UA71172A - Modular optoelectronic device - Google Patents

Abstract

The proposed modular optoelectronic device contains bit cells, a reset circuit, a control unit for the bit cells and the reset circuit, a D trigger, an RS trigger, AND logic elements, a circuit with an RS trigger for reversing the pulse count direction, an optoelectronic coupler, a bipolar transistor, photodetectors, blocking diodes, a resistor, a light-emitting diode, an OR logic element, and a unit for enabling data writing and recording.

Description

Description of the invention

The invention relates to pulse technology and can be used in computing devices and 2 discrete automation.

A well-known optoelectronic module (as. USSR 957437, cl. NOZK23/12, 1982), containing a counting trigger, switches, a light source in each and-bit, a transistor, the first-fourth photodetectors in pairs in series connection, the first outputs of which are connected to the base transistor, the collector of which is connected to the bus of the power source through the light source, and the emitter is connected to the common bus, the light source of the previous 70 digit is connected to the second photoreceptor of the next digit, the light source of each digit is connected to the first photoreceptor of the same digit, and the output of the pulse generator is connected to the counting input of the trigger, the direct output of which is connected to the switching contact of the first group of switches, and the inverse one is connected to the switching contact of the second group of switches, the second output of the second photodetector of the i-th category is connected to the second output of the first photodetector (i- 14)-th digit, to the second output of the first photoreceiver 12 (-1)-th digit and to the opening contact of the first switch group, etc. the first output of the second photodetector (i-1) of the i-th category is connected to the first 4) photoreceiver of the i-th category, to the second output of the first photo-receiver (ii-2) of the i-th category and to the opening contact of the second group of the switch, the second output of the third photo-receiver of the i-th category is connected to of the second output of the fourth photodetector (i-1)th, to the second output of the fourth photodetector (i1-1) of the th category and to the closing contact of the second switch group, the first output of the fourth (photoreceiver of the ith category is connected to the base of the transistor, the second output of the third photodetector (ii-1) of the i-th category is connected to the second output of the fourth photo-receiver of the i-th category, to the second output of the fourth photo-receiver (i-2) of the i-th category and to the opening contact of the first switch group, and the light source of each category is connected to the fourth photoreceptor of the same category.

The disadvantage of the known device is limited functionality, since the measurement of the duration of the input electrical signal is not implemented, as well as the forced setting of all discharges to a single state. "

The closest in terms of technical essence is the optoelectronic module (as. USSR 1274155, class H 03 K 23/78, 1986), which contains discharge cells and an initial state cell, a counting flip-flop, hereinafter named as a U-flipper, and a direction switching node numbers, the first input of which is connected to the direct output of the U-trigger, the second to the inverse output of the U-trigger, the first output of the node for switching the direction of the digit s 30 is connected to the first bus of odd pulses, the second, third and fourth outputs - to the first bus of even pulses, of the second bus of odd pulses and the second bus of even pulses, respectively, the first bus of odd pulses is connected to the first control inputs of the odd bit cells, the first bus of even pulses - -- to the first control inputs of the even bit cells and the initial state cell, the second bus of odd "-- pulses connected to the second control inputs of odd bit cells, the second bus of even pulses - to

From the second control inputs of paired discharge cells and cells of the initial state, all cells contain a regenerative optocoupler in which the first output of the light source is connected to the power bus, the second output is to the collector of the transistor, the emitter of which is connected to the common bus, the base is to the first outputs of the first, second and third photodetectors and through a resistor - to the common bus, the first optical output of the light source is connected to the first photodetector of its discharge cell, the second optical output - to the second Z 50 photodetector of the next discharge cell, the third output - to the third by the photoreceptor of the previous bit cell, in addition, the device contains a third bus of odd pulses, a third bus of even pulses, element Y,

From" each bit cell and the initial state cell contain the first, second and third isolation diodes, and the initial state cell contains an additional resistor and an additional LED, the digit direction switching node contains a K5 flip-flop and four AND elements, the direct output of the K5 flip-flop is connected to the first inputs of the first 49 and second elements of I, the inverse output - to the first and second inputs of the third and fourth elements of I, 7 the first input of the digit direction switching node is connected to the second inputs of the first and third elements of I, - the second input - to the inputs of the second and fourth elements of I , outputs of the first, second, third and fourth elements | connected respectively to the first, second, third and fourth outputs of the switching node - the direction of counting, the third bus of odd pulses is connected to the direct output of the Y-trigger and to the third -I 20 control input of the odd bit cells, the third bus of even pulses is connected to the inverse output

of the O-trigger, to the third control input of paired discharge cells and the initial state cell, in which the o additional LED is optically connected to the second photoreceptor, the anode of the additional LED is connected to the power bus through an additional resistor, the cathode is connected to the K-input of the U-trigger and to the setting input of the device, the 5-input of the K5-trigger is connected to the input of the forward digit, the K-input is connected to the input of the reverse digit of the device, in all cells between the first, second and third control inputs and the second outputs of the second and third, and in of the first photodetectors, the first, second, and third separation diodes are included, respectively, a photodiode is used as the first photodetector, the C input of the O-trigger is connected to the output of the additional element I, the first input of which is connected to the recording input, the second input is connected to the clock input of the device.

The disadvantage of this device is limited functionality, since it does not provide for the need to read information without saving it.

The invention is based on the task of creating an optoelectronic module in which, as a result of the introduction of new nodes and connections, it is possible to perform write and read operations without saving the data presented in a single normal code, which leads to the expansion of the device's functionality.

The problem is solved by the fact that in the optoelectronic module, which contains discharge cells and a cell of the initial state, an O-flip-flop, an element I and a node for switching the direction of the digit, which contains an E-flip-flop and four elements I, the first input of the node for switching the direction of the digit is connected to the forward output of the SW flip-flop, and the second is connected to the inverse output of the O-flip-flop, the first output of the digit direction switching node is connected to the first bus of odd pulses, the second, third and fourth outputs are connected to the first bus of even pulses, the second bus of odd pulses and the second bus of even pulses pulses, respectively, the first bus of odd pulses is connected to the first control inputs of the odd bit cells, the first bus of even pulses is connected to the first control inputs of the even bit cells and the initial state cell, the second bus of odd pulses is connected to the second control inputs of the odd bit cells, the second bus of even pulses connected to the second inputs of steam control x discharge cells and cells of the initial state, all 7/0 cells contain a regenerative optocoupler in which the first terminal of the light source is connected to the power bus, the second terminal is connected to the collector of the transistor, the emitter of which is connected to the common bus, the base is connected to the first terminals of the first, second and third photodetectors and through a resistor to the common bus. the first optical output of the light source is connected to the first photoreceptor of its discharge cell, the second optical output is connected to the second photoreceptor of the next discharge cell, the third optical /5 OUTPUT is connected to the third photoreceptor of the previous discharge cell, in addition. each bit cell and the cell of the initial state contain the first, second and third separation diodes, the cell of the initial state contains an additional resistor and an additional LED, the direct output of the K5 flip-flop of the node for switching the direction of the digit is connected to the first inputs of the first and second elements AND, the inverse output is connected to the first of the inputs of the third and fourth elements AND, the first input of the digit direction switching node is connected to the second inputs of the first and third elements AND, the second input is connected to the second inputs of the second and fourth elements AND, the outputs of the first, second, third and fourth elements | connected to the first, second, third and fourth outputs of the digit direction switching node, respectively, the third bus of odd pulses is connected to the direct output of the U-trigger and to the third control input of the odd bit cells, the third bus of even pulses is connected to the inverse output of the U-trigger, to O -input of the Y-trigger and to the third input 2g5 Control of paired discharge cells and the cell of the initial state, in which the additional LED is optically connected to the second photoreceptor, the anode of the additional LED is connected to the power bus via an additional resistor, the cathode is connected to the inverse K-input of the U-flip-flop and to the setting input of the device, the inverse 5-input of the short-circuit flip-flop is connected to the input of the forward digit, the inverse K-input is connected to the input of the inverse digit of the device, in all cells between the first and third control inputs and the second outputs from the second and the first photodetectors, respectively, the first and third separation diodes are turned on, as the first photodetector uses photodiode, the C-input of the Y-trigger is connected to the output of the element I, the second input of which is connected to the clock input of the device, which contains the recording input, the second and third elements |, "- the OR element, the write and read enable inputs, respectively, information read input, and the set input and the write enable input are connected to the inputs of the second AND element, the output of which is connected to --

With the INPUT of the forward digit of the device, the read permission input is connected to the input of the reverse digit of the device, and the write and read information inputs are connected to the inputs of the OR element, the output of which is connected to the first input of the first AND element, the third optical output of the light source of the initial cell state is connected to the third photodetector of the senior discharge cell, in all discharge cells and in the cell of the initial state, between the second control input and the first output of the third photodetector, the second separation diode is turned on, and the second output of the third photodetector is connected to the common bus of the device, in addition, the information the reading input and pl») with the collector output of the transistor of the initial state cells are connected according to the direct and inverse inputs. of the third element I, the output of which is the information output of the device. a The drawing shows the schematic diagram of the optoelectronic module.

The optoelectronic module contains discharge cells 1.1,....1.9, cell 2 of the initial state, SW-trigger 3,

Node 4 switching the direction of the digit, the first bus 5 odd pulses, the first bus 6 even pulses, the second -I bus 7 odd pulses, the second bus 8 even pulses, the third bus 9 odd pulses, the third bus 10 even pulses, KOZ-trigger 11, input 12 forward digits of the device, input 13 reverse digits of the device, - first-fourth elements | 14-17. Accordingly, the discharge cells 1.1,...1.9 and cell 2 of the initial state - have control inputs 18-20 and contain a transistor 21, a light source 22 with three optical outputs 23-25, the first-third photodetectors 26-28, separation diodes 29-31 , resistor 32, common bus 33, power bus 34. - The device contains elements | 35, 36, OR element 37, write input 38, read input 39, clock input 40,

Ge setting input 41, information output 42 of the device, inputs 43 and 44 of permission to write and read, respectively, cell 2 of the initial state contains a resistor 45 and an LED 46, and the device contains an element | 47. The first input of the node 4 for switching the direction of the digit is connected to the direct output of the U-flip-flop Z, the second input is connected dv to the inverse output of the O-flip-flop 3, the first output of the node 4 for switching the direction of the digit is connected to the first bus of 5 odd pulses, the second output is connected to the first bus b even pulses, third output

P" is connected to the second bus of 7 odd pulses, and the fourth output is connected to the second bus of 8 even pulses. The first bus of 5 odd pulses is connected to the inputs 19 of the control of the odd bit cells 1.1, 1.3,...1.9, the first bus of 6 even pulses is connected to the inputs 19 of the control of the even bit cells 1.2, bo 014,...1.8 and cells 2 of the initial state , the second bus of 7 odd pulses is connected to the inputs 20 of the control of the odd bit cells 1.1, 1.3,...1.9, the second bus of 8 even pulses is connected to the inputs 20 of the control of the even bit cells 1.2, 1.4,...1.8 and cell 2 of the initial state. All cells 1.1,.,.,1.9 and 2 contain a regenerative optocoupler in which the first output of the light source 22 is connected to the power bus 34, the second output is connected to the collector of the transistor 21, the emitter of which is connected to the common bus 65 33, the base is connected to the first outputs of the first-third photodetectors 26-28 and through the resistor 32 to the common bus 33. The first optical output 23 of the light source 22 is connected to the first photodetector 26 of its cell, the second optical output 24 is connected to the second photodetector 27 of the next cell, the third output 25 is connected to the third photoreceiver 28 of the previous cell. The direct output of the K5-griger 11 is connected to the first inputs of the first and second elements I 14, 15, its inverse output is connected to the first inputs of the third and

Of the fourth elements I 16, 17, the first input of node 4 of switching the direction of the number is connected to the second inputs of the first and third elements | 14, 16, the second input is connected to the second inputs of the second and fourth elements AND 15, 17. Outputs of the first-fourth elements | 14-17 are connected according to the first-fourth outputs of the node 4 switching the direction of the digit, the third bus 9 of odd pulses is connected to the direct output

SW-trigger Z and to input 18 control of odd bit cells 1.1, 1.3,....1.9, the third bus of 10 even 7/0 pulses is connected to the inverse output of O-trigger Z, to the O-input of O-trigger Z and to the input 18 control of paired discharge cells 1.2, 1.4,...1.8 and cell 2 of the initial state, in which the LED 46 is optically connected to the second photoreceptor 27, the anode of the LED 46 is connected to the power bus 34 through a resistor 45, the cathode is connected to the inverse K- to the input of the SW-trigger Z and to the adjustable input 41 of the device. Inverse 5-input

K5-trigger 11 is connected to input 12 of the forward digit, the inverse K-input is connected to input 13 of the reverse digit /5 of the device. In all cells 1.1,...,1.9 and in cell 2 between the control inputs 18-20 and the second outputs of the photodetectors 26, 27 and the first output of the photodetector 28, the separation diodes 29-31 are turned on, respectively, the second output of the photodetector 28 is connected to the common bus 33 , photodiodes are used as photodetectors 26-28. The C-input of the SW-trigger Z is connected to the output of the element I! 35, the first input of which is connected to the output of the OR element 37, the second input is connected to the clock input 40 of the device, the optical output 24 of the light source 22 of the last bit cell 1.9 is the transfer output of the device, the optical output 25 of the light source 22 of the first bit cell 1.1 is connected to the third photoreceptor 28 of cell 2 of the initial state, in which the optical output 25 of the light source 22 is connected to the third photoreceptor 28 of the last discharge cell 1.9. The inputs of the OR element 37 are connected according to the write inputs 38 and read 39 of the device, the first input of the element 36 is connected to the write enable input 43, its second input is connected to the setting input 41 of the device, and the output is connected to the input 12 of the direct digit of the device, input 13 the inverse number of which is connected to the input 44 of the reading permission of the device, the collector output of the transistor 21 of the cell 2 of the initial state is connected to the inverse input of the element I 47, the direct input of which is connected to the reading input 39, and the output is the information output 42 of the device.

The device works in the following way. с зо In order for the module to be ready to record information, power supply voltage is applied to power bus 34. To establish the initial state, a low potential is applied to the setting input 41 of the device, while -

The K5 flip-flop 11 is set to the "single" state, and the O-trigger Z is set to the "zero" state. "-

As a result, the first input of the element 115 of the node 4 of switching the direction of the number receives a "1" from the direct output of the short-circuit trigger 11, and the second input receives a "1" from the inverse output of the SW-trigger 3, therefore, a high is set at the output of the element "| 15 potential, and low potentials are set at the outputs of elements I 14, 16, 17.

At the same time, cell 2 of the module is excited. There is a "0" on the cathode of the LED 46, a current flows around the supply bus 34 - resistor 45 - LED 46, which excites the LED 46, which, in turn, optically acts on the photoreceptor 27 of cell 2. Under the influence of this connection and high potential on bus 6, the resistance of the photodetector 27 decreases sharply, and as a result, the transistor 21 opens. A current flows around the collector-emitter circuit of the transistor 21 - light source 22, the light source 22 emits light, around the output 23 - photodetector 26, positive feedback is provided, since the bus 34 - diode 29 - photodetector 26 flows around the circuit current. Cell 2 stores information. From the output 24 of the light source 22 of the cell 2 light signal;" acts on the photoreceiver 27 of the next digit cell 1.1, preparing it for work,

When performing the operation of writing operands at the input 43 of the write permission of the device, the presence of a low potential is required, which through the element | 36 is applied to the input 12 of the direct number, i.e. to the inverse 5-input of the K5-trigger -I 11, and it sets it to the "single state". As a result, buses 5 and b are connected, and buses 7 and 8 are disconnected.

Informational signals from input 38 of the record through the OR element 37 enter the first input of element AND 35, and clock pulses from input 40 clock pulses of the device come to its second input. SW-trigger Z starts - to work in the counting mode.

With the arrival of a single signal from input 38 of the record and in the presence of a clock signal from input 40, the O-trigger Z - will go into the "single" state, that is, "1" will be set at its direct output, and "0" will be set at its inverse output.

As a result, a low potential will appear at the output of element I 15 of node 4 of switching the direction of the digit, because "0" is received at its second input from the inverse output of U-trigger 3, and at the output of element | 14 will appear at a high potential, because its first input is a "1" from the direct output of the K5 flip-flop 11, and the second input dv is a "717" from the direct output of the O-flip-flop 3.

Under the action of a single signal from the output 24 of the light source 22 of the cell 2 of the initial state and high

P of the potential coming from bus 5, the resistance of the photoreceptor 27 of the discharge cell 1.1 decreases sharply. As a result, the transistor 21 of the discharge cell 1.1 opens, a current flows around the light source 22 - the collector-emitter of the transistor 21 - the common bus 33, the light source 22 emits light and through the output 23 affects the photoreceptor in 28, providing positive optical feedback. Cell 1.1 stores the first recording signal.

The blocking of cell 2 of the initial state occurs due to the presence of resistor 32 and a zero potential on buses 6 and 10, which leads to the blocking of transistor 21, and the supply of zero potential from bus 10 through diode 29 and photodetector 26 (photodiode) significantly reduces the time of blocking of transistor 21.

With the arrival of the next recording pulse, the Y-trigger Z will go to the zero state, that is, a "0" will appear on its direct output 65, and a "1" will appear on the inverse output. As a result, bus 5 is set to a low potential, and bus b is set to a high potential. Under the action of the optical connection from the output 24 of the cell 1.1 to the photodetector 27 of the cell 1.2 and the high potential from bus b, the resistance of the photodetector 27 of the cell 1.2 decreases sharply, the transistor 21 opens, the regenerative optocoupler of the cell 1.2 is excited, and the regenerative optocoupler of the cell 1.1 is closed in the same way as described above.

In a similar way, the next cells 1.3,...1.9 of the module are activated, while the signals at the inputs 18 and 19 of the cell control and the diodes 29 and 30 are activated. The number of activated cells of the module is determined by the duration of the recording signal at the input 38 of the recording device. Locking on inputs 18 and 19 of odd-numbered cells 1.1,1.3,...,1.9 occurs due to the presence of zero potential on buses 5 and 9, and of even-numbered cells 1.2,...1.8 due to the presence of zero potential on 7/0 buses 6 and 10. When the bit grid of the module is full, the transfer unit appears on the optical output 24 of the older cell 1.9 of the module.

When performing the operation of reading data at the input 44 of the read permission of the device, the presence of a low potential is required, which is applied to the input 13 of the reverse digit and sets the Ko5 flip-flop 11 in the "zero" state, therefore, the buses 5 and 6 are disconnected, that is, they have low potentials, and the buses 7 and 8 are connected, that is, they have high /5 potentials alternately, depending on the duration of the reading signal at the reading input 39, which through OR elements 37 and | 35 is fed to the C-input of the SW-trigger 3, as well as to the direct input of the element I 47. As a result, the connections of the inverse number are realized through the output 25 of the source 22 of light to the photoreceptor 28 of the previous discharge cell 1.1,...1.9 and cell 2 of the initial state Therefore, when the states of cells 1.1,...,1.9 are shifted, cell 2 changes in the opposite direction, passing from a single state to a zero state, while the signals at the control inputs 20 of the discharge cells 1.1,...,1.9 and cell 2 are decisive and diodes 31 are engaged, and the optical connection from the output 25 of the light source 22 of the cell 2 of the initial state to the photoreceptor 28 of the older cell 1.9 of the module is also functioning.

Simultaneously with the beginning of sequential zeroing of digit cells 1.1,...1.9, starting with the (K-1)th one, which was the penultimate one that worked during recording, at the output of 42 elements | 47, a single signal appears, because 25 A current flows through the circuit, power bus 34 - source 22 of light - transistor 21 - common bus 33 of cell 2 of the initial state, and a zero signal from the collector terminal of transistor 21 is fed to the inverse input of the element

And 47 if there is a single reading signal from input 39 of the reading device on its direct input. As a result, at the output 42 of the element AND 47, the duration of the unit signal will be equal to the value

Go)

Te Bu vu s 30 de idu - reading time (K-1) of bit cells 1.1...,1.9; rch- id, 7 reading time of cell 2 of the initial state. -

If 1.4 (KE -117 and in, -th then Here, that is, the duration of the unit signal at the output 42 of the element I! 47 "- 35 will be proportional to the number K of bit cells 1.1,...,1.9 that worked during recording. At the same time, the information in the m module will be lost, since only the K-th bit cell 1.1,...,1.9 will be in the single state.

In the proposed device, the optoelectronic module has extended functionality, as it provides sequential recording and reading without saving digital data in the form of a single normal code. sew behind her Rg Star Ul 2 55" And now with Te :" vy-ya her with i.: y "(and about 7 zones left vyh nySHYNIM SHY NO nn RN M - HER 11 1 11711717 11 18 19 20 |v yav 191 20| tv 19| 20 -I 20 cones sew she moh ryn po m po po po M more shk what she what! 311" and this|31" KE ІІ z|zi | »yu I Y| zo|z I | yu Ts , M u hu SU u i i IHY Hu i hu I shchi i i i ! i i I I I ! I ; 2). .) 2 in. And" - ! » or 7 Pi IM. vi ky y "HM m 5 "DU to which SY A p still i! schi tii B; ih i ze ku I z" ie | U i Da her De ii i D yi D yi ! u DY BY!! ! y! y! and in! and; zvi with ! well these and: and and | and and

M i v ay 2 - ti t mi i et li rai mi; ; more

T and Y Y! because | L D li her shA AD i

And 32 and 2 and

Bosch 12 g. Lv z3 b5

Claims (1)

The formula of the invention An optoelectronic module that contains discharge cells and an initial state cell, an O-flip-flop, an element, and a digital flip-flop, which includes a K5b flip-flop and four elements. And the first input of the digital flip-flop is connected to the direct output of the SW flip-flop, and the second is connected to of the inverse output of the U-flip-flop, the first output of the digit direction switching node is connected to the first bus of odd pulses, the second, third and fourth outputs are connected to the first bus of even pulses, the second bus of odd pulses and the second bus of even pulses, respectively, the first bus of odd pulses is connected to the first control inputs of the odd bit cells, the first bus of even pulses is connected to the first 70 control inputs of even-digit cells and cells of the initial state, the second bus of odd pulses is connected to the second control inputs of odd-numbered cells, the second bus of even pulses is connected to the second control inputs of even-digit cells and cells of the initial state, all cells contain a regenerative optocoupler, in which the first terminal of the light source is connected to the power bus, the second terminal is connected to the collector of the transistor, the emitter of which is connected to the common bus, the base is connected to 75 first outputs of the first, second and third photodetectors and through a resistor to the common bus, the first optical output of the light source is connected to the first photodetector of its discharge cell, the second optical output is connected to the second photodetector of the next discharge cell, the third optical output is connected with the third photodetector of the previous discharge cell, in addition, each discharge cell and the initial state cell contain first, second and third isolation diodes, the initial state cell contains an additional resistor and an additional LED, the direct output of the K5 flip-flop of the digit direction switching node is connected to the first inputs of the first and the second elements AND, the inverse output is connected to the first inputs of the third and fourth elements AND, the first input of the digit direction switching node is connected to the second inputs of the first and third elements AND, the second input is connected to the second inputs of the second and fourth elements AND, the outputs of the first, second, of the third and fourth elements | connected to the first, second, third and fourth outputs of the digit direction switching node, respectively, the third bus of odd pulses is connected to the direct output of the O-flip-flop and to the third control input of the odd bit cells, the third bus of even pulses is connected to the inverse output of the U-flip-flop, O -input of the SW flip-flop and to the third input of the control of paired discharge cells and the cell of the initial state, in which the additional LED is optically connected to the second photoreceptor, the anode of the LED is connected to the power bus via an additional resistor, the cathode is connected to the inverse c In-input of the SW flip-flop and to the setting input of the device, the inverse 5-input of the K5-flip-flop is connected to the input m of the forward digit, the inverse K-input is connected to the input of the inverse digit of the device, in all cells between the first and third control inputs and the second outputs of the second and the first photodetectors are turned on, respectively, the first ke and the third separation diodes, a photodiode is used as the first photodetector, the C-input of the O-trigger is connected to the - output of the element I, the second input of which is connected to the clock input of the device, which contains the recording input, characterized in that it contains second and third AND elements, an OR element, write and read enable inputs, respectively, a read information input, and the set input and the write enable input are connected to the inputs of the second AND element, the output of which is connected to the input forward digit of the device, the read permission input is connected to the input of the reverse digit of the device, the write and read information inputs are connected to the inputs of the OR element, the output of which is connected to the first input of the first AND element, the third optical output of the light source of the initial state cell with connected to the third photoreceiver of the senior discharge cell, in all - with the discharge cells and in the cell of the initial state between the second control input and the first output of the third photodetector, the second separation diode is turned on, and the second output of the third photodetector is connected to the common bus of the device, in addition, the information input of the readout and the collector output of the transistor of the initial state cell are connected according to the direct and inverse inputs of the third element And, the output of which is the information output of the device. -I - Official Bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2004, M 11, 11/15/2004. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. - 50 Ko) R 60 b5