RU2417044C1 - Measurement unit for pass band of receptive fields of visual neurons - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medical equipment. A unit comprises a toggle switch, first-third keys, a mode switch, a ramp voltage generator, first-fourth analogue multiplexers, first-third units of ten analogue multiplexers, first-third multiplexers, first-second units of ten voltage-frequency converters, a second pulse generator, a counter, a calculator, first-second encoders, first-second shift registers, a register, first-second analogue memories, an arithmetic/logic unit, a trigger, a first-second gates, first-sixth single vibrators, first-fourth OR elements, first-second units of resistance dividers, a units of ten keys, a light pulse source unit and first-second display units.

EFFECT: use of the device enables cutting measuring time of pass-band of receptive fields of visual neurons.

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Description

The invention relates to medical equipment and is intended to determine the passband of the receptive fields of the neurons of the visual system.

A device is known for processing impulse activity of neurons and constructing spatial-frequency characteristics of receptive fields of the visual system, containing a linear filter, a nonlinear filter, a block for allocating informative sections in the impulse activity of neurons, an OR circuit, an address code generation unit, an And circuit, memory and arithmetic analyzer devices, stimulus movement control device [1, Fig. 77, p. 140]. If there are signals at all three inputs of the AND circuit, the pulses of the process under study are sent to the arithmetic device of the analyzer, summed and transmitted to the storage device at the address corresponding to the spatial frequency and position of the area allocated by the block for the selection of informative areas in the impulse activity of neurons. The analyzer memory is divided into groups, the number of which corresponds to the number of sections allocated in the impulse activity of neurons, the number of memory cells in each group is equal to the number of stimuli, and an estimate of the response of a neuron to a specific spatial frequency is recorded in each cell. The procedure for presenting the entire set of stimuli, which are lattices with different spatial frequencies, is repeated several times [1, p.141].

It is known to determine the bandwidth of receptive fields of neurons of the visual system using arrays of different spatial frequencies with a sinusoidal distribution of illumination [2]. For the formation of images of various shapes — a world of variable contrast, different spatial frequencies with a sinusoidal brightness profile, two-dimensional gratings with a sinusoidal brightness distribution — a programmable synthesizer is known that contains a microcomputer, an interface, a control synchronization unit, a test answer input panel, video buffer memory, a digital-to-analog converter, video monitoring device, operator terminal and plotter [3, Fig. 38, p. 68]. The formed images are displayed on the screen of the video monitoring device, the test subject is entered into the computer by pressing the buttons - “see” - “do not see” [3, p. 84].

The disadvantages of the known devices are the long preparatory period, the need for special equipment, the complexity of research.

Closest to the technical nature of the present invention is a device for determining the passband of the receptive fields of neurons of the visual system, containing a mode switch, a ramp generator, a voltage-frequency converter, a light pulse source, an OR element, a calculator and a block of indicators, and the output of the mode switch connected to the input of the generator, the output of the OR element is connected to the first input of the calculator, the second input of which is connected to the output of the converter I voltage-frequency, and the output is with the input of the indicator block, the output of the voltage-frequency converter is also connected to the input of the light pulse source, characterized in that it additionally includes a second mode switch, a second linear voltage generator, a second indicator block, second generator pulses, analog multiplexer, counter, first to third demultiplexers, trigger, first and second valves, first to third single vibrators, first to sixth keys and toggle switch, and the outputs of the first and second key th are connected to the inputs of the first and second mode switches, the outputs of the third to fifth keys are connected respectively to the information inputs of the first to third demultiplexers, the first outputs of which are connected to the inputs of the first mode switch, the second outputs to the inputs of the second mode switch, the output of the sixth key is connected to - the trigger input, the output of which is connected to the first input of the first valve, the R-input is connected to the second output of the calculator, and the D-input - with the normally open output of the toggle switch, normally closed output which is connected to the first input of the second valve, the output of the second mode switch is connected to the input of the second ramp generator, the outputs of the first and second ramp generators are connected to the information inputs of the analog multiplexer, the output of which is connected to the voltage-frequency converter input, the output of the second pulse generator connected to the address input of the analog multiplexer, second inputs of the first and second gates and address inputs of the first to third demultiplexers, the output of the first gate is connected to the inputs of the first and second single vibrators, the outputs of which are connected to the inputs of the OR element, the inverse output of the second gate is connected to the input of the third single vibrator and the counter resolution input of the counter, the counting input of which is connected to the voltage-frequency converter output, the zeroing input is with the output of the third one-shot, and the output with the input of the second block of indicators [4].

The disadvantage of this device is the duration of the measurement procedure, which limits its use in mass surveys.

The technical result of the claimed device is to reduce the measurement time.

The technical result is achieved by the fact that the device contains a toggle switch, first-third keys, a mode switch, a ramp generator, an analog multiplexer, a second pulse generator, a counter, a computer, a trigger, the first-second valves, the first-third one-shots, the OR element and the first - the second blocks of indicators, the outputs of the first or second keys are connected to the inputs of the mode switch, the output of which is connected to the input of the ramp generator, the output of which is connected to the first input analog analog multiplexer, the second input of the calculator is connected to the output of the first OR element, and the outputs are connected to the inputs of the first block of indicators, the output of the second pulse generator is connected to the first input of the second valve, the output of which is connected to the counting input of the counter, the outputs of which are connected to the inputs of the second block of indicators, moreover, the second and fourth analog multiplexers, the first and third blocks of ten analog multiplexers, the first and third multiplexers, the first and second blocks of ten voltage-frequency converters, first-second encoders, first-second shift registers, register, first-second analogue storage devices, arithmetic-logical device, fourth-sixth single-vibrators, second-fourth OR elements, first-second resistive divider blocks, block of ten keys and a block of light pulse sources, normally closed and normally open outputs of the toggle switch are connected to the inputs of the first encoder, the output of which is connected to the address inputs of analog multiplexers the first block, the first inputs of which are connected to the output of the ramp generator, the second inputs are with the outputs of the analog multiplexers of the second block, the outputs are with the inputs of the converters of the first block, the outputs of which are connected to the second inputs of the light pulse source block, the second inputs of the second valve and the inputs of the first a multiplexer whose address inputs are connected to the outputs of the first gate, and the output to the first input of the second multiplexer, the second input of which is connected to the output of the third multiplex a, the address input is with the output of the second pulse generator, and the output is with the first input of the calculator, the output of the third key is connected to the input of the first shift register, the first output of which is connected to the first input of the second OR element, the second output to the first input of the third OR element, the third output is with the second inputs of the second or third OR elements and address inputs of the multiplexers of analogue second-third blocks, the output of the second OR element is connected to the input of the fourth one-shot, the output of which is connected to the second input of the first of an analogue storage device, the first input of which is connected to the output of the first analog multiplexer, and the output is connected to the inputs of the dividers of the first block, the first and second outputs of which are connected respectively to the first and second inputs of the analog multiplexers of the second block, the output of the third element OR is connected to the input of the fifth one-shot the output of which is connected to the second input of the second analog storage device, the first input of which is connected to the output of the second analog multiplexer, and the output to the inputs of affairs the second block, the first-second outputs of which are connected respectively to the first-second inputs of the analog multiplexers of the third block, the outputs of which are connected to the inputs of the fourth multiplexer and the inputs of the converters of the second block, the outputs of the converters of the second block are connected to the first inputs of the block of light pulse sources and the inputs of the third multiplexer the address inputs of which are connected to the outputs of the first valve, the output of the ramp generator is also connected to the first input of the second an analog multiplexer, the second input of which is connected to the output of the fourth multiplexer, the address input is connected to the trigger output, the trigger output is also connected to the address input of the first analog multiplexer, the second input of which is connected to the output of the third analog multiplexer, the inputs of which are connected to the outputs of the analogue second multiplexers , address inputs - with register outputs, register outputs are also connected to the first inputs of the first gate and the second inputs of the arithmetic-logic device, on the first inputs of which code A is supplied, and the outputs are connected to the address inputs of the fourth analog multiplexer, the outputs of the key block are connected to the inputs of the fourth OR element and the second encoder, the outputs of the second encoder are connected to the first inputs of the register, the output of the fourth OR element is connected to the input of the sixth one-shot, output which is connected to the second input of the register and the input of the second shift register, the first output of which is connected to the S-input of the trigger, the second output - with the R-input of the trigger and the second input of the first gate, you od second pulses of the generator is also connected to the inputs of the first to third monostable multivibrator, the output of the first monostable coupled to a first input of the first OR gate, the output of the second monostable coupled to a second input of said first OR gate, the output of the third monostable multivibrator coupled to the R-input of the counter.

Figure 1 presents the structural diagram of the inventive device, figure 2 is a diagram of the blocks of resistive dividers, figure 3 is the location of the LEDs and their corresponding keys, made in the form of buttons.

The device contains a toggle switch 1, first to third 2-4 keys, a switch of 5 modes, a generator 6 of linearly varying voltage, the first to fourth 7-10 analog multiplexers, the first to third 11-13 blocks of ten analog multiplexers, the first to third 14-16 multiplexers, first-second 17-18 blocks of ten voltage-frequency converters, 19 second pulse generator, counter 20, calculator 21, first-second 22-23 encoders, first-second 24-25 shift registers, register 26, first-second 27-28 analog storage devices, arithmetic Logic device 29, trigger 30, first-second 31-32 gates, first-sixth 33-38 single vibrators, first-fourth 39-42 OR elements, first-second 43-44 resistive divider blocks, block 45 of ten keys, block 46 light pulse sources and first to second 47-48 indicator blocks.

The toggle switch 1 is intended for setting the modes of setting the frequency of light flickering and determining the passband of the receptive fields of the neurons of the visual system.

The first 2 switch is designed to set the generator 6 in the mode of generating a ramp voltage corresponding to a change in frequency at the output of the voltage-frequency converter 14 at a speed of 1 Hz / s.

The second 3 switch is used to set the generator 6 in the mode of generating a linearly incident voltage corresponding to a change in frequency at the output of the voltage-frequency converter 14 at a speed of 1 Hz / s.

The third 4 key is intended for fixing the frequencies of light flickers established or fixed by the test subject.

Keys 2-4 are manual switches to two positions for closing and opening electrical control circuits and are made in the form of control buttons.

Devices 27-28 analog storage devices are designed to store voltage and can be performed, for example, according to the scheme [5, Fig. 8.17, p.240].

Arithmetic-logic device 29 is intended to calculate the function AB-1, where A and B are input variables, and can be performed, for example, on the chip 564 IPZ [5, p.75-79].

Trigger 30 is a standard RS trigger with a null input.

The remaining functional units of the structural diagram correspond to the prototype or are well known.

The device operates as follows. In the initial state, the toggle switch 1 is in a position corresponding to the setting mode of the frequency of light flickering, as shown in figure 1. When the power is turned on, the code 1000 is written to the shift register 24, the code 100 is written to the shift register 25, the binary code of the number corresponding to the number 12 in the decimal code is supplied to the inputs of the arithmetic logic device 29, register 26 and the counter 20 are reset, trigger 30 is turned off ( the circuit is not shown), the generator 19 generates second pulses, the generator 6 generates a constant voltage output corresponding to the frequency of light flicker at the outputs of the converter unit 17, equal to 25 Hz, that is, the average frequency of the received visible range of lights flicker from 0 to 50 Hz.

In this case, the voltage from the output of the generator 6 through the multiplexers of the block 11 is supplied to the converters of the block 17, where it is converted to frequencies that control the second LEDs of the block 46. The frequency from the output of the first converter of the block 17 is supplied to the valve 32. When the signal of a logical unit at the output of the generator 19, the valve 32 opens, on the leading edge of each signal of a logical unit from the output of the generator 19, the single-shot 35 generates a short pulse, resetting the counter 20. The frequency from the output of the first converter of block 17 through the open first gate 32 is fed to the count input of the counter 20, the count value displayed on unit 48 displays.

The test key closure 2 or 3 sets the specified initial F _N light flicker frequency, taken as the average frequency of the determined passband of the receptive fields of the neurons of the visual system.

To set the initial F _N light flicker frequency greater than 25 Hz, the test person closes the key 2. The signal from the output of the key 2 through the mode switch 5 sets the generator 6 to the mode of linearly increasing voltage generation at a given speed. The control of the second LEDs of block 46 and the output of the result of counting the frequency of light flickers to block 48 of the indicators is carried out similarly as described above.

To set the initial F _N light flicker frequency, less than 25 Hz, the test person closes the key 3. The signal from the output of the key 3 through the mode switch 5 sets the generator 6 to the mode of linearly incident voltage generation at a given speed. The control of the second LEDs of block 46 and the output of the result of counting the frequency of light flickers to block 48 of the indicators is carried out similarly as described above.

When the keys 2 or 3 are opened, the generator 6 stores at the output a constant voltage corresponding to the set initial F _N light flicker frequency at the output of the transducers of block 17.

The test subject closes key 4 briefly (for the first time). The pulse from the output of the key 4 shifts the state of the register 24 by one bit to the right, the signal of the logical unit from the first output of the register 24 passes through the 40 element OR to a single-shot 36, which generates a pulse along its leading edge that arrives at the device 27. The voltage 27 is stored in the device 27, coming from the output of the generator 6 through the multiplexer 7, corresponding to the set initial F _H light flicker frequency at the output of the converters of block 17.

The test by closing the key 2 sets the incremental F _{AND the} frequency of light flicker equal to F _N +2.5 Hz. The signal from the output of the key 2 through the switch 5 modes sets the generator 6 in the mode of generating a ramp voltage with a given speed. The control of the second LEDs of block 46 and the output of the result of counting the frequency of light flickers to block 48 of the indicators are carried out similarly as described above.

The test subject closes key 4 for a short time (second time). The pulse from the output of the key 4 shifts the state of the register 24 by one bit to the right, the signal of the logical unit from the second output of the register 24 through the element 41 OR is fed to a single-shot 37, which generates a pulse from its leading edge to the device 28. The voltage is stored in the device 28, coming from the output of the generator 6 through the multiplexer 8, corresponding to the installed incremental F _{And the} frequency of light flicker at the output of the converters of block 17.

The test subject switches the toggle switch 1 to the position corresponding to the measurement mode. The voltage from the device 27 corresponding to the initial F _N light flicker frequency is supplied to the block 43 of the dividers, from the first outputs of which ten constant voltages through the multiplexers of the blocks 12 and 11 are respectively supplied to the inputs of ten converters voltage-frequency of the block 17. At the output of the first converter is formed decrement frequency equal to F _N -0.25 Hz, at the output of each subsequent converter, a frequency is formed that is reduced in comparison with the frequency at the output of the previous converter by 0.25 Hz The frequencies from the outputs of ten voltage-frequency converters of the block 17 are respectively supplied to the block 46 and control its second LEDs.

The voltage from the device 28, corresponding to the installed incremental F _{AND the} frequency of light flickering, is supplied to block 44 dividers. Voltages from the first outputs of block 44 dividers through block 13 of multiplexers are supplied to the inputs of ten voltage-frequency converters of block 18, and voltage from the tenth output goes to the input of the first converter, voltage from the ninth output to the input of the second converter, etc. An incremental frequency equal to F _Н +2.5 Hz is formed at the output of the tenth voltage-frequency converter of block 18, and a frequency reduced by 0.25 Hz compared to the frequency at the output of the subsequent converter is formed at the output of each previous converter. The frequencies from the outputs of the ten voltage-frequency converters of block 18 are respectively supplied to block 46 and control its first LEDs.

At the first stage of measurements, the test subject determines the pair of LEDs with the highest number, the frequencies of light flickering of which do not differ, and closes the corresponding key of block 45, the output signal of which goes to the encoder 23 and the OR element 42. The private key code from the output of the encoder 23 enters the register 26, the signal from the output of the element 42 OR to the one-shot 38, the pulse from the output of which writes the private key code to the register 26. The signal from the output of the one-shot 38 shifts the state of the register 25 by one bit to the right. The signal of the logical unit from the first output of the register 25 is fed to the S-input of the trigger 30 and turns it on. The signal of the logical unit from the output of the trigger 30 is supplied to the multiplexers 7 and 8.

The private key code from the output of the register 26 is supplied to the multiplexer 9 and to the inputs B of the arithmetic logic device 29, from the outputs of which the code A-B-1 is supplied to the address inputs of the multiplexer 10. The voltage corresponding to the decrement frequency F _{D1 of the} second LED of the pair with the highest number , the light flicker frequencies of which do not differ, from the output of block 43 dividers through the multiplexer of block 12, the multiplexers 9 and 7 are supplied to device 27. The voltage corresponding to the incremental frequency F _{I1 of the} first LED of the pair with the highest a meter, the light flicker frequencies of which do not differ, from the output of block 44 dividers through the multiplexer of block 13, multiplexers 10 and 8 are fed to device 28.

The test subject closes key 4 briefly (third time). The pulse from the output of the key 4 shifts the state of the register 24 by one bit to the right, the signal of the logical unit from the third output of the register 24 goes to the address inputs of the multiplexers of blocks 12, 13 and the elements 40 and 41 OR. The signal of the logical unit from the output of the OR element 40 is fed to a single-vibrator 36, which generates a pulse at its leading edge that arrives at device 27. The voltage 27 corresponding to the decrement frequency F _{D1 of the} second LED of the pair with the highest number, the frequencies of light flickering does not differ, is stored in device 27 . The logical unit signal from the output of the OR element 41 is fed to a single-shot 37, which generates a pulse along its leading edge that arrives at the device 28. The voltage corresponding to the incremental frequency F _{И1 of the} first LED of the pair with the highest number, the frequencies of light flickering does not differ, is stored in the device 28 .

The voltage from the device 27 corresponding to the decrement frequency F _{D1 of the} second LED of the pair with the highest number, the frequencies of light flickering of which do not differ, is supplied to block 43 dividers, from the second outputs of which ten constant voltages are supplied through the multiplexers of blocks 12 and 11 to the inputs of ten converters -frequency block 17. decremental frequency generated at the output of the first inverter is equal to F _D1, the frequency is generated, reduced CPA at the output of each successive inverter pared with the frequency at the output of the preceding inverter to 0.05 Hz. The frequencies from the outputs of ten voltage-frequency converters of the block 17 are respectively supplied to the block 46 and control its second LEDs.

The voltage from the device 28, corresponding to the incremental frequency F _AND 1 of the first LED of the pair with the highest number, the frequencies of light flickering which do not differ, is supplied to block 44 dividers. The voltages from the second outputs of the block 44 dividers through the block 13 of the multiplexers are supplied to the inputs of ten voltage-frequency converters of the block 18, and the voltage from the tenth output goes to the input of the first converter, the voltage from the ninth output to the input of the second converter, etc. An incremental frequency equal to F _И1 is formed at the output of the tenth converter, a frequency is reduced at the output of each previous converter, reduced by 0.05 Hz compared to the frequency at the output of the subsequent converter. The frequencies from the outputs of the ten voltage-frequency converters of block 18 are respectively supplied to block 46 and control its first LEDs.

At the second stage of measurements, the test subject determines the pair of LEDs with the lowest number, the light flicker frequencies of which differ, and closes the corresponding key of the block 45, the output signal of which goes to the encoder 23 and the OR element 42. The private key code from the output of the encoder 23 enters the register 26, the signal from the output of the element 42 OR to the one-shot 38, the pulse from the output of which writes the private key code to the register 26. At the same time, the signal from the output of the one-shot 38 shifts the state of the register 25 by one bit to the right. The signal of a logical unit from the second output of the register 25 is fed to the R-input of the trigger 30 and turns it on. At the same time, the signal from the second output of the register 25 enters the valve 31 and opens it. The closed key code from the output of the register 26 through the open valve 31 is fed to the address inputs of the multiplexers 14 and 16.

When the logic unit signal at the output of the generator 19, the frequency corresponding to the incremental frequency F _{AND2 of the} first LED of the pair with the lowest number, the frequencies of light flickering which differ, from the block 18 through the multiplexers 16 and 15 is fed to the calculator 21. When the signal is a logic zero at the output of the generator 19 corresponding to the decrement frequency F _{D2 of the} first LED of the pair with the smallest number, the light flicker frequencies of which differ, from block 17 through the multiplexers 14 and 15 is fed to the calculator 21.

On the leading edge of the signal of the logical unit from the output of the generator 19, the single-vibrator 33 generates a pulse transmitted through the OR element 39 to the calculator 21, in which the value of the frequency corresponding to the incremental frequency F _{AND2 of the} first LED of the pair with the lowest number, the light flicker frequencies of which are different, is written. On the trailing edge of the signal of the logical unit from the output of the generator 19, the single-shot 34 generates a pulse transmitted through the OR element 39 to the calculator 21, in which the value of the frequency corresponding to the decrement frequency F _{D2 of the} second LED of the pair with the lowest number, the frequencies of light flickering are recorded, is written.

The calculator 21 calculates the difference of the frequencies ΔF = F _И2 -F _Д2 fixed in the second stage, equal to the passband of the receptive fields of the neurons of the visual system relative to the initial frequency F _Н , outputs the calculation result to the block of 47 indicators, after which it generates a pulse that sets the device to its initial state ( chains not shown).

Thus, the claimed device allows to reduce the time to determine the passband of the receptive fields of the neurons of the visual system, due to which it can be used in mass examinations.

Information sources

1. Dudkin K.N., Gauselman V.E. Automation of a neurophysiological experiment. - L .: Nauka, 1979. - 160 p.

2. Kulikowski J.J., Vidyasagar T.R. Space and spatial frequency: analysis and representation in the macaque striate cortex // Exp. Brain Res. - 1986.- V.64. - No. 1. - P.6-18.

3. Shelepin Yu.E., Kolesnikova LN, Levkovich Yu.I. Visocontrastometry: Measurement of the spatial transfer functions of the visual system. - L .: Nauka, 1985 .-- 103 p.

4. RF patent 2240029, IPC АВВ 3/00. A device for determining the passband of receptive fields of neurons of the visual system / A.G. Isaev, T.A. Lezhnina, V.V. Rozhentsov (RF). - Publ. 11/20/2004. Bull. Number 32.

5. Lantsov A.L., Zvorykin L.N., Osipov I.F. Digital devices on complementary MIS integrated circuits. - M.: Radio and Communications, 1983 .-- 272 p.

Claims (1)

A device for determining the bandwidth of the receptive fields of the neurons of the visual system, containing a toggle switch, first-third keys, a mode switch, a linearly varying voltage generator, an analog multiplexer, a second pulse generator, a counter, a computer, a trigger, first-second valves, a first-third one-shot, element OR and the first or second blocks of indicators, the outputs of the first and second keys are connected to the inputs of the mode switch, the output of which is connected to the input of the ramp generator, you the stroke of which is connected to the first input of the analog multiplexer, the second input of the calculator is connected to the output of the first OR element, and the outputs to the inputs of the first block of indicators, the output of the second pulse generator is connected to the first input of the second valve, the output of which is connected to the counting input of the counter, the outputs of which are connected with the inputs of the second block of indicators, characterized in that the second to fourth analog multiplexers are additionally introduced into it, the first to third blocks of ten analog multiplexers, the first to third m ultiplexers, first-second blocks of ten voltage-frequency converters, first-second encoders, first-second shift registers, register, first-second analogue storage devices, arithmetic-logical device, fourth-sixth single-vibrators, second-fourth OR elements, first - the second block of resistive dividers, a block of ten keys and a block of light pulse sources, the outputs of the toggle switch are connected to the inputs of the first encoder, the output of which is connected to the address inputs of the multiplexers of the analogue first units, the first inputs of which are connected to the output of the ramp generator, the second inputs are with the outputs of the analogue second multiplexers, the outputs are with the inputs of the converters of the first unit, the outputs of which are connected to the second inputs of the light pulse source block, the second inputs of the second valve and the inputs of the first multiplexer whose address inputs are connected to the outputs of the first gate, and the output is to the first input of the second multiplexer, the second input of which is connected to the output of the third multiplexer, the input is with the output of the second pulse generator, and the output is with the first input of the calculator, the output of the third key is connected to the input of the first shift register, the first output of which is connected to the first input of the second OR element, the second output is with the first input of the third OR element, the third output - with the second inputs of the second or third OR elements and the address inputs of the analog multiplexers of the second and third blocks, the output of the second OR element is connected to the input of the fourth one-shot, the output of which is connected to the second input of the first device analogue storage, the first input of which is connected to the output of the first analog multiplexer, and the output is connected to the inputs of the dividers of the first block, the first and second outputs of which are connected respectively to the first and second inputs of the analog multiplexers of the second block, the output of the third OR element is connected to the input of the fifth one-shot, the output of which is connected to the second input of the second analog storage device, the first input of which is connected to the output of the second analog multiplexer, and the output to the inputs of the dividers in of the second block, the first-second outputs of which are connected respectively to the first-second inputs of the analog multiplexers of the third block, the outputs of which are connected to the inputs of the fourth multiplexer and the inputs of the converters of the second block, the outputs of the converters of the second block are connected to the first inputs of the block of light pulse sources and the inputs of the third multiplexer, whose address inputs are connected to the outputs of the first valve, the output of the ramp generator is also connected to the first input of the second an analog typlexer, the second input of which is connected to the output of the fourth multiplexer, the address input is connected to the trigger output, the trigger output is also connected to the address input of the first analog multiplexer, the second input of which is connected to the output of the third analog multiplexer, the inputs of which are connected to the outputs of the analog multiplexers of the second block, address inputs - with register outputs, register outputs are also connected to the first inputs of the first gate and the second inputs of the arithmetic-logic device, to the first inputs of which the binary code of the number corresponding to the number 12 in the decimal code is supplied, and the outputs are connected to the address inputs of the fourth analog multiplexer, the outputs of the key block are connected to the inputs of the fourth OR element and the second encoder, the outputs of the second encoder are connected to the first inputs of the register, the output of the fourth OR element connected to the input of the sixth one-shot, the output of which is connected to the second input of the register and the input of the second shift register, the first output of which is connected to the S-input of the trigger, the second output is from R-in the trigger odor and the second input of the first gate, the output of the second pulse generator is also connected to the inputs of the first or third one-shots, the output of the first one-shot is connected to the first input of the first OR element, the output of the second one-shot is connected to the second input of the first OR, the output of the third one-shot is connected to R- counter input.

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