. Since the logical unit will be at the first input of the And 18 element, the pulse from the output of the one-shot 14 will go through the And 18 and will go to the control inputs of the information output unit 2 and ADC 3. On the leading edge of this pulse in information output unit 2, the number of the failed element will be recorded, as well as the result of the conversion from the output of the ADC 3, i.e. the value of the signal level at the output of the failed element.

On the negative edge of this pulse, a code of 6 will be written in register 17, i.e. next test number t ₆ .

 Under the influence of a pulse from the output of the element And 18, as well as the level of the logical unit from the fifth output of the ROM 19, the trigger 15 will go to the zero state, the zero logic level from its output will block the pulse generator 13, and the troubleshooting procedure will stop.

 The operator has the ability to record the number of the failed element and the signal level at its output.

To continue the search procedure, it is necessary to apply a pulse to the “Start” input of the device. The next test performed will be t ₆ , etc. The search for the remaining failed elements is performed in a similar way. The test t ₁ is performed last (in this case, the state of the second element of the control object 12 will be determined), and the operation of the device ends there.

Thus, the device allows you to organize troubleshooting in the control object according to the optimal control programs and, therefore, increase the speed of the device. In accordance with (G. Pashkovsky, Problems of Optimal Detection and Search of Failures in CEA / Ed. By I. A. Ushakov. - M.: Radio and Communications, 1981. - P. 127, Fig. 3.8) average search time all failed elements will be 15.7 seconds (it is assumed that the time required to complete the tests in Table 1 is given in seconds). At the same time, if you consistently check all the elements of the control object one at a time, then the time to determine the true state of the control object will be 6 + 7 + 9 + 7 + 8 = 37 sec (total test time t ₁ , t ₂ , t ₁₁ , t ₁₂ , t ₁₃ ). Therefore, the proposed device can reduce the troubleshooting time in the object of control.

 The simple structure of the control unit, fewer meters will allow you to create inexpensive and versatile devices to control the parameters of various objects. Having selected the ROM 19 in a separate chip with the possibility of its replacement, you can easily change the algorithm of the device and adjust it to control specific objects of control.

Claims (2)

 1. A device for monitoring parameters, comprising an information output unit, first and second switches, a stimulating signal unit, an analysis unit, a register unit, a control unit, whose first outputs are connected to the first information inputs of the information output unit, and the second outputs to information inputs of the register unit the first outputs of which are connected to the inputs of the block of stimulating signals, the first information inputs and outputs of the second switch are information inputs and outputs of the device for connecting to the inputs and outputs of the control object, the second information inputs are connected to the outputs of the stimulating signal block, characterized in that a normalizer block, a maximum signal extraction block, a minimum signal extraction block, an analog-to-digital converter, information outputs of which are connected to the second information inputs of the information output block, are introduced into it; the analog input is connected to the output of the maximum signal extraction unit, the control input is connected to the control input of the information output unit and the third output of the control unit phenomena, the second outputs of the register block are connected to the control inputs of the second switch, the third outputs are with the control inputs of the first switch, the fourth outputs are with the control inputs of the normalizer block, the information inputs of which are connected to the second information outputs of the second switch, and the outputs are connected to the information inputs of the first switch , the first and second outputs of which are connected to the inputs, respectively, of the maximum signal extraction unit and the minimum signal extraction unit, the outputs of which x are connected respectively to the first and second inputs of the analysis unit, the output of which is connected to the first input of the control unit, the second and third inputs of which are the control inputs of the device, the fourth output is connected to the first control input of the register block, and the third input is connected to the second control input of the register block.  2. The device according to claim 1, characterized in that the control unit comprises a pulse generator, a single vibrator, a trigger, a subtracting counter, a register, an AND element, a read-only memory device, the first address input of which is the first input of the control unit, the second address inputs are connected to information the outputs of the register, the first and second outputs are respectively the first and second outputs of the control unit, the third outputs are connected to the information inputs of the register, the fourth outputs are to the information inputs of the subtracting counter and the fifth output is to the first input of the And element, and to the first control input of the trigger, the second control input of which is the second input of the control unit, the output is connected to the control input of the pulse generator, the output of which is connected to the first control input of the subtracting counter, the second control input of which connected to the first control input of the register and is the third input of the control unit, the output is connected to the input of a single vibrator, the output of which is the fourth output of the control unit and connected to the second control yayuschim register input, the third control input of the subtracter counter third control input of the flip-flop and the second input of AND gate; the output of which is the third output of the control unit.

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