SU1076895A1 - Device for linking end users with computer - Google Patents

Abstract

A DEVICE FOR PAIRING BY A SUBSCRIBER WITH AN ELECTRONIC COMPUTING MACHINE containing a communication unit with a computer and M communication units with a subscriber, the first ones. the input and output of the communication unit with the computing machine are connected respectively with the first output and the input of the first communication unit with the subscriber, the first input and output of the i -th communication unit with the subscriber (i 2, M) are connected respectively with the second output and input (il ) -ro of the communication unit with the subscriber, the second, third, fourth and fifth inputs and the second output of the communication unit with the computer are respectively the inputs of the setup signals and the reset of the interrupt enable, interrogation of the presence and acknowledgment of the device and the output of the interrupt signal tva, the third input of the communication unit with the subscriber is the t-th input of the device communication request, and the communication unit with the computer contains transmitting and receiving, a current generator, two triggers, two AND-NOT elements, the first element is NOT and a delay element and a load resistor, and each communication unit with the subscriber is a receiving and first transmitting optocouplers, three triggers, two NOT elements, an OR element, an AND-NO element, a delay element, and the first load resistor, and in the communication unit with computer output of the current generator is connected to the first The input of the transmitting optocoupler, the output and the second input of which are connected respectively to the first output of the unit and the bus of the zero potential of the power supply, and the third input through the load resistor to the positive polarity of the power supply source, the first and second inputs of the receiving optocoupler are respectively connected to the first input block and the negative polarity of the power supply source, and the output through the first element is NOT to the first input of the first I – BE element, the second and third inputs and the output connected to the output the first trigger, the fourth input of the block and the bar (the secondary input of the second trigger, the output of which is the second output of the block and through the first delay element is connected to the first input of the second AND-NOT element, the output of the receiving optocoupler connected to the second input and the reset inputs of the first and second triggers are the second, third and fifth "block inputs, respectively, in each block o: communication with the subscriber; the first input and output of the receiving optocoupler are connected 00 respectively with the first input of the fleas to a and the input of the first transmitting oprone, the second input through the first na01 load resistor - with the positive polarity of the power supply source, and the third input through the first element NOT with the output of the first trigger and the first input of the NAND element, the second input connected through the second element is NOT to the first output of the first receiving optocoupler, the third input through the delay element to the output of the second element is NOT, and the output to the synchronization input of the second trigger and the reset input of the third trigger, the output of which is connected to

Description

the first input of the Or element, the synchronization input with the third input of the block, and the information input with the information input of the second trigger and the positive polar bus of the power source; the setup input of the first trigger is connected to the output of the OR element, the input and the second output of the first receiver optocoupler solenoids, respectively, with the second input, and the first output of the unit, and so on, so that, in order to increase throughput, a counter, a third trigger, a third AND-NOT element, are entered into the communication unit with the computing machine, the element , the second element NOT and the second and third delay elements, and in each communication unit with the subscriber - the second transmitting optocoupler, the third element NOT the fourth trigger, the counter, the second load resistor, the comparison node and the pulse shaper, and in the communication unit with a computer information the input of the third trigger is connected to the output of the First element NOT, the synchronization input through the serially connected second element NOT and the delay element to the output of the first delay element, the reset input to the counter reset input, the first input third AND-NO element and the output of the second flip-flop, th output - to a second input of the third AND-NO element, output ready signal -, NOSTA apparatus and the first input

of the AND element, the second input of the third NAND element connected to the output and through the third delay element “to the second input of the second NAND element, and the output to the synchronization input. the counter, the output of which is an information output of the device, the third input of the third element is connected to the output of the receiving optocoupler, in each communication unit with the subscriber the output of the fourth trigger is connected to the input, resetting the first trigger, the reset input - to the second input of the OR element, the reset input of the second the trigger and through the pulse shaper to the first output of the first forward optocoupler and the synchronization input of the counter, the information input to the output of the comparison node, and the synchronization input to the inverse output of the second trigger and through tr This element is NOT to the first input of the second transmitting optocoupler, the second input connected through the second load resistor to the positive polarity of the power supply, and the third input and output respectively to the first input and the second output of the block, the reset input of the counter is connected to the forward output of the second trigger, a group of outputs — to the first group of inputs of a comparison node, the second group of inputs of which is appropriate for specifying the device subscriber number,

The invention relates to the selection technique and can be used to connect a large number of remote peripherals to an electronic computer (EEhm) using a two-wire communication line both for transmitting interrupt requests to the computer and for choosing the priority of one of the competing devices

A device for connecting subscribers to a computer is known, comprising a interface unit, a computer and a group of subscriber units combined by a three-wire communication line, the computer interface unit comprising a ring shift register and a pulse generator connected respectively to the first and the second wire is a three-wire ™ HQ5 communication line; subscriber unit contains a counter and a group of registers connected via matching elements to the first wire

In this case, the meter is connected via a matching element to the second wire of the three-wire communication line, and the third wire of this line is the common neutral wire of the device.

In the course of the computer operation, connected to the device, periodically, for example, at a frequency of 100 Hz), sends commands to the communication line. Invitation to an interrupt. These commands are received simultaneously by all subscribers connected to the line. Upon receiving such a command, subscribers that require service from the computer, begin to compete on the common line of communication, analyzing the bit by bit codes assigned to subscribers to secure their priorities. As a result, a serial code is formed on the common communication line, which unambiguously characterizes the address of the claimant-candidate for priority service. Computer reads this

the code exchanges information with the subscriber and returns to the interrupted task, later on, it re-generates the Interrupt Request commands, etc. .

The disadvantage of this device is the long response time to the interruption. In the worst case, even in the absence of competitors, the peripheral device has to wait for service for the whole command follow-up period. (For the example, this time is 0.01 seconds, which is not always permissible. In addition, an increase in the command follow frequency reduces the computer performance, as more and more of the computer time is spent on executing useless (from the user's point of view) scanning commands.

Closest to: proposed by those: the essence is a device for interfacing subscribers with a computer, containing a communication unit with a computer and a group of communication units with subscribers, interconnected by a two-wire communication line, and the communication unit with a computer contains a current generator, re-. the giving and receiving optocouplers, the first and second triggers, the first and second elements AND-NOT, the first element NOT, the first delay element and the load resistor, the output of the current generator through the output transistor of the transmitting optocoupler is connected to the first wire of the two-wire communication line, the second wire is two-wire the communication line is connected via the LED of the receiving optocoupler to the linear power supply bus, the output of the receiving optocoupler through the first element is NOT connected to the first input of the first NAND element, the second input of which is connected to the output of the first the trigger whose inputs are the inputs for setting and resetting the device interrupt resolution, the third input of the first IS element is the interrogation input of the device interlock, the input input of the device interface block is connected to the reset input of the second trigger, the installation input of which is connected to the output the first NAND element, the output of the second flip-flop is the output of the interrupt signal of the device and is connected to the first input of the second element through the first delay element. AND-NN, the output of which is connected via a load resistor a positive power supply bus and transmitting through the optocoupler LED - to a negative busbar of the source, wherein the communication unit comprises a receiver with a subscriber and a first optocoupler transmitting photocoupler, three triggers, two of NOT element

OR, NAND element, delay element and first load resistor, the clock input of the first trigger being a request input of the subscriber unit; the information input of the first trigger is connected to the power supply bus; the zero arm output of the first trigger is connected to the first input of the OR; the output of which is connected to the input of the installation of the second trigger. The output of which is connected to the first input of the NAND element and through the series-connected first element NOT, the LED of the first transmitting optocoupler and the first, load. a positive resistor with a positive power supply bus: power supply, the output transistor first transmitting optocoupler is connected between the first and second wires of the two-wire communication line, the receive optocoupler diode is connected successively to the second wire of the two-wire communication line, the output of the receiving optocoupler through the second element is NOT connected to to the second input of the NAND element and through the delay element to the third input of the NAND element, the output of which is connected to the synchronization input of the third trigger and to the reset input of the first trigger, information The third input of the trigger is connected to the power supply bus, the output of a single shoulder of the third trigger, in the communication unit with the subscriber is the output of the acknowledgment signal of this unit, and the reset input of the third trigger is input of the third trigger connected to the input reset the second trigger.

During the operation of the device, communication units with subscribers send interrupt request signals to the communication line. In response, the computer communication unit generates a response signal that causes activation of a single (highest priority) communication unit with the subscriber -dub. After that, the computer on the information channel issues the Who You command and receives, in response to the same channel, the subscriber number, which is used to go to the corresponding service subprogram 2j.

A disadvantage of the known device is low bandwidth due to the need for a soft dial of the subscriber number, i.e. . due to the loss of time in the interrupt response.

The purpose of the invention is to increase the capacity of the device.

This goal is achieved by the fact that a device for interfacing subscribers with an electronic computing machine containing a communication unit with a computing mailbox / ii communication unit with a subscriber, the first input and output of the communication unit with the computing machine} are connected respectively with the first the output and input of the first communication unit with the subscriber, the first input and output of the i.ro communication unit with the subscriber 2, m) from each other with the second output and input (i-lj-ro communication unit with the subscriber, second the third, fourth and fifth inputs and the second output of the communication unit with the computer are the inputs of the setup and reset interrupt enable signals, the interrogation of the presence of interrupted and device acknowledgment and the output of the interrupt signal of the device, the third input 1 - IH of the communication unit with the subscriber is the i input of the communication request of the device , the communication unit with the computing machine contains a transmitter and a receiving opron current generator, two trigger, two NAND. elements, the first element is NOT and the delay element and the load resistor, and each communication unit with the subscriber is the receiving and the first pass on optocouplers, three triggers, two NOT elements, an OR element, a NAND element, a delay element and the first load resistor, and in the communication unit with the computer, the current generator output is connected to the first input of the transmitting optocoupler, the output, and the second input of which connected to the first output of the unit and the zero potential of the power supply source, and the third input through the load resistor with a positive polarity of the power supply source, the first and second inputs of the receiving optocoupler are connected respectively to the first input of the unit and the negative polarity bus of the power supply, and the output through the first element NOT to the first input of the first NAND element, the second and third inputs and output connected respectively to the output of the first trigger by the fourth input of the unit and the installation input of the second trigger, whose output is the second output of the block and through the first delay element connected to the first input of the second element AND-NOT, the output connected to the second input of the receiving optocoupler, the installation input of the first trigger and the reset inputs of the first and second triggers are the second, third and fifth inputs of the block, respectively. In each communication unit with the subscriber, the first input and output of the receiving, optocoupler are connected respectively to the first input of the unit and the input of the first transmitting optocoupler, the second input through the first load resistor is connected to the positive bus power supply and the third input through the first element is NOT with the output of the first trigger and the first input of the element, the second input connected through the second element NOT to the first output of the first receiving optocoupler, the third input through the element Holders - to the output of the second element NOT, and the output to the synchronization input of the second trigger and the reset input of the third trigger, the output of which is connected to the first input of the OR element, the synchronization input to the third input of the block, and the information input to the information input of the second trigger and bus positive polarity of the power supply, the setup input of the first trigger is connected to the output of the OR element, the input and the second output of the first receiving optocoupler are connected respectively to the second input and the first output of the unit, in the communication unit with calculate The machine has a counter, a third trigger, a third NAND element, an AND element, a second element NOT and a second and a third delay element, and a second transmitting optocoupler, a third element NOT, a fourth trigger, a counter, and a second a load resistor, a comparison node and a pulse shaper, and in the communication unit with a computing machine, the information input of the third trigger is connected to the output of the first element NOT, the synchronization input through the serially connected second element NOT and the delay element - with the output ne the delay element, the reset input with the counter reset input, the first input of the third element and the output of the second trigger, and the output with the second input: the third NAND element, the output of the device’s ready signal and the first input of the AND element, the second input connected to the third output AND-NOT element and through the third delay element to the second input of the second element, and the output to the synchronization input of the counter, the output of which is the information output of the device, the third input of the third AND-NOT element is connected to the output of the receiving optocoupler , in each communication unit with the subscriber, the output of the fourth trigger is connected to the reset input of the first trigger, the reset input to the second input of the OR element, the reset input of the second trigger and through the pulse shaper to the first output of the first transmitting optocoupler and the synchronization input of the counter, the information input to output of the comparison node, and the synchronization input to the inverse output of the second trigger and, through the third element, NOT to the first input of the second transmitting optocoupler, which is connected to the second input through the second load resistor with the bus polarity of the power source, and the third input and output -. respectively with the first input and the second output of the block, the counter reset input is connected to the forward output of the second trigger, the output group is. to the first group of inputs of the comparison node, the second group of inputs of which is the corresponding input for setting the subscriber number of the device. In FIG. 1 shows the block diagram of the device being pre paginated in FIG. 2 is a functional diagram of a communication unit with a computer; .on FIG. 3 is a functional diagram of a communication unit with a subscriber / in FIG. 4 time diagrams for device operation. The device for connecting the subscribers to the computer contains (FIG. 1) block 1 of communication with the computer and M blocks 2 of communication with the subscriber (the number of blocks 2 is taken to be three). Blocks 1 and 2 are interconnected by two-wire communication lines containing the first wire 4 and the second wire 5. Fig. 1 denotes the inputs B and 7 of the set signal and reset the interrupt enable signal of the device, the input 8 of the interrogation signal for the presence of interrupt signal 9 the device acknowledges, the outputs 10 and 11 of the interrupt and device ready signals and the information output 12, as well as the inputs 13 of the device communication requests. Unit 1 of communication with the computing machine (Fig. 2) contains a current generator 14, transmitting the optocoupler 15, receiving optocoupler 16, AND-HE elements 17 19, HE elements 20 and 21, the first, third and second elements 22-24 of the holder, triggers 25 --27, element 28, counter 29 and load resistor 30. Generator 14 output 31 through the output transistor of the transmitting optocoupler 15 is connected to the first output of the block and wire 4. Wire 5 is connected to the first input of the block and through the LED of the receiving optocoupler 16 s bus 32 negative polarity of the power source. Fig. 2 also indicates the output 33 of the receiving optocoupler 16, the bus 34 of the positive power source polarity and the bus 3 of zero ground potential of the power source. The current generator 14 is made on a transistor 36 connected in accordance with a common base circuit. The emitter of the transistor 36 is connected via a current-supplying resistor 37 to the bus 38 of the source of positive power, the second pole of which is connected to the earth bus 39, HV connected to the earth bus 35 (1). The collector of transistor 36 is the output 31 of the generator 14. The current in line 3 when it is closed is given by the buses of two sources: negative (bus 32) and positive (bus 38), the second poles of which are connected to a common point — bus 39 of the ground line. The source of the bus 34 is galvanically developed with the sources of the tires 32 and 38. The second pole of the busbar source 34 is connected to the ground bus 35 of the power supply source of unit 1, unit 2 is connected to the subscriber (FIG. 3) contains receiving optocoupler 40, transmitting optocouplers 41 and 42, third, first, second and fourth triggers 43-46, elements NOT 47 - 49, element OR.50 element AND-HE 51, delay element 52, load resistors 53 and 54, pulse shaper 55, counter 56 and comparison node 57. The trigger synchronization input of the trigger 43 is the third input of the block and the input.13 of the device's request signal, the information input of the trigger 43 is connected to the bus 58 of the positive polarity of the power supply source. FIG. 3 denotes the output 59 of the receiving optocoupler 40, the first group of inputs 60 and the second group of inputs 61 of the comparison node 57, which is the input of the subscriber's reference number of the device (these bit buses of the inputs 61 are supplied with a combination of low and high potentials, individual for each block, but not null, and the output 62 of the comparison node 57. In Fig. 4, plot 63 displays the signal at the trigger output 44, plot 64 represents the current through the LED of the optocoupler 16, plot 65 shows the signal at the output of the trigger 26, plot 66 indicates the signal at the direct output of the trigger 45 plot 67 - the signal at the output of the trigger 46, plot 6 8 - the contents of the counter -56, plot 69 - the signal at the output of the trigger 27. In addition, time slots 70-73 are marked in Fig. 4. The device operates as follows. The device is designed to notify the computer that one of the subscribers (if the conflicts of the highest priority requires servicing, and the subscriber number is automatically transferred from the corresponding block 2 via line 3 to the counter 29. The computer reads this number and uses it to go to the service subscriber of the corresponding subscriber. The signal from output 10 of block 1 warns the computer that there is at least one service request in the outside world, and the subscriber’s number on line 3 will soon begin to transfer to counter 29 if the transmission rate of signals on line 3 is high and the computer has a low performance , it can use the signal from output 10 of block 1 as an interrupt signal. In this case, the transition process to the interrupting program 1me storing return parameters in the stack, establishing a new program state, etc.) and accumulating information Chike 29 will proceed in parallel and by the time of the inquiry of the counter 29 in. the formation of the subscriber number code will already be completed.

If the transmission rate of signals on line 3 is low, for example, 50 baud), and the computer has high performance (500 thousand operations per second), then the warning signal from output 10 is too premature and therefore is not used, fBO avoiding wasted computer waiting time complete the transfer of the subscriber number on the line 3 in the counter 29). In this case, the interrupt signal can be the negative edge of the ready signal from output 11, which indicates that the accumulation of code in counter 29 is completed (with an increase in the transfer number; the number given, the accumulation time of the code in counter 29 increases)

If the ratio of the transmission rate of signals on line 3 and the performance of a computer is such that the transition time to the interrupting program is commensurate with the accumulation time of the code in the counter 29, then the interruption can be triggered by the signal from output 10, and the signal from output 11 can be indicated by the indicator in the counter and cyclically interrogate in the most interrupting program at the initial stage of its execution. Releasing the readiness sign, interrupting the program transfers control to the appropriate branch using the read from the counter 29 code as branch address

The response to the interrogation signals from the subscribers at the inputs 13 mole; it should be prohibited or allowed. The reset signals or the flip-flop 213 signals coming through the inputs 7 and b from the computer,

The signal at input B of block 1 is a gating signal from the side of a computer and is formed, for example, by performing each machine command. The signal on the input of block 1 comes from the computer after reading the code from the sensor 29, for example, at the end of the subscriber's service subroutine, as a result of which the device arrives at the initial connection and is able to accept the request signals again if there is no prohibition from the trigger 25.

Thus, the device performs the functions of selecting the highest priority subscriber from among those requiring service and determining its number without the cost of computer time.

Unit 1 is designed to provide communication between the computer and the two-wire communication line 3.

In the initial position, the trigger 25 (interrupt resolution) is set to one state by the previously received pulse on input 6. In the absence of interrupt requests, the current through the LED of the optocoupler 16 is negligible, the output 33 of the optocoupler 16 is delayed by the signal of the logical unit that is converted by the HE element 20 In the logical zero signal, the locking element H-HHO 17, Poet Iy, the gate signals at input 8 do not affect the output state of the AND-NE element 17 and, therefore, trigger state 26f previously reset at input 9..

A null signal from flip-flop 26 maintains flip-flop 27 in one state, and counter 29 in its reset state and, passing through delay element 22, blocks AND-HEN 18 with an open collector. The current from the bus 34 passes through the resistor 30, the optocoupler 15 LED and flows to 355, the glow of the optocoupler LED 15 means that its output transistor is saturated, however, the current through the transistor is close to zero, since in the absence of requests the line 3 is open, t. e. the resistance between the first 4 and second 5 wires of this line is very large and is, for example, 1 MΩ. The current through the LED of the receiving optocoupler 16 is almost zero, as previously assumed.

This state is maintained until one or several appear: service requests, with the result that the resistance between wires 4 and 5 of line 3 becomes low, for example, of the order of 1 kΩ.

In this case, the current from the generator 14 flows through the saturated transistor of the optocoupler 15 into the closed line 3 and then through the slug of the optocoupler 16 (including it) to the other 32. At the same time, the output of the optocoupler 16 produces a logic zero signal and the output element HE 20 - logical unit signal.

When a positive pulse arrives at the input 8 of block 1, the AND-NE element 17 is triggered, the trigger 26 is set to one, the interrupt signal is received from

output 10 in the computer (information carries the front of the signal). The same signal passes through the delay element 22 and triggers the AND-HE element 18, and the current through the LED of the optocoupler 15 stops. The transistor of the optocoupler 15 is turned off, the current in line 3 is stopped, a high potential is formed at the output 33 of the optocoupler 16, the AND-HE element 17 is again closed by the signal from the output of the HE element 20,

At the same time, the appearance of a high potential at the output 33 of the optocoupler 16 causes autogeneration around the ring: bus 33, AND-NE element 19, delay element 23, AND-NE element 18. The LED of the optocoupler 15, lines 4 and 5, the LED of the optocoupler 16 bus 32, because the element AND-NOT 19 is open to the inputs 10 and 11. The pulses from the output of the element AND-NOT 19 pass through the element 28, which is open to the input by a signal from the output of the trigger 27, and is counted by the counter 29, because the reset signal counter 29 is no longer valid on it.

The block 2 selected as a result of competitive selection also counts the pulses generated in the resulting ring. Ultimately, when the number of pulses is equal to the number of the selected block 2, the resistance between the wires 4 and 5 of line 3 (from the side of block 1) will become high again and the generation will stop, as the ring will be broken.

In the process of generalization, trigger 27 is maintained in a single state, because by the time a positive edge of a pulse from an output of an HE element 21 arrives at its sync input, a logical unit from an output of an HE element 20 is supplied to the synchronization input. When the generation is disrupted, this condition is violated: synchro-synchronizing the signal causes reset of trigger 27, since, at the moment of its arrival, a logical zero is present at the information input.

The zero signal from the output of the trigger 27 prevents the triggering of the element NAND 19 and the element 28 and the input from the output 11 into the computer can be used as a code readiness signal at the output 12.

Subsequently, the computer starts working with the selected subscriber via the information communication channel, for which one or several cable lines (not shown) are allocated.

When the exchange is completed (or during the exchange), a reset signal is sent from the computer to the trigger 26, as a result of which the latter is reset, the trigger 27 is set to one state, the counter 29 is reset. The LED of the optocoupler 15 is turned on and, if requests are present, the current from the generator 14 through the saturated transistor of the optocoupler 15 goes to wire 4 and returns via wire 5 to bus 32, etc., i.e. the process of searching for the subscriber and transmitting his number is repeated.

Blocks 2 operate as follows.

In the initial state, a logical zero is applied to the input 13, the triggers 43 46 and the counter 56 are reset, the NOT 47 element with an open collector is closed at the output, the current through the LED of the optocoupler 41 is negligible, and the transistor of this optocoupler is turned off. A logical unit is supplied to the input element of the HE 49 with an open collector, therefore, the LED of the optocoupler 42 emits light when current flows through the circuit: bus 58, resistor 54, LED of the optocoupler 42, output of the element. NOT 49, The transistor of the optocoupler 42 is open, however, in the initial state the current through it does not flow. Because, by assumption, there are no requests and the optocouplers of the LEDs 41 of all units 2 are turned off. For the same reason. There is no current through the LED of the optocoupler 40, therefore, a logical unit is formed at its output 59.

The shaper 55 pulses, in the presence of a constant single signal at the input, maintains a constant zero signal at the output. Subsequently, it converts the first negative impulse that arrived at the input into a wide positive impulse at the output. Its duration is slightly longer than the transmission time on line 3 (in the process of autogenerating pulses) of the maximum subscriber number. During the formation of the output pulse, the shaper remains insensitive to the input effects.

The positive edge of the subscriber's request signal from input 13 transfers trigger 43 to one state, since a high potential is fed to its information input from bus 58. A logical zero signal from the trigger output 43 is transmitted through the OR 50 element to the set trigger input 44, As a result, a logical unit is formed at its output, the element NOT 47 is triggered and the LED of the optocoupler 41 turns on, which leads to saturation of the transistor of this optocoupler, i.e. to short circuit of wires 4 and 5 lines 3.

If there are no competing requests, then the current flowing into: into the wire 4 from the block 1, passes through the transistor of the optocoupler 41 and turns on the light diodes of the optocouplers 40 of its own and all foreign blocks 2, located in the direction of the block 1. After the triggering of the optocouplers 40 and shapers 55 in the indicated foreign blocks 2, they can no longer to compete, since the logical unit from the output of the driver 55 in these blocks unconditionally passes through the element OR 50 to the input of the installation of the trigger 44, preventing its transfer to the one state when the trigger 43 is triggered. Other blocks 2 located to the left of the nguy ( , e / in the direction from block 1), is also incapable of competing, although they are allowed to install triggers 44 and turn on the LEDs of optocouplers 41. This is due to the fact that the switched-on transistor of optocoupler 4 of our unit 2 shunts similar circuits, located on the left. Therefore, in these foreign units 2, the transistors of optocouplers -41 are omnipresent and turned on (if someone else's requests are received after ours, however, in these units, the optocouplers 4 LEDs will be turned off and therefore further processes will not develop. After the transient processes associated with the arrival of one or several inputs 13 of the requesting signals, block 2 is in one of three possible states I. The trigger 44 is set to one, the LED optro 40 is turned on. These conditions will condition one unit 2, namely the one This will be due to the shunt effect of the saturated transistor ogrgron 41. The current does not flow through the LEDs of the optropes 40 blocks 2, located around the center; on the other hand, the assumption that these conditions still characterize One block is located on the right, not true, since in this case these conditions would not have been fulfilled in wave 2 due to the shunting effect of the right block 2, II. The trigger 44 is set to the free state, the LED is optr on. 40 is turned off, this is the condition characterizing blocks 2 located to the left of that block, has captured line 3 (condition I), III..T rigger 44 is in the reset state, light source LED 40 is turned on These are the EOT characterization blocks 2 to the right of block 2 In this case, the allocation of conditions I is produced with the help of the circuit Vg, the course 59 of the optocoupler 40, the element NO 48, the element 52 of the holder, the element H - HS 51, the trigger code 45. Since the optocoupler 40 is switched on, at the output 59 of this optocoupler a logical nooh is formed, at the output of the element NOT 48 - a logical one Itza. The signal from the output of the HE element 48, if it has a sufficiently long duration that exceeds the delay time of the delay element 52 (this is the condition of the system calming down), interacts with the single signal from the trigger 44 and includes the AND-NOT element 51. The zero signal from the output of the element 51 / resets the trigger 43, the trigger 45 continues to be in the reset state. This state in a single block 2 is maintained until the current in line 3 stops at the initiative of block 1. After the time determined by the delay of element 22 (FIG. 2), the current from gene The rator 44 ceases to flow into the wire 4, therefore, all the LEDs of the optocouplers 4 that were previously turned on are turned off. Turning off the LED of the optocoupler 49 and block 2, characterized by condition 1, leads to the shutdown of the element 51, i.e. to the formation of its 5 zyhol; e positive signal front. This front translates trigger 45 into a single state, since Kc1. its information input is fed to the positive potential from the bus 58, the signal from the direct output of the trigger 45 pa; decides the counter 56 to accumulate subsequent current pulses in line 3; The signal from the inverse output of the trigger 45 (logical zero) turns off the LED of the optocoupler 42, as a result of which the transistor of the optocoupler 42 turns off. With simultaneous or almost simultaneous receipt to the device of several query signals on inputs 13 races are possible, connected with intercepting the current of block 2, located closer to block 1 (having higher priority), However, this process cannot lead to ambiguous choosing one of the competing subscribers. Indeed, the time T for the existence of these races is limited by the response time of the blocking circuits, the output 59, the driver 55, and the calming down time of the element OR 50 trigger 44 — the element NOT 47 is the lip optocoupler after which the device goes into a static state in which each block 2 is in one of stable states 1-111; the absence of false triggering of element 51 during the racing period is guaranteed by filtering at its inputs pulses whose duration is less than or equal to the delay time of signal propagation through element 52 Derzhko, wherein the selected delay greater than the time f, after completion of the first cycle of operation of the device appear in it self oscillation. Each time the LED of the optocoupler 40 turns on, the contents of the counter 56 are incremented by one. In one of the clocks, the content of the counter 56 becomes equal to the subscriber number decoupled at the inputs 61 (the number must be nonzero). At the end of the current pulse through the LED of the optocoupler 40, the set value of the signal when the unit value coincides) from the output of node 57 (stored on trigger 46. When the codes on inputs 60 and 61 coincide, a zero signal from trigger output 46 clears trigger 44, as a result of which the circuit operates : element NOT 47 optocoupler 41, the resistor 53 and the output transistor of the optocoupler 41 is turned off. Line 3 is open and block 1’s attempt to pass a current current through it is unsuccessful. Thus, the autogeneration mode is stopped and the code The measure of the selected subscriber is transmitted to the counter 29 of block 1. After the subscriber number is transmitted (calculated for the worst case of transmitting the maximum number), a logical zero signal appears again on the output of the transformer 55, which resets the triggers 45 and 46 and the counter 56. Thus, block 2 enters the initial state.

6 7 3 10 П 12 At the moment 70 of FIG. 4) the trigger 44 of the block 2 having the number 5 is set to one, which leads to the appearance of current through the LED of the optocoupler 16 (plot 64). The trigger 26 is set to a single state (plot 65) and the current through the LED of the optocoupler 16 stops. Starting from this moment, the counter is enabled in block 2, since the signal at the direct output of the trigger 45 takes on a single value (plot 661. Subsequently, the current reappears, disappears again, etc., i.e., autogeneration A counter accumulates in counter 56 (plot 68). At time 71, node 57 is triggered and the nearest pause is set to -5 zero state signal at the output of flip-flop 46 (plot 67). Then flip-flop 44 (plot 63} and block 1 , sensing the termination of generation, generates a code readiness signal in the counter 29 (the codes in the counters are the same), which is plotted 69. At time 72, driver 55 sets block 2 to its initial state At time 73, the trigger 26 is reset and the ready signal of the code is removed (plots 65 and 69). Thus, the proposed device provides the transmission of the code of the channel number without the fate of the computer, which allows to shorten the response time to the interruption and increase the throughput of the device.

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Claims (2)

A device for interfacing subscribers with an electronic computing machine, comprising a communication unit with a computer and M communication units with a subscriber, the first, the input and output of the communication unit with the computer being connected respectively to the first output and input of the first communication unit with the subscriber, the first input and output ί th unit of communication with the subscriber ((= 2, M) are connected respectively with the second output and input (il) -ro of the communication unit with the subscriber, the second, third, fourth and fifth inputs and the second output of the communication unit with the computer are respectively the inputs of the signals for setting and resetting the interrupt resolution, polling for the presence of interruption and 'acknowledgment of the device and the output of the device interruption signal, the third input of the nth communication unit with the subscriber is the tth input of the communication request of the device, and the communication unit with the computer contains a transmitting and receiving οπίροΗΗ, the generator then ka, two trigger elements AND-NOT, the first element NOT and the delay element and the load resistor, and each communication unit with the subscriber is the receiving and first transmitting optocouplers, three triggers, two elements NOT, the OR element, the AND element, the delay element and the first load resistor, and in the communication unit with the computer, the output of the current generator is connected to the first input of the transmitting optocoupler, the output and second input of which are connected respectively to the first output of the block and the bus of the zero potential of the power source, and the third input through the load the source is with a bus of positive polarity of the power source, the first and second inputs of the receiving optocoupler are connected respectively to the first input of the block and the bus of negative polarity of the power source, and the output through the first element is NOT connected to the first input of the first I-элемента element, the second and third inputs and output connected respectively to the output of the first trigger, the fourth input of the block and the installation input of the second trigger, the output of which is the second output of the block and through the first delay element is connected to the first input of the second element NAND AND, with the output of the receiving optocoupler connected to the second input, the installation input of the first trigger and the reset inputs of the first and second triggers are the second, third and fifth inputs of the block, in each communication unit with the subscriber, the first input and output of the receiving optocoupler are connected respectively to the first the input of the block and the input of the first transmitting op. tron, the second input through the first load resistor with a bus of positive polarity of the power source, and the third input through the first element NOT - with the output of the first trigger and the first input of the NAND element, the second input connected through the second element NOT to the first output of the first receiving optocoupler, the third input through the delay element to the output of the second element NOT, and the output to the synchronization input of the second trigger and the reset input of the third trigger, the output of which is connected to the first input of the OR element, the synchronization input is to the third input m of the unit, and the information input - with the information input of the second trigger and the positive polar bus of the power supply, the installation input of the first trigger is connected to the output of the OR element, the input and second output of the first receiving optocoupler are connected respectively to the second input and the first output of the block , which distinguishes me by the fact that, in order to increase throughput, a counter is introduced into the communication unit with the computer, the third trigger, the third AND element, the AND element, the second NOT element, and the second and third delay elements, and in each ok, communication with the subscriber - the second transmitting optocoupler, the third element NOT, the fourth trigger, the counter, the second load resistor, the comparison node and the pulse shaper, and in the communication unit with the computing machine, the information input of the third trigger is connected to the output of the first element NOT, the synchronization input through the second HE element and the delay element connected in series with the output of the first delay element, the reset input with the counter reset input, the first input of the third NAND element and the output of the second trigger, and the output with the second input the house of the third AND-NOT element, the output of the device’s ready signal and the first input of the AND element, the second input connected to the output of the third AND-NOT element and through the third delay element to the second input of the second AND-NOT element, and the output to the synchronization input . counter, the output of which is the information output of the device, the third input of the third AND-NOT element is connected to the output of the receiving optocoupler, in each communication unit with the subscriber, the output of the fourth trigger is connected to the input, reset the first trigger, the reset input to the second input of the OR element, reset input the second trigger and through the pulse former to the first output of the first transmitting optocoupler and the counter synchronization input, the information input - to the output of the comparison node, and the synchronization input - to the inverse output of the second trigger and through the third element is NOT to the first input of the second transmitting optocoupler, the second input connected through the second • load resistor "to the bus of positive polarity of the power source, and the third input and output, respectively, with the first input and second output of the unit, the counter reset input is connected to the direct output of the second trigger, group of outputs - to the first group of inputs of the comparison node, the second group of inputs of which is corresponding to the inputs of setting the subscriber number of the device. ·