SU593626A1 - Duplex multichannel time-multiplexing system for transmitting binary information - Google Patents

Description

the same control unit, whose information input is connected to the start-up regenerator input, the clock input is connected to the start-stop regenerator clock output, and the control output is connected to the corresponding start-up regenerator input, while the additional start-stop regenerator input is the clock input of the code-dependent channel forming node, a control input of which is an additional input of a matching storage device; each code-dependent channel signal recovery node contains serially connected matching drive, switch and output pulse shaper, as well as a dial-up regenerator, phasing unit and control unit, and the control inputs of the matching drive and phasing unit are connected and are the control input of the recovery node code-dependent channels, the clock input of which is connected to the corresponding inputs of the dial pulse generator, control unit and block and the phasing, the clock output of which is connected to the clock input of the matching accumulator, the additional information output of the latter is connected to the corresponding input of the control unit directly, and to the input of the dial pulse generator through the phasing unit, the control outputs of the control unit are connected to the corresponding inputs of the phasing unit, the regenerator dialing pulses and a switch, the second information input of which is connected to the output of the dial pulse generator. FIG. 1 shows the structural electrical circuit of the proposed system; in fig. 2 is a structural electrical circuit of a signal generating unit for code-dependent channels; in fig. 3 is a structural electrical circuit of a node for recovering signals of code-dependent channels. The duplex multichannel binary information transmission system with time compression contains in the transmitting part a clock pulse generator 1 connected to distributor 2, a signal-generating channel forming unit 3, the control inputs of which are connected to the outputs of the distributor 2, and outputs are connected to information inputs of the adder 4, it the control input is connected to the output of the clock pulse generator 1, and the output is connected to the communication channel through the output matching unit 5, in the receiving part of the multichannel system contains t input matching unit 6, the synchronizing output of which is connected to the input of the distributor 7, whose outputs are connected to the control inputs of the recovery unit 8 of code-independent channel signals, whose information input is connected to the information output of the input matching unit 6, l of the code-dependent channel forming units, their clocks the inputs are connected to the corresponding output of the generator 1 clock pulses, the control inputs are connected to the output of the distributor 2, and the outputs are connected to the inputs of the adder 4, n nodes 10 in signals of code-dependent channels, their information inputs are connected to the corresponding output of the input matching unit 6, the control input of each of the nodes 10-1-10-recovery of the code-dependent channel signals is connected to the corresponding output of the distributor 7, and the clock input is connected to the corresponding output of the input matching unit 6, with the nodes 10-1 to 10-p of recovering signals of code-dependent channels and the corresponding nodes 9-1 to 9-p of forming signals of code-dependent channels interconnected The operation, each node 9-1-9-n of forming signals of code-dependent channels contains serially connected input shaper 11 pulses (see FIG. 2), the start-stop regenerator 12 and the matching drive 13, as well as the control unit 14, whose information input is connected to the input of the start-stop regenerator 12, the clock input is connected to the clock output of the start-stop regenerator 12, and the control output is connected to the corresponding input of the start-stop regenerator 12, with This additional input of the start-up regenerator 12 is the clock input of the node 9-1-9-l of the formation of signals of code-dependent channels, the control input of which is the additional input of the matching signal opitel 13, and each node 10-1 - 10-l recovery of code-dependent channel signals contains serially connected matching drive 15, switch 16, output pulse shaper 17, regenerator 18 dialing pulses, phasing unit 19 and control unit 20, with control inputs the matching accumulator 15 and the phasing unit 19 are connected, are the control input of the node 10-1 - 10-l of the recovery of signals from the code-dependent channels, its input is connected to the corresponding moves of the regenerator 18 dialing pulses, With the 20th control unit and the lasing unit 19, the clock output of which is connected to the clock input of the matching battery 15, the additional information output of the latter is connected to the corresponding input of the control unit 20 directly, and to the input of the regenerator 18 dialing pulses through the phasing unit 19, the control outputs of the unit 20 control units are connected to the corresponding inputs of the phasing unit 19, the dial pulse regenerator 18 and the switch 16, the second information input of which is connected to the output of the pulse regenerator 18 dialing a number.

A duplex multichannel binary data transfer system with a temporary compression works as follows.

Signals L of code-dependent channels () are sent to the information inputs of nodes 9-1-9-n, the clock inputs from the output of generator 1 receive clock pulses, and the control inputs are pulses from the output of distributor 2. Each of the nodes 9-1- 9-p operate in one of three modes: regeneration mode and transmission of start-stop telegraph signals, generation mode and transmission of dialing pulses, and code-dependent channel control mode.

The signals from the outputs of the nodes 9-1 to 9-n are combined by the adder 4 and at the allotted time intervals are transmitted through block 5 to the communication channel.

The input signals of the code-independent channels are fed to the input of block 3, which converts anisochronous signals into isochronous signals using special coding. The encoded signals are fed to the input of the adder 4, which sequentially transfers them through block 5 to the communication channel.

The group signal from the communication channel is fed to the input of block b, providing cyclic phasing of the distributor 7 and transmitting the group signal to the corresponding inputs of nodes 10-1-10-l, each of these nodes can operate in one of three modes: recovery mode for start-stop telegraph signals , the mode of regeneration of dialing pulses and the mode of recovery of control signals of code-dependent channels.

The group signal arriving at the inputs of block 8, by means of the control pulses of the distributor 7, is divided into separate channel sequences with the restoration of significant modulation moments in each independent code.

The input signal to the input of one of the nodes 9-1-9-p is converted in the input shaper 11 (see Fig. 2) in the form of polarity and level and at certain time intervals is fed to the information inputs of the block 14 and the regenerator 12, operating in one of three modes: selection of the start-stop transition and regeneration of the input telegram signal, selection mode

stop start and gating the input pulses of the number and the selection mode of the start / stop transition and gating of the input control signals of the code-dependent channel.

The output signal and clock pulses of the regenerator 12 at intervals of time allocated for processing this code-dependent channel are fed to the input of accumulator 13, in which the nominal wiring speed is matched to the speed of channel pulses. The group signal from the output of block 6 is fed to the information input of accumulator 15, in its input cell at intervals of time allocated for processing the signal of this code-dependent channel, it is extracted, while in the first mode of operation of accumulator 15 the start-stop signal is restored by the speed and duration of the start-stop signal cycle, in the second mode, the regenerator 18 converts the parameters of dialing pulses in accordance with the applicable standards and in the third mode, the frequency of the read cycles is set It is equal to the nominal wiring speed.

The selection of the appropriate mode is carried out in block 20, while block 19 provides start-stop phasing and the formation of a start-stop cycle of a predetermined duration. When the switch 16 arrives at its control input, the switch 16 transmits in the first and third modes signals from the output of accumulator 15, and in the second mode - from the output of the regenerator 18. Signals from the output

the switch 16 is converted in the driver 17 into an output telegraph signal and is fed to the output of this code-dependent channel. Such a system provides increased

throughput and utilization of a compressed communication channel.

Claims (3)

1. Duplex multichannel system transmitting binary information with time compression, containing in the transmitting part a clock pulse generator connected to the distributor, a coding-independent signal generating unit channels, the control inputs of which are connected to the outputs of the distributor, and the outputs are connected to the information inputs of the adder, the control input of which is connected to the output of the clock generator, and the output is connected to the communication channel through the output matching unit, in the receiving part the multichannel system contains the input matching block, snihroniziru; whose output co.d.d.d of the distributor, whose outputs are connected to the control inputs of the recovery unit for code-independent channels, whose information input is connected to the information output of the input matching unit, characterized in that, in order to increase the capacity of the system, the transmitting part is entered by nodes of forming code-dependent channel signals, the clock inputs of which are connected to the corresponding output of the clock generator, the control inputs are connected to the output of the distributor, and the outputs connected to the inputs of the adder, into the receiving part entered n nodes of recovery of code-dependent channels, the information inputs of which are connected to the corresponding output of the input matching unit, the control input of each of the recovery nodes of the code-dependent channels is connected to the corresponding output of the distributor, and the clock input is connected to the corresponding output input matching unit, with the code-dependent channel signal recovery nodes and the corresponding codeose signaling nodes isimyh channels are interconnected chains reacting. 2. The system of claim 1, wherein each node of forming code-dependent channel signals comprises a serially connected input pulse shaper, a start / stop regenerator and a matching drive, as well as a control unit, whose information input is connected to the start / stop regenerator input, a clock input is connected to the clock output of the start-stop regenerator, and the control output is connected to the corresponding input of the start-stop regenerator, while the additional input of the start-stop regenerator L is a clock input node forming the code-dependent channel signals, a control input of which is an additional input matching accumulator. 3. The system according to claim 1, characterized in that each node of the recovery of signals of code-dependent channels contains serially connected matching the accumulator, the switch and the output pulse shaper, as well as the dial pulse regenerator, the phasing unit and the control unit, the control inputs of the matching drive and The phasing unit is connected and is the control input of the code-dependent channel signal recovery node, the clock input of which is connected to the corresponding inputs of the pulse generator dialing, control unit and phasing unit, the clock output of which is connected to the clock input of the matching drive, the additional information output of which is connected to the corresponding input of the control unit directly, and to the input of the dialer regenerator through the phasing unit, the control outputs of the control unit are connected to appropriate the inputs of the phasing unit, the dial pulse regenerator and the switch, the second information input of which is connected to the output of the dial pulse regenerator. lunge I hanal c & ampu  W node Rig Tantalum b HfjaEjiflmmuu Sxod To supporter Out Kuz / iv 9