SU1277128A1 - Interphace for linking input-output channels with peripheral equipment - Google Patents

Abstract

The invention relates to the field of computing and can be used for switching and interfacing input-output devices and external memory with input-output channels of one or more computers. The device allows you to connect groups of I / O devices and external memory to the I / O channels of the computer, and allows you to organize common fields of I / O devices and external memory. The aim of the invention is to increase throughput by arranging a parallel polling signal to all groups of I / O devices and external memory, as well as to ensure the establishment of new connections without interrupting work in others. The goal is achieved by entering a device containing a group of interface matching blocks, a matrix of switching blocks and a priority block into a matrix of scanning blocks, a group of pulse shapers and a group of OR elements. 2 hp f-ly, 5 ill.

Description

eleven

The invention relates to computing and can be used for interfacing and switching input-output devices and external memory between the channels of one or more computers.

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

. FIG. 1 shows a block diagram of the device i in FIG. - functional diagrams of matrix switching units, matrix scanning units, priority unit; in fig. 5 - functional block diagram of interface matching.

The device (Fig. 1) contains a matrix of switching units 1, a group of 2 interface matching units, a matrix of 3 scanning units, a priority unit 4, buses 5, 6 and 7, 8 information outputs, inputs of the I / O channel and external devices, line 9 of signals request and lines 10 and 11 of resolution signals, line 12 of synchronization signal, line 13 of readiness signals of switching units, bus 1 of the second information input of the matrix, line 15 of resolution from external devices, line 16 of the first information output of the matrix, line 17 of the request signals of external devices TV, busses 18 and 19 of the second information output of block 2 and the first information input of matrix 1, line 20 of the scan line resolution signal, bus 21 and 22 of the second information inputs of block 2 and outputs of matrix 1, line 23 of the signal g ωness of matrix 3 .

FIG. 2 shows the elements of the OR 24 groups and the formers of the 25 pulses of the group connected to the switching blocks 26 of the matrix 1. Each switching block 26 contains a trigger 27, elements AND 28 and 29, elements OR 30 and 31, element 32, elements AND 33 and 34 of the first and the second group, the elements OR 35 and 36 of the first and second groups,. lines 38 of the third and fourth information inputs, lines 39 of response signals, lines 40 and 41 of response and transit signals, lines 42 and 43 of address recognition and reset signals from external devices.

Each scan block 44 of the matrix 3 (FIG. 3) consists of an element .HE 45, the first 46, the third 47, and the second 5

71

O 5

0 5 0

5 0 5

282

48 AND elements, OR elements 49 and 50, and 51 and 52 readiness and response signals are connected to each other through lines.

Each block of interface matching of group 2 (Fig. 4) contains a comparison node 54 (reactions to the initial sample), a device address setting node 55, a series of pulses of the terminating sequence, a node of 57 forming a series of pulses of a occupied device, node 58 of resolution communication, multiplexer 59, g element AND 60, flag generation node 61, flag storage node 62, priority node 63. The priority block 4 consists of line selection (orientation) nodes 64, each of which contains AND elements 65 and 66, NE element 67 and delay element 68.

Node 54 (FIG. 5) contains a group of comparison elements 69, a clock generator 70, a trigger 71, elements AND 72, OR 73 and NOT 74. Node 55 contains an address counter 75, an address number register 76, an address register 77, a delay element 78 and The fixed memory 79, Node 56 contains a group of elements And 80, elements NE 81 and 82, elements 83 and 84 of delay, triggers 85-87 and element And 88. Node 57 contains element And 89, trigger 90 and element 91 of delay. Node 58 contains a trigger 92 and an element OR 93. Node 61 contains a counter 94 and an element AND 95, and a node 62 - a decoder 96, a group of triggers 97, two groups of elements AND 98 and 99. Node 63 consists of a multistable trigger 100 and an encoder 101 ( Fig. 5).

The device works as follows.

In the initial state, O. is present on tires 5 and 7. O. is present on tires 6 and 8.

The establishment of a subchannel connection between the channel and the device is as follows. On the bus 9, the channel sends a single search request signal that passes through the corresponding; unit 4 input and via line 10 enters the input of node 58 (Fig. 4). At the same time, the search signal and the device address on bus 5 arrive at the input of node 54, which compares the address with the resolved addresses that come from node 55, followed by a control signal received at the input of elements 69 (the signal about issuing the last address from node 55 goes to inputs elements AND 72, OR 73).

If no address is compared, then node 54 blocks node 58 and in the case of a direct polling signal on pin 5, sends a reverse polling (unavailability) signal via bus 6 to the channel through multiplexer 59, thus signaling the lack of access channel to the device with the given address.

If the addresses are compared, then node 54 allows the search signal to pass through node 58 to line 11, prepares node 57 for operation, opens AND 60.

The signal on line 11 is ≤ 20 nt) and OR 49 on line 23 of bus 21

The cops And 28 (Fig. 2) of blocks 26 of the corresponding line, the outputs of these elements otplogoyut through elements OR 30 elements And 33, 34, which commute tires 14 to tires 22, and tires 19 - to buses 16, The signal on line 11 otkryshat elements And 33, 34 only if blocks 26 of the corresponding column of matrix 1 are free, i.e. line 40 receives a zero signal from the outputs of the remaining triggers 27 of this column through the elements of IL 31 of all blocks 26 of this column. Spread across the device, the search signal provides communication setup across all free columns.

Now it is necessary to select the desired subchannel connection, and release the rest. This is achieved by generating a single signal on the line 42 of bus 14 by an I / O device that identifies its address. With

the channel receives a reverse polling signal.

After the communication channel has been established, i.e. on one of the lines 20

25, bus 18 has received a highlight signal, the search must be cleared. The further appearance of the search signal in this installed subchannel does not affect its operation,

30 In the event that several search signals arrive on buses 9, block 4 (FIG. 4) is connected to only one input, elements AND 65 and HE 67 of node 64 of which have the smallest

35 response time. Thus, the time of activation is determined by the priority of connecting the inputs of block 4. Delay elements 68 protect block 4 from false triggering

40, ensuring reliable signal reliability along lines 10 when block 4 is installed in a certain state.

The reverse interrogation signal (ready) through line 23 enters via bus 21 through the AND 29 element set to 45 in the corresponding block 53 (FIG. 4), the trigger 27 of the corresponding block 26, which through the OR 30 element supports AND 33, 34 elements open . The signal arriving via line 42 of bus 21 (FIG. 5) to node 58 blocks Q and passes the signal of lines 11 to the output of flip-flop 92, freeing the remaining blocks 26 (communication subchannels).

blocking node 58 and allowing node 57 through multiplexer 59 to issue a sequence of busy devices. Through the open element 60 of node 57, a signal is received that adds +1 at node 61 and sets the address flag to which the call occurred, at node 62 .

A single signal on line 42 is outputted by the input-only device only when a single direct polling signal is received on line 17 (Fig. 2, 3) of bus 8 via OR 50 elements, which is generated by the presence of

2771284

on line 20 of the interrogation signal received through the AND 47 elements at the inputs of the OR elements 50 of the blocks 44 of the corresponding line. If this column is occupied, i.e. If any trigger 27 of block 26 of this column is set to one, then the element: And 47 is blocked by the signal of line 13 and the input direct interrogation signal does not pass to the blocks of 26 of this column. If the I / O device has not detected its address, the bus 7 line receives a reverse interrogation signal, which is fed to the inputs of the elements.

15 and 46 of this column. If none, the external device in this line does not recognize its address, either through the element 46 (if the column is free) or the elements 48 (if the column is empty).

the channel receives a reverse polling signal.

After the communication subchannel is established, i.e. on one of the lines 20

tires 18 have come to the selection signal, the search signal must be cleared. Further appearance of the search signal in this assigned subchannel does not affect its operation,

In case several search signals arrive on buses 9, block 4 (FIG. 4) is connected to only one input, elements AND 65 and NOT 67 of node 64 of which have the smallest

response time. Thus, the time of activation is determined by the priority of connecting the inputs of block 4. Delay elements 68 protect block 4 from false triggering

ensuring reliable signal strength along lines 10 when block 4 is installed in a certain state.

The return polling signal (ready) via line 23 is fed via bus 21 to the corresponding block 53 (FIG. 4),

blocking node 58 and allowing node 57 through multiplexer 59 to output a sequence of busy devices. At the same time, through an open element 60 of node 57, a signal is received that adds +1 at node 61 and sets the address flag that was accessed at node 62 .

If in the matrix 1 (Fig. 2) a column is freed (i.e., an I / O device is freed), the corresponding driver 25, executed, for example, as a one-shot, through ele 5, 12

cops OR 2k sends on line 12 a signal that arrives at all nodes 61 (Fig. 4).

If the contents of counter 94 are not zero, then one is subtracted from it. The node 61 prepares the node 56 to receive the address and allows the node 62 to transmit signals to the node 63 to fetch the addresses. Node 63 permits Node 55 to transmit the address of the highest priority I / O device to Node 56 and clears the check box of the selected address. If the channels currently do not work with I / O devices, i.e., there is no single signal on line 11, the termination sequence is output to the channels, node 56 via multiplexer 59. To establish a communication subchannel, the channel must again send a single search signal with the address I / O and polling signal The device operates in the same way as described above.

If the contents of counter 94 are zero, then the unit is not subtracted and node 56 is blocked.

The release of the communication subchannel is performed by the signal of the end of the communication, coming through line 43 of the terminal 14 (Fig. 2) to the synchronization input of the trigger 27 of the corresponding block 26. Since the information input of the trigger 27 contains a signal c. zero tires. The trigger 27 is set to the zero state by closing the elements And 33, 34 and the elements 46, 47, for removing the signal of the end of communication (falling edge) in line 43, which is removed by the input-output device on the receipt of the response of the reception of this signal bus 5 from the input-output channel.

During the entire time from the beginning of the connection to the release of the subchannel of communication, the And 33, 34 and And 46,47 elements are reliably opened first by a signal on line 11 from block 53 through elements 28, OR 30, then trigger 27, i.e. during this time, the communication is established, the information is transmitted, the termination of the communication by signals from tires 5 to PMNA 8 and from tires 7 to tires 6.

Since the interrogation signal enters the columns in parallel, first, the establishment of the communication channel is faster than with a sequential interrogation of an I / O device.

86

Secondly, if some I / O device pushed to one of the columns of matrix 1 recognized its address, the connection establishment is not affected either by an erroneous operation because the failure (for example, the loss of the interrogation signal) of the I / O devices connected in other columns. Block 4 is ready to establish subchannels of communication on other lines immediately after the search signal is removed in this line. Moreover, the installation of a new communication subchannel in a column in which at least one trigger 27 is installed is impossible, since AND 28 elements are locked with a zero signal from the HE element 32.

Consider the operation of block 53, for example, when the input-output channels of a computer and input-output devices establish communication by exchanging the signals given below:

Channel Signals Computer Input / Output Search Signal Survey Poll Signal

Reception Signal Termination Signal

Device Signals I / O Release Signal Reverse Poll Signal

Request signal Address ID

Occupancy Signal Termination Signal Status Identifier

On bus 5. a channel supplies the address of a device to the first group of inputs of comparison elements 69, and the search signal, running generator 70, which by a signal from the third output resets counter 75 to its initial stateJ produces a signal arriving at inputs of counter 75,. and register 77. From the permanent memory 79, through the register 77, the address of the input-output device is fed to the second group of inputs of the comparison elements 69. The address comparison is performed on the enable signal from counter 75.

If the addresses are compared, then a single signal is sent to the information input of the trigger 71, which, according to the control signal from the generator 70

7

sets trigger 71 to one. The delay of the signal at the second output of the generator 70 relative to the signal at the first output ensures a reliable trigger trigger 71.

The signal from the single output of the trigger 71 stops the operation of the generator 70 through the element IL 73, sets the trigger 92 in accordance with the presence or absence of a search signal at the information input, prepares And elements 60, 89.

If no address is compared, then the counter 75 on the second output disables the operation of generator 70. and opens element 72, through which the direct interrogation signal from buses 5 enters the input of multiplexer 59, which ensures its passage through the reverse interrogation signal line tires 6.

If the reverse polling signal is received along the line 23 of bus 21 (i.e., the device is connected via another channel), the trigger 92 is set to the zero state 92 and the 89 element opens to the first and second inputs of which are fed from the channel through the buses 5, a direct polling signal and a search signal, which enable the trigger 90 to be set to one.

The signal from trigger 90 through AND 60 adds +1 to counter 94, sets AND 60 and 99 sets trigger 97 to the address number on register 76, the contents of which are decrypted by decoder 96J, which generates an occupancy signal element 91.delays, comes with id

After receiving signals that indicate the release of a device, the channel sends a signal to the final device (via a trigger 90) via bus 5 via a multi-45 connection that resets the trigger 59 that provides them. Р ° „

Block 53 is in the initial state.

transfer through bus 6 to the channel.

Upon receipt of a signal that the device is busy, the channel by the signal of the termination of the communication coming through the buses 5 to the installation input, to the zero of the trigger 90, resets it.

If a signal is received on line 12 (i.e., a column is vacated), then element AND 95 is discarded. If the contents of counter 94 are nonzero. then the signal from the output element ...: And 95 reduces the contents of counter 94 by one computer channel can establish communication with the freed device by Q sending the search signal and device address to the bus 5.

The implementation of block 5 in accordance with the example in FIG. 5 is effective when the computer channels are slow to work.

There are 5 I / O devices in multiplexed mode, in which the communication time is significantly shorter than the period between communication sessions. In this case, the column free column is a frequent event.

28

eight

tsu sets the single-state trigger 85, if the channel allows access to it, i.e. there are no signals at the inputs of the HE elements 81 and 82, the trigger 85 generates a request signal, which through the multiplexer 59 enters the channel through the 6J buses opens the elements AND 98, through which the signals from the single inputs of the trigger 97 reach the multistable trigger 100, which passes on the encoder 101 a single signal | from only one trigger 97, which is set to the zero state by this signal; allows through the delay element 78 to read the address number from the encoder 101 into the register 76 and through the register 77 to read the device address to the input of the AND 80 elements.

Upon receiving the request signal, the channel sends a 5 direct polling signal through the buses, which sets the signal to zero

the state of the trigger 85, opens the elements And 80, allowing the address to pass through the multiplexer 59 and bus 6 to the computer channel, sets up through the element 83 of the delay to the single state the trigger 86, which generates the address identifier incoming through the multiplexer 59 into the computer channel.

Having received the device address, the channel sprinkles the reception signal onto buses 5, which sets the trigger 86 to the zero state, sets the trigger 87 to one state, which outputs the termination signal and, through the delay element 84, the device status identifier These signals are multiplexed 59 and tires 6 enter the channel.

Having received the signals that indicate the release of the device, the channel sends a bus termination signal through the busses 5, which resets the channel three times, the computer can establish a connection. with the vacant device by means of Q signaling the search signal and the device address on the bus 5.

The implementation of block 5 in accordance with the example in FIG. 5 is effective when slow I / O devices are operated with computer channels in a multiplexed mode, in which the communication time is much shorter than the period between communication sessions. In this case, free columns are frequent events.

Thus, the device provides an increase in throughput due to the effective use of communication subchannels by organizing parallel work on several CMI subchannels at the same time, removing restrictions on the device configuration, and parallel scanning of devices when the communication channel is installed.

Claims (3)

1 The invention relates to computing and can be used for interfacing and switching input-output devices and external memory between the channels of one or several computers. The aim of the invention is to increase the capacity of the device. . FIG. 1 shows a block diagram of the device i in FIG. - functional diagrams of matrix switching units, matrix scanning units, priority unit; in fig. 5 is a functional block diagram of interface matching. The device (Fig. 1) contains matrix 1 of switching units, group 2 of interface matching blocks, matrix 3 of scanning blocks, priority block 4, buses 5, 6 and 7, 8 information outputs, I / O channel inputs and external devices, line 9 request signals and lines 10 and 11 of resolution signals, line 12 of synchronization signal, line 13 of readiness signals of switching units, bus 1 of the second information input of the matrix, line 15 of resolution from external devices, line 16 of the first information output of the matrix, line 17 of the request signals of external devices TV, buses 18 and 19 of the second information output of block 2 and the first information input of matrix 1, line 20 of the scan resolution resolution signal of bus line 21 and 22 of the second information inputs of block 2 and outputs of matrix 1, line 23 of readiness signals of matrix 3. In FIG. 2 shows the elements of the OR 24 groups and the formers of the 25 pulses of the group connected to the switching blocks 26 of the matrix 1. Each switching block 26 contains a trigger 27, elements AND 28 and 29, elements OR 30 and 31, element 32, elements AND 33 and 34 of the first and the second group, the elements OR 35 and 36 of the first and second groups,. lines 38 of the third and fourth information inputs, lines 39 of response signals, lines 40 and 41 of response and transit signals, lines 42 and 43 of address recognition and reset signals from external devices. Each block 44 of scanning the matrix 3 (FIG. 3) consists of the element .NE 45, the first 46, the third 47 and the second 482 AND elements, the OR elements 49 and 50 and are connected to each other through the lines 51 and 52 of the ready and answer signals . Each block of interface matching of group 2 (Fig. 4) contains a comparison node 54 (reactions to the initial sample), a device address setting node 55, a series of pulses of the terminating sequence, a node of 57 forming a series of pulses of a occupied device, node 58 of resolution communication, multiplexer 59, g element AND 60, flag generation node 61, flag storage node 62, priority node 63. The priority block 4 consists of line selection (orientation) nodes 64, each of which contains AND elements 65 and 66, NE element 67 and delay element 68. Node 54 (FIG. 5) contains a group of comparison elements 69, a clock generator 70, a trigger 71, elements AND 72, OR 73 and NOT 74. Node 55 contains an address counter 75, an address number register 76, an address register 77, a delay element 78 and The fixed memory 79, Node 56 contains a group of elements And 80, elements NE 81 and 82, elements 83 and 84 of delay, triggers 85-87 and element And 88. Node 57 contains element And 89, trigger 90 and element 91 of delay. Node 58 contains a trigger 92 and an element OR 93. Node 61 contains a counter 94 and an element AND 95, and a node 62 - a decoder 96, a group of triggers 97, two groups of elements AND 98 and 99. Node 63 consists of a multistable trigger 100 and an encoder 101 ( Fig. 5). The device works as follows. In the initial state, O are present on buses 5 and 7. Here, O is present on buses 6 and 8. A subchannel is established. The connection between the channel and the device is as follows. On bus 9, the channel sends a single query search signal that passes through corresponding input block 4 and through line 10 enters the input of node 58 (Fig. 4). At the same time, the search signal and the device address on bus 5 arrive at the input of node 54, which compares the address with the resolved addresses that come from node 55, followed by a control signal received at the input of elements 69 (the signal about issuing the last address from node 55 goes to inputs elements AND 72, OR 73). If no address is compared, then node 54 blocks node 58 and in the case of a direct polling signal on pin 5, sends a reverse polling (unavailability) signal via bus 6 to the channel through the multiplexer 59, thus signaling the absence of a signal access to the device with the given address. If the addresses are compared, the node 54 permits the search signal to pass through the node 58 to line 11, prepares the node 57 for operation, opens AND 60 element. The signal on line 11 opens 20 units and 28 units (Fig. 2) 26 of the corresponding line, the outputs of these elements otkrgoyut through the elements OR 30 elements AND 33, 34, which commute the bus 14 to the bus 22, and the bus 19 - on the bus 16, the signal on line 11 otkryshat elements And 33, 34 only if the blocks 26 of the corresponding column of matrix 1 are free, i.e. line 40 receives a zero signal from the outputs of the remaining triggers 27 of this column through the elements of IL 31 of all blocks 26 of this column. Spread across the device, the search signal provides communication setup across all free columns. Now it is necessary to select the desired subchannel connection, and release the rest. This is achieved by forming a single signal on the line 42 from the bus 14 with an input / output device that identifies its address. In this case, the trigger 27 of the corresponding block 26 is installed through the AND 29 element, and through the OR 30 element supports the AND 33, 34 elements open. The signal, coming through line 42 of bus 21 (FIG. 5) to node 58, blocks the signal from lines 11 to the output of trigger 92, freeing the remaining blocks 26 (communication subchannels). A single signal on line 42 is output by an input-only device only when a single direct polling signal is received on line 17 (Figs. 2, 3) of bus 8 via OR 50 elements, which is generated by the presence of 1,284 on line 20 of a polling signal coming through the elements AND 47 to the inputs of the elements OR 50 blocks 44 of the corresponding line. If this column is occupied, i.e. if one trigger 27 of block 26 of this column is set to one, then the element: AND 47 is blocked by the signal of line 13 and the input direct interrogation signal does not pass to the blocks 26 of this column. If the I / O device has not detected its address, a bus line 7 sends a return polling signal, which is fed to the inputs of the AND elements of this column. If none, the external device in this line did not recognize its address through AND 46 (if the column is free) or AND 48 (if the column is OR- 49 through the line 23 of the bus 21 to the channel receives a reverse polling signal. After the subchannel connection is established, i.e. one of the lines 20 of bus 18 has received a selection signal, the search signal must be cleared. Further appearance of the search signal in this assigned subchannel does not affect its operation. In case of tires 9 several search signals arrive, block 4 (FIG. 4) is connected only to The first input, the elements of AND 65 and HE 67 of node 64 of which have the shortest response time. Thus, the activation time determines the priority of connecting the inputs of block 4. Delay elements 68 protect block 4 from false triggering, ensuring reliability of the vertical signals during installation to a certain state of block 4. A reverse interrogation signal (ready) on line 23 arrives via bus 21 to the corresponding block 53 (Fig. 4), blocking node 58 and allowing node 57 through multiplexer 59 to output a sequence of busy devices. At the same time, through an open element 60 from node 57, a signal is received that adds +1 at node 61 and sets the address flag to which the call occurred at node 62. If a column is freed in the matrix 1 (Fig. 2) (i.e., an I / O device is freed), the corresponding driver 25, executed, for example, as a one-shot, through ele 5, 1 cops, OR 2k sends 12 sig cash that goes to all nodes 61 (Fig. 4). If the contents of counter 94 are not zero, then one is subtracted from it. Node 61 prepares node 56 for addresses when it is enabled, and allows node 62 to transmit signals to sample node 63 to node 63. Node 63 permits Node 55 to transmit the address of the highest priority I / O device to Node 56 and clears the check box of the selected address. If the channels currently do not work with I / O devices, i.e., there is no single signal on line 11, the termination sequence is output to the channels, node 56 via multiplexer 59. To establish a communication subchannel, the channel must again send a single search signal with the address I / O and polling signal The device operates in the same way as described above. If the contents of counter 94 are zero, then the unit is not subtracted and node 56 is blocked. The release of the communication subchannel is performed by the signal of the end of communication coming in via line 43 at 14 (Fig. 2) to the synchronization input of trigger 27 of the corresponding block 26. As the information input trigger 27 there is a signal with. zero tires. The trigger 27 is set to the zero state by closing the And 33, 34 and And 46, 47 elements, for removing the termination signal (falling edge) on line 43, which is removed by the Bus I / O device. 5 from the input-output channel. During the entire time from the beginning of the connection to the release of the sub-channel, the And 33, 34 and And 46,47 elements are reliably opened first by a signal on line 11 from block 53 through And 28, OR 30, then trigger 27, i.e. during this time, the establishment of communication, the transfer of information, the termination of communication by signals coming from buses 5 to PMNA 8 and from buses 7 to buses 6. Since the interrogation signal enters the columns in parallel, firstly, the establishment of a communication channel is faster than polling an I / O device. 86 and, secondly, if some I / O device pushed to one of the columns of matrix 1 recognized its address, the connection establishment is not affected by the erroneous operation or failure (for example, the loss of the polling signal) of the input devices output connected in other columns. Block 4 is ready to establish subchannels of communication on other lines immediately after the search signal is removed in this line. Moreover, the installation of a new subchannel of communication over a column in which at least one trigger 27 is installed is impossible, because elements AND 28. are locked with a zero signal from the element 32. Consider the operation of block 53 for example, when the input-output channels of the computer and I / O devices establish communication by exchanging the signals below: Channel signals Signal I / O search for a computer Direct interrogation signal Receive signal Signal termination of signals Device signals I / O separation signal Interrogation signal Interrogation signal Adapter identifier sa Occupation signal Termination signal Identifier of the state On bus 5. The channel gives the device address to the first group of inputs of 69 comparison elements, and the search signal, starting generator 70, which by the third output resets the counter 75 to the initial stateJ generates a signal arriving at the inputs of the counter 75, register 76 and register 77. From the permanent memory 79 through the register 77 enters the address of the input-output device to the second group of inputs of the comparison elements 69. Comparison of addresses is performed by the enable signal from the counter 75. If the addresses are compared, then a single signal arrives at the information input of the trigger 71, which, by a control signal from the generator 70 7, sets the trigger 71 to the single state. By delaying the signal at the second output of the generator 70 relative to the signal at the first output, trigger 71 acts reliably. The signal from the single output of the trigger 71 stops the generator 70 through the element OR 73, sets the trigger 92 according to the presence or absence of the search signal at the information input, prepares elements And 60, 89. If no address is compared, then the counter 75 on the second output prohibits the operation of the generator 70. and opens the element 72, through which the direct interrogation signal from the tires 5 enters t to the input of multiplexer 59, which ensures its passage to the channel along the line of the reverse signal of the bus 6 polling. If the reverse signal of the polling post drank on the line 23 of bus 21 (i.e., the device is placed on another channel), then through the element OR 93 The trigger 92 is set to the zero state and the element 89 is opened, the first and second inputs of which are fed from the channel through the buses 5 to the direct interrogation signal and the search signal, which ensure that the trigger 90 is set to one. The signal from the trigger 90 through the element And 60 adds +1 to counter 94, through elements 60 and 99 establishes a trigger 97 corresponding to an address number located on register 76, the contents of which is decrypted by decoder 96J, which generates an busy signal which, when passed through delay element 91., comes along with the device status identifier It is operated by trigger 90) through multi-detector 59, which ensures their transmission through buses 6 to the channel. Upon receiving a signal about the device's occupation, the channel by the signal of the termination of the communication coming through the busses 5 to the installation input, to the zero of the trigger 90, resets it. If a signal is received on line 12 (i.e., a column is vacated), then element 95 is turned off. If the contents of counter 94 are not zero, then the signal from the output of element ...: and 95 decreases the contents of counter 94 by one, sets the single-state trigger 85, if the channel allows access to it, i.e. there are no signals at the inputs of the HE elements 81 and 82, the trigger 85 generates a request signal which, through multiplexer 59, enters the channel through the 6J buses opens the AND 98 elements, through which the signals from the single inputs of the trigger 97 arrive at the multistable trigger 100, which passes the encoder 101 unit signals from only one trigger 97, which is set to zero state by this signal; resolves through the delay element 78 the reading of the address number from the encoder 101 to the register 76 and through the register 77 - reading the device address to the input of the AND elements 80. Upon receiving the request signal, the channel sends a direct interrogation signal through bus 5, which sets the trigger 85 to the zero state , opens the elements And 80, allowing the passage of the address through the multiplexer 59 and bus 6 to the computer channel, sets through the delay element 83 to the one state trigger 86, which generates the address identifier incoming through the multiplexer 59 to the computer channel . Having received the device address, the channel sprinkles the reception signal onto the busses 5, which sets the trigger 86 to the zero state, sets the trigger 87 to one state, which outputs the termination signal and, via the delay element 84, identifies the device state. These signals are transmitted through multiplex 59 and buses 6 enter the channel. Having received the signals that indicate the release of the device, the channel sends a bus termination signal via bus 5, which resets the Trig P ° Block 53 - to its initial state. and the computer channel can establish a connection. with the device freed by sending a search signal and the device address to the bus 5. The implementation of block 5 in accordance with the example in FIG. 5 is effective when computer channels are slow. I / O devices in the multi-band mode, in which the time in communication is much less than the period between communication sessions. In this case, the column columns are frequent events. Thus, the device provides an increase in throughput due to the effective use of communication subchannels by organizing parallel work on several CMM subchannels at the same time, removing restrictions on the device configuration, and concurrently polling the device when the communication channel is installed. Claim 1. Device for interfacing input-output channels with external devices, containing a group of interface matching units, a priority block and a switching unit matrix, the first information inputs and outputs i-rq of the interface matching unit (, N) are connected respectively with informational outputs and inputs of the i-ro I / O channel, and the second information output - with the first informational inputs of the switching units of the 1st row of the matrix, the second informational inputs of the switching units of the j-ro column of the matrix (. AND) Eny with information output j-ro external device, the third and fourth information inputs of the switching unit of the i-th row and j-ro column are connected respectively to the first MU output of the switching unit (1-1) -th row and j-ro column of the matrix and the second the output of the row switching unit and (j-1) -ro matrix column, characterized in that, in order to increase the device capacity, a matrix of scanning blocks, a group of pulse shapers and a group of OR elements are introduced into it, and the query inputs and block resolution outputs priority connected respectively, to the request outputs of the corresponding input channels d-a-output and the resolution inputs of the corresponding interface matching units of the group synchronized; whose inputs are connected to the output of the Mth OR element of the group enabling the inputs of the i-th switching units to the enabling output An i-ro interface negotiation unit whose second information input is connected to. the second information output of the switching unit of the 1st row and the Mth matrix column and the readiness output of the i-th line scan block and M-th matrix column; the resolution inputs of the scan blocks of the i-th matrix row are connected to the second information output of the interface matching unit and the readiness input of the scanner of the i-th row and the first column of the matrix, the first information output of the switching unit of the N-th row and j-ro column of the matrix and the output of the response of the scanner of the N-th row and the j-ro column of the matrix are connected respectively to the information The j input input and input j-ro of the external device whose resolution output is connected to the readiness inputs of the j-ro matrix scan columns, the readiness outputs of which are connected to the polling inputs of the row of the corresponding scan blocks (j-1) of the matrix column, the output outputs of the scanning blocks The i-th row of the matrix is connected to the transit inputs of the column of the corresponding scan blocks (1 + 1) -th row of the matrix, the inputs of the scan request block of the i-th row and the j-ro column of the matrix are connected to the readiness output of the i block the rows and j-ro columns of the matrix, whose answer VIESOD is connected to the transit input of the switching unit (1 + 1) -th row and j-ro column of the matrix, and the blocking input - with the output of the response of the switching unit of the Nth row and j-ro column matrix and through the j-th group pulse shaper - with the first input of the j-ro element OR group, the second input. which is connected to the output (j-l) -ro of the element OR group. 2. The device according to claim 1, characterized in that each block scanning the matrix contains three elements AND two elements OR and element NOT, the output of the first element OR is the output of the ready block, and the first and second inputs are connected respectively to the outputs of the first and The second elements are And, the first inputs of which are connected to the polling input of the block line, and the second inputs, respectively, with the input of the block request and the output of the NOT element, the input of the block connected to the input of the request and the first input of the third And element, the second input and output of which and, yen, respectively, with a block enable input and a first input of the second IL, the second input and output of which are respectively a transit input and a block response, the third input of the first element I is connected to the block ready input. 3. The device according to claim 1, characterized in that each switching unit of the matrix contains a trigger, two elements AND, two elements SH, two groups of elements AND, two groups of elements OR, and element NOT, and the outputs of elements SH of the first and second groups form respectively the first and second information outputs, and the first inputs are the third and fourth information inputs of the block, respectively; the first inputs of the AND elements of the first and second groups are connected respectively to the second and first information inputs of the block; the outputs, respectively, to the second the inputs of the second and the first groups of LII elements and the second inputs are with the unit ready output and the output of the first element OR, the first input connected to the output of the first element AND and the first input of the second element AND, and the second input to the output of the trigger and the first input of the second element OR, The second input and output of which are, respectively, a transit input and a response of the block response, the first input of the first terminal AND is connected to the block enable input, and the second input through the NOT element to the blocking input input, the second input of the second element I and input The trigger trigger is connected to the second information input of the block, the trigger information input is connected to the logical zero bus, and the setup input is connected to the output of the second element I. 13 G7