SU1691889A1 - A holographic information permanent storage with the exchangeable holograms medium - Google Patents

Abstract

The invention relates to computing. The aim of the invention is to extend the functionality of the holographic memory, which consists in recognizing the re-reading of the carrier of the holograms and in the formation of the sign of re-use. The device contains an emitter, hologram carrier, photomatrix, erase pulse shaper, control unit, polling pulse shaper unit, address bus switch, matrix element counter, odd and even discharge switch boards, accumulation time control unit, one-shot, operational memory block, element delays, fixed memory blocks, drive, tape mechanism, pump unit, hologram counter, three code comparison blocks, comparison block, coincidence counter, decoder, damping node, trigger, four elements OR, eight elements AND, five inverters. 1 Z.p. f-ly, 3 ill. SO with

Description

The invention relates to computing.

The aim of the invention is to enhance the functionality of a holographic read-only memory device with a removable hologram carrier by enabling recognition of the re-reading of the hologram carrier and the formation of the reuse characteristic of the carrier.

FIG. 1 shows a functional diagram of the device; in fig. 2 is the same for the accumulation time control unit; in fig. 3 - the same, carrier quenching unit.

The holographic read-only memory with a removable hologram carrier contains optically coupled emitter 1, a tape carrier 2 holograms and a matrix of 3 photodetectors, the erasure bus of which is connected through the shaper 4 erase pulses to the first input of the control unit 5. The address buses of the matrix 3 are connected via the block 6 of the polling pulse drivers and the switch 7 of the address buses to the outputs of the first group of the sensor 8 matrix elements, the first input of which is connected to the second output of the control unit 5. All odd and even output (bit) buses of matrix 3 are connected via switch 9 odd bit buses and switch 10 even bit buses to the first and second, respectively, inputs of the accumulation time control unit 11, the third and fourth inputs of which are connected respectively to the first and third control unit 5 outputs

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the second and second outputs of the control unit 11 are connected respectively to the input of the single-oscillator 12 and to the information input of the 1C block (RAM, the output of the one-vibrator through the delay element 14 is connected to the first input of the first element OR 15, whose output is connected to the second (counting) input the counter 8 matrix elements and with the first input of the control unit 5, the outputs of the second group of the counter 8 matrix elements are connected to the address inputs of switches 9 and 10, the outputs of the third group of the counter 8 are connected to the address inputs of the operational memory block 13 and the address inputs of the first and second blocks 16 and 17. Constant memory, made in the form of integrated circuits, consisting of memory elements and access decryption schemes. The fourth output of the counter 8 matrix elements is connected to the second input of the control unit 5, the second output of which through the actuator 18 and the tape mechanism 19 is connected to the hologram carrier 2. The fourth output of the control unit 5 is connected to the emitter 1 via the pumping unit 20, and the fifth and sixth outputs of the control unit 5 are connected to the reset input and the counting input Etchik 21 holograms. The outputs of the hologram counter 21 are connected to the inputs of the first group of the first, second and third blocks 22-24 of the code comparison. Each of blocks 22-24 consists of m EXCLUSIVE OR elements, the outputs of which are connected to the corresponding inputs of element I. The first hologram codes (hologram A), the second hologram (hologram B) and the last hologram ( holograms N). The outputs of the first, second and third blocks 22-24 of the code comparison, respectively, through the first, second and third inverters 25-27 are connected to the corresponding inputs of the first element 28, the fourth input of which is connected to the fourth output of the counter 8 matrix elements, and the output is connected to the third the input of the control unit 5. The outputs of the first and second blocks 22, 23 of the code comparison unit are connected via the second element OR 29 to the first input of the second element AND 30, the second input of which is the third output of the accumulation time control unit 11, the output of which is connected to the second input of the first element OR 15. Outputs The first and second blocks 22, 23 of the code comparison are connected respectively to the first inputs of the third and fourth elements I 31 and 32, to the second inputs of which the output of the one-vibrator 12 is connected, also connected to the control input

memory unit 13, and outputs of the third and fourth elements And 31, 32 are connected respectively to the control inputs of the first and second blocks 16 and

17 of the permanent memory, information outputs of the blocks 16 and 17 of the permanent memory through the third element OR 33 are connected to the first input of the comparison unit 34, made as an EXCLUSIVE element

0 OR, whose inputs are the first and second inputs of block 34, and the output is connected to the first input of the AND element, the second input of which is the clock input of block 34, and its output is the output of the block

5 34. The second input of the comparator unit 34 is connected to the second output of the accumulation time control unit 11, and the output of the unit 34 is connected to the counting input of the coincidence counter 35. The reset input of the coincidence counter 35 is associated with the sixth output of the control unit 5, and its outputs are connected to the corresponding inputs of the decoder 36, the output of which is connected to the first inputs of the fifth and sixth elements 37 and 38.

5 the fourth inverter 39 output of the decoder 36 is also connected to the first input of the seventh element 40, and through the fifth inverter 41 to the first input of the eighth element 42. The second inputs of the fifth and seventh elements 37, 40 are connected to the output of the first block 22 code comparison, and the second inputs of the sixth and eighth elements And 38, 42 - with the output of the second block 23 of code comparison, the third inputs of the seventh and eighth elements And 40, 42 are connected to the seventh output of the control block 5, the fourth input of which is connected to the output of the fifth element And 37. Outputs of the sixth and eighth ementov and 38, 42 are connected to the inputs of the fourth

0 of the element OR 43, the output of which is connected to the input of the quench unit 44 associated with the carrier 2 of the holograms; the output of quench unit 44 is connected to the fifth input of control unit 5, the fifth output of which is connected to

5 trigger reset input 45; the trigger setup input 45 is connected to the output of the eighth element OR 42.

The control unit 5 consists of a start unit 46, the output of which is the fifth

0 by the output of the control unit 5, connected to the first input of the fifth element OR 47. The inputs two through four of which are the fourth, fifth and third inputs of the control unit 5. and the output, which is the second output of the control unit 5, are connected to the first input of the sixth element OR 48 and through the delay element 49 to the installation input of the trigger 50. The reset input and the inverse output of the trigger 50 are respectively the second input and

the seventh output of the control unit 5, and its direct output, which is the fourth output of the unit 5, is connected to the start input of the clock pulse generator 51, the output of which is the third output of the control unit 5. The second input and the output of the sixth element OR 48 are respectively the first input and the first output of the control unit 5, and the output of the delay element 49 is the sixth output of the block 5.

The accumulation time control unit 11 comprises a differential amplifier 52, the inputs of which are the first and second inputs of the unit 11, the output of which is connected to the inputs of the first group of the comparators unit 53. The inputs of the second group of block 53 of the comparators are connected to sources of reference voltages. The outputs of the block 53 of the Comparators are connected respectively to the inputs of the block 54 one-shot, the outputs of which are connected to the inputs of the element OR 55, the output of which is connected to the input of the distributor 56 pulses. The outputs of the comparator unit 53 are connected respectively to the information inputs of the first and second registers 57, 58, the gate inputs of which are connected respectively to the first output of the pulse distributor 56 and, through the OR 59 element, to the second and third outputs of the pulse distributor 56. The outputs of the first and second registers 57, 58 are connected respectively to the inputs of the first and second groups of subtracting node 60, the gate input of which is connected to the input of the OR element 59. The first and second outputs of subtracting node 60 are connected respectively to the counting inputs of the first and second counters 61, 62, the outputs of which are connected respectively to the inputs of the decoder 1 63 and the decoder O 64. The outputs of the decoder G 63 and O 64 are connected respectively to the set and reset inputs of the trigger 65, to the inputs of the OR 66 element and to the inputs of the inverters 67. 68 respectively, output The ports of which are connected to the first and second inputs of the AND 69 element, the third input of which is connected to the third output of the pulse distributor 56, the output of the AND 69 element is connected to the first input of the OR 70 element, the second input of which is connected to the output of the decoder 71, the outputs of which are connected respectively to the outputs of the time counter 72, the counting input of which is the fourth input of block 11. The installation inputs O of the distributor 56 pulses, the first and second counters 61, 62 and the time counter 72 are the third input of block 11. The element outputs OR 66 and 70 and the direct output of the trigger 65 are respectively the first.

the third and second outputs of the accumulation time control unit 11.

Quench unit 44 contains a piercer 73, consisting of a matrix 74 and a punch 75, which acts on a contactor button .76, the contacts of which are connected to inputs of a logic unit shaper 77, the output of which is an output of quench unit 44 and connected to a reset input of a trigger 78 , the direct output of the trigger 78 is connected to the indicator 79, and its setup input is the input of the blanking unit 44. The punch 75 and the matrix 74 of the piercer 73 are placed on opposite sides of the carrier 2 of the holograms, and the matrix 74 is mounted on a tape drive mechanism so that the reading and diffracted rays pass through its opening. The punch 75 is set in motion by the operator at the signal of the inductor 79, and when the punch 75 is inserted into the hole of the die 74, it closes the contacts of the contactor 76.

The device works as follows.

The Start signal from the fifth output of the control unit 5, namely from the output of the start node 46, resets the hologram counter 21, and a zero potential is established at the direct output of the trigger 45. The signal from the second output of the control unit 5, namely from the output of the start node 46, is fed through the fifth element OR 47 to the first input of the counter 8 matrix elements, sets it to its initial state, as well as to the drive 18 of the tape drive and the carrier 2 the holograms are set to the position corresponding to the reading of the first hologram — the test hologram A. From the first output of the control unit 5, namely from the output of the sixth element OR 48, through the shaper 4, an erase pulse is fed to the erase bar of the matrix 3 photodetectors and set m last to the initial state. From the same output of the control unit 5, the signal is fed to the third input of the accumulation time control unit 11, namely, to the inputs of the installation in O of the distributor 56 pulses in, the first and second counters 61, 62 and the counter 72 of time.

From the sixth output of the control unit 5 (from the output of the fifth element OR 47 through the delay element 49) the signal is fed to the counting input of the hologram counter 21 and to the reset input of the coincidence counter 35. The signal from the output of the fifth element OR 47 through the delay element 49 is also fed to the input of the trigger setup 50, the unit potential is set at its direct output and thereby the generator of 51 clock pulses is triggered. The pulses from the third output of the control unit 5 (from the output of the generator 51) begin to pass to the fourth input of the accumulation time control unit 11, namely to the counting input of the time counter 72. From the fourth output of the control unit 5 (from the direct output of the flip-flop 50), a signal is given to start up the pumping unit 20 and the laser emitter 1 is turned on.

The reading beam of the emitter 1 illuminates the first test hologram A on the carrier 2 of the holograms, and the two-dimensional optical signal reconstructed from the hologram presented in the paraphase code is projected onto the photomatrix 3. Since the counter 8 of the matrix elements is set to its original state, code that corresponds to the passage of a pulse from the first output of the switch 7 address buses through the block 6 of the polling pulse drivers to the first address bus of the photomatrix 3. At the outputs of the second group of the counter 8 e ementov matrix formed by the code corresponding to the connection of the first and second bit lines photomatrixes 3 via the switches 9, 10 of odd and even bit lines to first and second inputs of block 11 control the accumulation time. In block 11, the electrical signals of the first two cells of the photomatrix 3 are processed, which register the first bit recorded in the test hologram A. Upon completion of the processing of the first pair of electrical signals of the photomatrix 3, a single or zero level is established at the second output of the accumulation time control unit 11, depending on which bit of information is read (1 or 0), and a single signal from the first output of block 11 passes to the input of the one-shot 12. The single-oscillator generates a single control pulse applied to a control input unit 13, RAM memory, as well as to first inputs of third and fourth AND gates 31,32 and a clock input 34 of the comparison unit. In this case, the signal from the second output of the accumulation time control unit 11 is recorded in the corresponding cell of the operational memory unit 13, the address of which is set at the outputs of the third group of the matrix element 8. Since, by the Start signal, the first pulse from the sixth output of control unit 5 passed to the counting input of the hologram counter 21 and the code of the first hologram A is formed at the output of the last, then the output of the first code comparison unit 22 has a single level. It permits the passage of a pulse from the output of the one-shot 12 to the control input of the first block 16 of the permanent memory, which stores the information page of the test hologram A. In accordance with

formed by the outputs of the third group of the matrix of 8 elements of the matrix, the address of the memory block 16 selects the first bit of information. The information signal from the output of the memory block 16 through the third element OR 33 passes to one of the inputs of the comparison unit 34, to the other input of which the second (informational) output of the accumulation time control unit 11 is connected. If the values match

5, the first bit read from the hologram A and the first bit selected from the memory block 16, according to the clock signal output from the one-shot 12, the first single signal from the output of the comparison block 34 passes to the count input of the coincidence counter 35.

The signal from the output of the one-shot 12 through the delay element 14 and the first element OR 15 is fed to the counting input of the counter

5 8 matrix elements and to the first input of control unit 5 (to the input of the sixth element OR 48). Through the element OR 48, the signal passes to the shaper 4 erase pulses. On this signal after some

0, the delay time required to record a bit of information in the RAM 13 and compare it with the bit selected from the memory 16, the next pair of cells is deleted and connected

5 photomatrices 3 to the block 6 of the interrogation pulse formers and to the first and second inputs of the accumulation time control block 11. After this, the transformation begins from the hologram A

0 optical signals corresponding to the second bit of information, recording the second bit of information in the RAM block 13 and comparing it with the corresponding bit selected from the memory block 16, etc. right up

5 to the last K-ro bit of the test hologram A. In this case, all the information read from the hologram A is compared bit-by-bit with the information of the memory block 16, and a code is generated at the output of the coincidence counter 35.

0 corresponds to the number of bits matched.

When the number of pulses arriving at the counting input of the counter of 8 matrix elements becomes equal to the number of pairs of cells of the photomatrix 3 (K), i.e. when sun page

5, the information restored from the test hologram A will be read, the signal from the fourth output of the counter 8 matrix elements passes to the second input of the control unit 5 and sets a zero potential at the direct output of the trigger 50. The

The emitter 1 is switched off most of the time. A single potential from the inverse output of flip-flop 50 (the seventh output of control unit 5) passes to the first input of the seventh element 40, to the second input of which passes a single signal from the output of the first code comparison unit 22. If the number of matched bits counted by the counter 35 matches is not equal to K (i.e. the information read from the hologram A does not fully coincide with the information stored in block 16 and the code at the output of counter 35 does not correspond to K), then at the output of the decoder 36 there is no signal and, consequently, a single signal fails at the output of the seventh element AND 40. Its appearance means the erroneous reading of the test hologram A due to the failure of any element or for other reasons and the device's unavailability for further work. In case of failure of the emitter 1, optical signals on the photomatrix 3 are missing, and after the time allotted to read one bit (specified by time counter 72 and decoder 71 in block 11), the signal at the first output of accumulation time control 11 is also absent. The recording in the RAM block 13 and the sampling of the information bit from the memory block 16 are not made, and the signal from the third output of block 11 (from the output of the element OR 70) passes through the second element OR 29 and the second element AND 30 and the first element OR 15 to counting input of the counter 8 matrix elements. When the number of pulses arriving at the counting input of counter 8 reaches K, the zero code is saved at the output of the coincidence counter 35 and the Failure signal passes to the output of the seventh element 40.

If, upon completion of reading the hologram A, the number of matches is K, i.e. The test hologram A is read correctly, the corresponding code is formed at the output of the coincidence counter 35 and a single signal from the output of the decoder 35 passes through the fifth element 37 and the fourth input of the control unit 5 and through the fifth element OR 47 to the drive 18 of the tape drive mechanism 19. In this case, the media is set to the position corresponding to the reading of the second test hologram B. Through the delay element 49, the signal passes to the input of the trigger 50, to the counting input of the hologram counter 21 and to the reset input of the coincidence counter 35. At the output of the hologram counter 21, a hologram code B is formed. Now, the unit level from the output of the second code comparison unit 23 passes to the input of the fourth element AND 32.

The unit level at the direct output of the trigger 50 through the pumping unit 20 starts the emitter 1.

Similarly, hologram A produces a bit-by-bit reading of information from the B program, its rewriting into the RAM block 13, as well as a bit-by-bit comparison with the information of the second memory block 17. If the holographic carrier has not been read before and the hologram B has not been canceled, after its completion, a code K will be generated at the output of the coincidence counter 35 and a single signal from the output of the decoder 36 will pass to one of the inputs of the sixth element And 38. Since the second input of the element And 38 a single level is supplied from the output of the second code comparison unit 23, then the signal from the output of the AND 38 element passes through the fourth element OR 43 to the input of the blanking section 44, namely to the input of the trigger 78 installation. The single level from its direct output provides turning on the indicator 79. At the signal of the indicator 79, the operator drives the punch 75 of the piercer 73. The punch 75 enters the hole of the die 74, punches the hole on the carrier 2 at the location of the hologram B and closes the contacts of the button 76. At the same time, the signal from the output of the signal generator 77 units come to the reset input of the trigger 78. Thus, the indicator 79 turns off. From the output of the shaper 77, the signal passes to the fifth input of the control unit 5 and through the fifth element IL 47 to the actuator 18. Further advancement is carried L 2 and the transition to the next reading (information) of the hologram.

Since upon completion of reading the hologram B at the output of the encoder 36 in this case there is a single signal, there is no signal at the output of the eighth element I 42 and the direct output of the trigger 45 remains zero - a sign that the hologram carrier 2 has not been used before.

If media 2 was read earlier, then a hole has already been punctured in place of the hologram B. In this case, after reading the first test hologram A and advancing the carrier 2 to the next position, the readout beam of the emitter 1 passes through the hole in the carrier 2, not diffracted, and the optical signal on the photomatrix 3 is absent. Therefore, when the time allotted for processing the signals of the first pair of cells of the photomatrix 3 expires, the control signal at the first output of the accumulation time control unit 11 will be absent, and the signal from the third output of the block 11 (from the output

element OR 70) through the second element AND 30 and the first element OR 15 will pass to the counting input of the counter 8 elements of the matrix. Thus, the transition to processing signals of the second pair of cells of the photomatrix 3, etc. until the Kth pulse arrives at the counting input of the counter of 8 matrix elements. The signal from the fourth output of the counter 8 will set on the inverse output of the trigger 50 unit level. Since the code formed at the output of the coincidence counter 35 is different from K and the signal at the output of the decoder 36 is absent, all the inputs of the eighth element I 42 are single signals and the direct output of the trigger 45 is set to a single level. Thus, the sign of re-use of the carrier is formed. The signal from the output of the eighth element And 42 will pass through the fourth element IL AND 43 to the input of the node 44 of quenching. The indicator 79 will turn on. In accordance with this, the operator will drive the punch 75 of the piercer 73 and re-extinguish the carrier 2, and the signal from the output of the blanking unit 44 will pass to the fifth input of control unit 5 and through the fifth element IL1 / 47 to the actuator 18 The carrier 2 is set to the next position, and the corresponding code is formed at the output of the hologram counter 21. Reading the next hologram and rewriting the information into the RAM 13 is similar, but since the signals at the outputs of the first and second blocks 22, 23 compare the code, there is no comparison of the read information with the information recorded in the first and second blocks 16, 17 ti not produced. Upon completion of the hologram reading cycle, the signal from the fourth counter output of 8 matrix elements passes to the first input of the first element 28, the remaining inputs of which contain unit levels, since the code of the readable hologram does not match the codes of the holograms A, B and the last head. grams N. The signal from the output of the first element AND 28 passes to the third input of control unit 5 (to one of the inputs of the fifth element OR 47), thereby passing to the reading of the next hologram. When N passes through the input of the hologram counter 21, pulses and the output of the counter 21 generates the code of the last Nth hologram, the output of the third code comparison unit 24 will be a single signal and, therefore, the signal from the fourth output of the counter 8 matrix elements will not pass through the first element And 28 to the third input of the control unit 5. On exits with lane

In the fourth through fifth block, the control signals will be absent. This completes the cycle for reading information from the carrier 2 containing N holograms.

Compared to the prototype device

provides a special marker on the hologram readable media, and also allows you to reliably recognize the previously read media and in accordance with this

0 to form a sign of reuse. The marker is the hole punched in the location of the second hologram B. The diameter of this hole exceeds the diameter of the hologram. Since, when re-reading the hologram carrier in the proposed device, there is no hologram B on it and, accordingly, no diffraction of the radiation, it is almost impossible to get K matches by comparing the output signals of the photomatrix with the test information of the second fixed-memory block. Due to this, high reliability is ensured when recognizing previously read

5 media and the formation of the corresponding sign. Since just before reading the hologram B, the first test hologram A is read and the operability of the whole

0 of the device path, the probability of erroneous formation of a reuse sign when reading previously unused media is also quite low.

five

Claims (2)

Claim 1. Holographic read-only memory with removable hologram carrier containing 0 placed and sequentially connected emitter made in the form of an injection laser diode, a hologram tape carrier containing a hologram track and kinematically connected with 5 by a tape drive mechanism, and a photodetector unit, made in the form of an array of photodetectors with an accumulation of charge, whose address buses are connected by the corresponding inputs of a polling pulse generator unit, the inputs of which are connected to the corresponding outputs of the address bus switch, and the receivers are connected to 5 corresponding to the information inputs of the switch of odd bit buses, even even buses of the photodetector array are connected to the corresponding information inputs of the switch of even bit buses, the sensor erase bus of the photoreceivers is connected through the erasure pulse shaper to the first output of the control unit, the second output of which connected to the control input of the drive and connected to the first input of the counter of the matrix elements, the outputs of the first group of the matrix element counter are connected to the switch inputs of the address busses, the outputs of the second group of photodetector matrix elements are connected to the control inputs of the first and second switches of the bit buses, the outputs of which are connected respectively to the first and second inputs of the accumulation time control unit, the third and fourth inputs of the accumulation time control unit, respectively and the third output of the control unit, the fourth output of which is connected through the pumping unit to the control input of the injection laser diode, the first and second outputs of the block are regulated and the accumulation time are connected respectively to the input of the one-shot and the information input of the main memory unit, to the address inputs of which are connected the outputs of the third group of the photodetector array element elements, to the control input of which the output of the one-vibrator is connected, the output of which is connected to the first input of the first element OR, the output of which is connected to the second input of the counter of the elements of the array of photodetectors and to the first input of the control unit, the second input of which is connected to the fourth output House of photodetector matrix elements, characterized in that, in order to expand the functionality of the device by providing recognition of hologram carrier re-reading and forming the carrier reuse feature, the first, second and third code comparison blocks, the hologram counter, are entered into the device , coincidence counter, first and second permanent memory units, comparison unit, decoder, carrier blanking node, trigger, elements. And from the first to the eighth, the OR elements from the second to the fourth, the inverters from the first to the fifth, with the reset input and the counting input of the hologram counter are connected respectively to the fifth and sixth outputs of the control unit, and the outputs of the hologram counter - to the inputs the first group of blocks comparing codes whose outputs respectively through the first, second and third inverters are connected to the inputs from the first to the third of the first element I, the fourth input of which is connected with the fourth output of the photodetector array element counter, the output of the first element AND is connected to the third input of the control unit, the outputs of the first and second code comparison blocks are connected to the corresponding inputs of the second OR element, the output of which is connected to one of the inputs of the second And element, the other input of which is connected with the third output of the accumulation time control unit, the output of the second element AND is connected to the second input of the first element OR, the outputs of the first and second code comparison blocks are connected to the first input The third and fourth elements And will give, the second inputs of which are connected to the output of a single vibrator, the outputs of the third and fourth elements of And are connected respectively to the control inputs of the first and second blocks of permanent memory, the address inputs of which are connected to the outputs of the third group of matrix counter elements the photodetectors, the outputs of the first and second blocks of permanent memory are connected to the first and second inputs of the third OR element, the output of which is connected to the first input of the comparison unit, the second input of which is Connected to the second output of the accumulation time control unit, the sync signal input of the comparison unit is connected to the one-shot output, the output of the comparison unit is connected to the counting input of the coincidence counter, the outputs of which are connected to the corresponding inputs of the decoder, the output of which is connected to the first inputs of the fifth and sixth elements And through the fourth and fifth inverters to the first inputs of the seventh and eighth And elements, respectively, to the second inputs of the fifth and seventh And elements, the output of the first code comparison unit is connected, to the second The second inputs of the sixth and eighth elements I are connected to the output of the second code comparison unit, the third inputs of the seventh and eighth elements are connected to the seventh output of the control unit, the fourth input of which is connected to the output of the fifth element And, the outputs of the sixth and eighth elements And are connected respectively to the first and the second input of the fourth OR element, the output of which is connected to the input of the carrier quenching unit, kinematically connected with a hologram tape carrier, the output of the carrier quencher unit is connected to the fifth input of the control unit , A fifth output is connected to the reset input of flip-flop whose setting input connected to the output of the eighth AND gate, a sixth output of the control unit is connected to the reset input of the coincidence counter. 2. The device according to claim 1, characterized by a contactor, the contacts of which are connected by the fact that the carrier quenching node is connected to the input of the signal conditioner and logically triggers, the indicator, the signalformer, the output of which is the logic unit, the contactor and the output of the node quenching the carrier and the plug-in punch, made in the form of a movable 5 to the reset input trigger, installation input The punch and die set, the natrigger is the input of the quenching assembly to the nentropractic mechanism, the detector being located, the direct output of the trigger is connected to moving punch kinematically connected to the syndicator. Phi Operator Fi.Z