RU2234195C1 - Multichannel digital communication system - Google Patents

Abstract

FIELD: electrical communications; multichannel digital communication systems.

SUBSTANCE: proposed multichannel digital communication system that incorporates provision for considering users' needs for varying data transfer speed and has generators, switching units, transmitting aggregate unit, receiving aggregate unit, transmitting individual units, receiving individual units, control signal transfer unit, control instruction receiver, AND gate, and OR gate is provided in addition with code converter, arriving load evaluating unit, radiation power control unit, transmitter, and common signaling channel unit.

EFFECT: reduced power requirement of communication line.

1 cl, 10 dwg

Description

The invention relates to the field of telecommunications and can be used in digital multi-channel communication systems.

Known digital transmission system (DSP), using the principles of temporary separation of channels and designed to organize multi-channel communication lines / 1 /. In such DSPs, a group digital signal is formed by temporarily combining digital streams formed by systems with analog-to-digital signal conversion or systems with a temporary grouping of a lower order. However, the group stream speed in such systems does not change depending on the actual load of the combined digital channels.

Digital speech interpolation systems are also known that allow the transmission of q-incoming channel signals along an r-channel group path (r outgoing channels, where r <q) due to the fact that incoming channels in which the subscriber is currently silent are not transmitted / 2, 3 /. However, in such systems, during congestion, when the number of "active" channels exceeds the number of outgoing channels, information is lost (clipping) in the channels that go into the active state.

Closest in essence to the claimed device is the well-known multi-channel digital communication system described in the USSR author's certificate No. 1800631 of 03/07/93, IPC ⁷ H 04 J 3/24, published. in bull. No. 9 03/07/1993 / 4 /.

The closest analogue (prototype) contains on the transmitting side a generator, AND elements, an OR element, a transmitting group unit, a switching unit, transmitting individual units, a control signal transmission unit, a divider and a control memory unit, the generator outputs being connected to the second inputs of the I. elements. Outputs the switching unit is connected to the signal inputs of the transmitting individual units, the outputs of which are connected to the corresponding inputs of the transmitting group unit, the first and second outputs of which are connected respectively but with the first input of the receiving group unit and with the signal inputs of the switching unit. The outputs of the switching block are connected to the second inputs of the transmitting individual blocks, the corresponding output of the switching block is connected to the clock input of the transmission block of control commands, the output of which is connected to the information input of the last transmitting individual block, and the information inputs of the remaining transmitting individual blocks are information inputs of the system. The additional input of the transmitting group unit is connected to the output of the OR element, the inputs of which are connected to the outputs of the AND elements, the first inputs of which, as well as the control inputs of the switching unit and the information inputs of the control signal transmission unit, are connected to the outputs of the control memory unit, the input of which is connected to the output of the divider, the input of which is connected to the corresponding output of the generator, and on the receiving side contains a generator, AND elements, an OR element, a receiving group unit, a switching unit, individual receivers n blocks, the receiver of control commands, and the generator outputs are connected to the second inputs of elements I. Some outputs of the receiving group block are connected to the first inputs of the receiving individual blocks, other outputs are connected to the inputs of the switching block, the outputs of which are connected to the second inputs of the receiving individual blocks, the output of the last the receiving individual unit is connected to the first input of the receiver of control commands, and the outputs of the remaining receiving individual units are information outputs of the system. The first outputs of the control command receiver are connected to the second inputs of the switching unit, the corresponding output of which is connected to the second input of the control command receiver, the third input of which is connected to the second OR element, and the second outputs are connected to the first inputs of the AND elements, the outputs of which are connected to the inputs of the OR element, the output of which is connected to the second input of the receiving group unit.

In the prototype device, using combinations of control signals coming from the outputs of the control memory block that are optimal for a specific time of day (for specific conditions for transmitting information), one can obtain such a frequency of clock pulses at which the transmission and reception speeds in the group path of the system and proportionally changed the transmission and reception speeds of individual information streams will be optimal in terms of its maximum throughput under the conditions that are available at this time of day.

However, the prototype device has the following disadvantages:

there is no accounting for the needs of subscribers to change the speed of information transfer under conditions of a dynamically changing load at the input of a communication system;

high energy costs of the communication line, due to the fact that the power of the output signal does not change when the transmission speed (spectrum width) of the group signal changes.

The aim of the invention is to develop a multi-channel digital communication system that allows you to take into account the need of subscribers to change the speed of information transfer and reduce energy costs of the communication line.

This goal is achieved by the fact that in the well-known multi-channel communication system containing at the transmitting end m elements And, a generator, the i-th output of the generator, where i = 1, 2, ..., m, is connected to the first input of the i-th element And , the output of the i-th AND element is connected to the i-th input of the m-input OR element, the output of which is connected to the clock input of the transmitting group unit, the outputs of the clock and loop synchronism of which are connected respectively to the clock and loop inputs of the switching unit, the j-th clock whose output, where j = 1, 2, ..., n, is connected to the input of the jth transmitting individual unit, and the nth clock output of the switching unit is also connected to the clock input of the control signaling unit, the output of which is connected to the information input of the nth transmitting individual unit, the information inputs of the remaining transmitting individual units are the corresponding information inputs of a multi-channel digital radio communication system, the output of the j-th transmitting individual block is connected to the j-th information input of the transmitting group block at the end, a generator, m elements AND, a receiving group unit, the outputs of the clock and loop synchronization of which are connected respectively to the inputs of the clock and loop synchronism of the switching unit, the j-th clock output of which is connected to the clock input of the j-th individual receiver unit, and the n-th the clock output of the switching unit is also connected to the clock input of the control command receiver, the i-th control output of which is connected to the second input of the i-th element And, p additional control outputs of the control command receiver The connections are connected to the corresponding p control inputs of the switching unit, the first input of the i-th AND element is connected to the i-th output of the generator, and the output of the i-th AND element is connected to the i-th input of the m-input OR element, the output of which is connected to the clock input receiving group unit, the j-th information output of which is connected to the information input of the j-th receiving individual block, the information output of the n-th receiving individual block is connected to the information input of the control command receiver, and the information outputs are x receiving information blocks are the corresponding information outputs of a multi-channel digital radio communication system; in addition, a code converter, an incoming load estimation unit, a radiation power control unit, a transmitter, and a common signaling channel unit are introduced at the transmitting end. The input of the common signaling channel unit is connected to the information input of the control signal transmission unit and is the information input of the common signaling channel of a multi-channel digital radio communication system. The output of the common signaling channel unit is connected to the input of the incoming load estimation unit, p control outputs of which are connected to the corresponding p control inputs of the switching unit and p additional information inputs of the control signal transmission unit. An additional control output of the incoming load estimation unit is connected to the input of the radiation power control unit and the input of the code converter, the i-th output of which is connected to the second input of the i-th element I. The output of the radiation power control unit is connected to the control input of the transmitter, the information input of which is connected to information output of the transmitting group block. The output of the transmitter through the transmission path is connected to the information input of the receiving group unit.

Thanks to a new set of features, the subscriber’s need is taken into account for changing the speed of information transfer, under conditions of a dynamically changing load at the input of the communication system, by changing the speed of information transfer in individual channels and group path, and reducing the energy consumption of the communication line by adjusting the radiation power at the output of the transmission path depending on the speed of information transfer in the group path. At the same time, it is possible to establish independently in each individual channel one of 2 ^q possible gradations of the information transfer rate.

The analysis of the prior art made it possible to establish that analogues that are characterized by a set of features identical to all the features of the claimed technical solution are absent, which indicates the compliance of the claimed device with the patentability condition of "novelty". The search results for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the claimed object from the prototype showed that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the impact provided by the essential features of the claimed invention, the transformations on the achievement of the specified technical result. Therefore, the claimed invention meets the condition of patentability "inventive step".

The inventive device is illustrated by drawings, which show:

figure 1 is a structural diagram of a multi-channel digital communication system;

figure 2 is an example implementation of a transmitting group block;

figure 3 is an example implementation of a switching unit;

4 is an example implementation of a transmitting individual unit;

5 is an example implementation of a control command transmission unit;

6 is an example implementation of a unit for assessing the incoming load;

7 is an example implementation of a code converter;

Fig - an example implementation of a receiving group block;

Fig.9 is an example implementation of a receiving individual unit;

10 is an example implementation of a control command receiver.

The inventive multi-channel digital communication system shown in figure 1, contains at the transmitting end a generator 1, elements AND 13 ¹ , ..., 13 ^m , element OR 11, a transmitting group unit 5, a switching unit 3, transmitting individual units 4 ¹ , ..., 4 ⁿ , control signal transmission block 8, code converter 14, incoming load estimation block 15, radiation power control block 17, transmitter 18, common signaling channel block 19, i-th output of generator 1 is connected to the first input of AND element 13 ^i, an output of AND 13 is connected to the ⁱ th entry i-m-e vhodovogo OR 11, the output of the OR element 11 is connected to the clock input of the transmitting group unit 5. The outputs of the clock and cyclic synchronism of the transmitting group unit 5 are connected respectively to the inputs of the clock and cyclic synchronism of the switching unit 3, the j-th clock output of which is connected to the clock input of the transmitting individual unit 4 ^j , and the nth clock output of the switching unit 3 is connected, in addition, to the clock input of the control signal transmission unit 8. The information inputs of the multi-channel digital communication system are information inputs of the transmitting individual blocks 4 ¹ , ..., 4 ^n-1 are provided, and the information input of the transmitting individual block 4 ^{n is} connected to the output of the control signal transmission unit 8. The information input of the common signaling channel (CCS) is the information input of the control signal transmission unit 8, which is additionally connected to the input of the common signaling channel unit 19. The output of the common signaling channel unit 19 is connected to the input of the incoming load estimation unit 15, the p control outputs of which are connected to the p control inputs ladies switching unit 3 and the p data inputs of an additional control signal transmission unit 8. Additional output incoming load estimation unit 15 is connected to the input of the power control unit 17 and the radiation entry code converter 14, i-th control output of which is connected to a second input of AND gate 13 ⁱ . The output of the radiation power control unit 17 is connected to the control input of the transmitter 18, the input of which is connected to the information output of the transmitting group unit 5. The output of the transmitter 18 is connected through the transmission path to the input of the receiving group unit 6.

On the receiving side, it contains a generator 2, elements AND 16 ⁱ , ..., 16 ^m , an OR element 12, a receiving group unit 6, a switching unit 10, individual receiving blocks 7 ¹ , ..., 7 ⁿ , a control command receiver 9. The outputs of the clock and cycle synchronization of the receiving group unit 6 are connected respectively to the inputs of the clock and cycle synchronism of the switching unit 10, the j-th clock output of which is connected to the clock input of the receiving individual unit 7 ^j , and the n-th clock output of the switching unit 10 is additionally connected to the clock receive input ka control commands 9, the i-th control output of which is connected to the second input of the And 16 ⁱ element, and p additional control outputs of the receiver of the control commands 9 are connected to p control inputs of the switching unit 10. The first input of the And 16 ⁱ element is connected to the i-th output generator 2, and the output of the element And 16 ^{i is} connected to the i-th input of the m-input element OR 12, the output of which is connected to the clock input of the receiving group unit. The information outputs of the multi-channel digital communication system are the outputs of the receiving individual units 7 ¹ , ..., 7 ^n-1 , and the output of the receiving individual unit 7 "is connected to the information input of the receiver of control commands 9.

Generators 1 and 2 are used to form m sequences of clock pulses that are phase shifted relative to each other. An embodiment of a generator of sequences of rectangular pulses that are phase-shifted relative to each other is known and described, for example, in / 5, p. 176, Fig. 3.81 /.

The elements And 13 ¹ , ..., 13 ^m , and 16 ¹ , ..., 16 ^m are used to pass clock pulses from the outputs of the generators 1 and 2, connected to the first inputs of the elements And, when applying to the second inputs of the "allowing" control signal. A variant of the implementation of the And element is known and described, for example, in / 5, p. 278, Fig. 5.11 /.

The OR elements 11 and 12 serve to combine the signals from the outputs of the elements AND 13 ¹ , ..., 13 ^m , and 16 ¹ , ..., 16 ^m, respectively. At the output of the OR elements 11 and 12, a clock sequence is formed corresponding to the set transmission speed in the group path. A variant of the implementation of the OR element is known and described, for example, in / 5, p. 297, Fig. 5.31, p. 298, Fig. 5.32 /.

The transmitting group unit 5 serves to combine the signals from the transmitting individual units 4 ¹ , ..., 4 ⁿ , form a group signal, convert it (modulate) to a form convenient for transmission in a specific guide medium (cable, microwave, satellite, etc.). d.). An implementation option of the transmitting group block 5 is presented in figure 2. The transmitting group unit 5 consists of a shaper of a clock signal 5.1, an electronic key 5.2, a combining circuit 5.3, a modulator 5.4 and a shaper of a synchronous synchronization signal 5.5. Moreover, the output of the n + 1-input combining circuit 5.3 is connected to the input of the modulator 5.4. The control output of the shaper of the clock signal 5.1 is connected to the control input of the electronic key 5.2 and the input of the shaper of the signal cyclic synchronism 5.5. The information output of the shaper 5.1 is connected to the n + 1 input of the combining circuit 5.3, and the j-th input of the combining circuit 5.3 is the j-th information input of the transmitting group unit 5. The input of the shaper 5.1 is connected to the input of the electronic key 5.2 and is the clock input of the transmitting group block 5. The output of the modulator 5.4 is the information output of the transmitting group block 5. The output of the driver of the cyclic synchronism signal 5.5 is the output of the signal of the cyclic synchronism, and the output of the electronic key 5.2 - the output signal of the clock synchronism of the transmitting group unit 5.

The clock generator 5.1 is used to generate and add a deterministic clock signal to a group signal, as well as to generate a “Ban” signal for the duration of the clock signal transmission in the transmission cycle. An implementation option of the clock driver is known and described, for example, in / 7, p. 21, Fig. 1.5 /.

The electronic key 5.2 is used to prohibit the transmission of clock pulses to the output of the transmitting group unit 5 during the transmission of the clock signal. An embodiment of the electronic key is known and described, for example, in / 5, p. 462, Fig. 6.54 /.

Combination scheme 5.3 is used to combine information signals from transmitting individual blocks 4 ¹ , ..., 4 ⁿ and the clock signal into a group signal. An n + 1 input OR element can be used as a join scheme. A variant of the implementation of the OR element is known and described, for example, in / 5, p. 297, Fig. 5.31, p. 298, Fig. 5.32 /.

Modulator 5.4 is used to convert a sequence of group signal pulses arriving at the signal input of the modulator from the output of the combining circuit 5.3 to a form convenient for transmission in a specific guiding medium (cable, radio relay, satellite, etc.). In this case, various modulation methods (amplitude, frequency, phase or pulse) can be used, which is not fundamental for the inventive device. An example of a modulator implementation is known and described, for example, in / 6, pp. 273-274, Fig. 11.3 and Fig. 11.4 and in 3 p. 37, Fig. 2.1 /.

The cyclic synchronism signal generator 5.5 is used to generate a short pulse at the time when the transmission of the clock signal in the transmission cycle ends. This signal is intended for cyclic synchronization of the transmitting part. The driver of the signal of cyclic synchronism is a short pulse generator, which is triggered by the rise or fall of the control signal. An example of the implementation of a short pulse generator is known and described, for example, in / 8, p. 211, Fig. 7.5c /.

The switching unit 3 (10) is used to distribute the sequence of clock pulses between the inputs of the transmitting individual units 4 ¹ , ..., 4 ⁿ (receiving individual units 7 ¹ , ..., 7 ⁿ ,) depending on the control information from the incoming evaluation unit load 15 (receiver control commands 9). An embodiment of the switching unit 3 (10) is shown in FIG. 3. Switching unit 3 consists of RS-triggers 3.1 ¹ , ..., 3.1 ⁿ binary counters with synchronous data loading 3.2 ¹ , ..., 3.2 ⁿ , electronic keys 3.3 ¹ , ..., 3.3 ⁿ . Moreover, the output of the RS flip-flop 3.1 ^{j is} connected to the input E (count resolution) of the binary counter with synchronous data loading 3.2 ^j . The output of the binary counter with synchronous data loading 3.2 ^{j is} connected to the control input of the electronic key 3.3 ^j , the S-input of the RS-trigger 3.1 ^{j + 1} and the R-input of the RS-trigger 3.1 ^j . The output of the electronic key 3.3 ^j is the jth clock output of the switching block 3. The input L (control of synchronous data loading) of binary counters with synchronous data loading 3.2 ¹ , ..., 3.2 ^{n is} connected to the S-input of the RS-trigger and is the input of the cyclic of synchronism f _{C of the} switching unit 3. Input C (counting) of binary counters with synchronous data loading 3.2 ¹ , ..., 3.2 ^{n is} connected to the information input of electronic keys 3.3 ¹ , ..., 3.3 ⁿ and is a clock synchronization input f _{T of} switching block 3.

Inputs D ₁ , D ₂ , ..., D _q (data in binary code for synchronous loading - beginning of counting) of a binary counter with synchronous data loading 3.2 ^{j are} connected to the k-th control inputs of switching block 3, where k = 1, 2 , ..., p, p = n · q is the number of control inputs of the switching unit 3, 2 ^q is the possible number of gradations of the transmission speed in an individual channel.

The RS-trigger 3.1 ^j serves to generate a “count resolution” signal for a binary counter with synchronous data loading 3.2 ^j . An example of the implementation of an RS-trigger is known and described, for example, in / 5, p. 337, Fig. 5.74 /.

A binary counter with synchronous data loading 3.2 ^j serves to form a control pulse of variable duration. The duration of the control pulse depends on the binary code recorded in the counter at the inputs D ₁ , D ₂ , ..., D _q . An example of the implementation of a binary counter with synchronous data loading is known and described, for example, in / 5, p. 638, Fig. 7.46 /.

An electronic key 3.3 ^j serves to form a burst of pulses on the jth clock output of the switching block 3, which are a clock signal for the transmitting individual block 4 ^j . An embodiment of the electronic key is known and described, for example, in / 5, p. 462, Fig. 6.54 /.

The transmitting individual unit 4 ^j serves to record the input signal of the individual channel in the storage device under the control of the clock pulses of the input signal and reading it under the control of the clock pulses from the output of the switching unit 3.

An implementation option of the transmitting individual unit 4 ^j is presented in figure 4. The scheme of the transmitting individual unit is known and described, for example, in / 1, p. 87, Fig. 3.24 / (in this book this block is called the transmitting unit of synchronous pairing).

The control signal transmission unit 8 serves to combine the signal of the common signaling channel with the service control signal of the multi-channel digital communication system and transform it into a form convenient for transmission.

An embodiment of a control signal transmission unit 8 is shown in FIG. 5. The control signal transmission unit 8 consists of a bus transceiver with a memory register 8.1 and a shift register with parallel data recording 8.2. The information outputs of the bus transceiver with a memory register 8.1 are connected to the first group of inputs of the shift register with parallel writing of data 8.2, the second group of inputs of which is p additional information inputs of the block for transmitting control signals 8. The clock input of the shift register with parallel writing of data 8.2 is the clock input of the transmission block control signals 8. The information input of the bus transceiver with memory register 8.1 is the information input of the control signal transmission unit 8. Output The shift register with parallel data recording 8.2 is the output of the control signal transmission unit 8.

A bus transceiver with a memory register 8.1 serves to receive information from a common signaling channel and store it temporarily before being transmitted over the service (n-th) channel of a multi-channel digital communication system. An embodiment of a bus transceiver with a memory register is known and described, for example, in / 5, p. 377, Fig. 5.105-5.109 /.

The shift register with the parallel recording of data 8.2 serves to transmit ACS data and control information from the incoming load estimation block 15 via the serial service (nth) channel of the multichannel digital communication system. An embodiment of the shift register with parallel data recording is known and described, for example, in / 9, p. 264, 266 and 5, p. 605, Fig. 7.15 /.

The incoming load estimation block 15 serves to generate control signals for setting the value of the information transfer speed separately to each individual channel, as well as the value of the transmission speed of a group signal of a multi-channel digital communication system, depending on the needs of subscribers.

An embodiment of the incoming load estimation unit is shown in FIG. 6. The incoming load estimation unit 15 consists of a bus transceiver with a memory register 15.1, a read-only memory device 15.2 and a bus transceiver with a shift register 15.3. The outputs of the bus transceiver with memory register 15.1 are connected to the address inputs of the read-only memory device 15.2, the outputs of which are the p control outputs of the incoming load estimation unit 15. The additional outputs of the read-only memory device 15.2 are connected to the inputs of the bus transceiver with a shift register 15.3, the output of which is an additional control the output of the incoming load estimator 15. The input of the bus transceiver with the memory register 15.1 is the input of the estimator load 15.

The bus transceiver with a memory register 15.1 serves to receive information from the block of the common signaling channel 19, store it temporarily and generate an address signal for the permanent storage device 15.2 on its basis. An embodiment of a bus transceiver with a memory register is known and described, for example, in / 5, p. 377, Fig. 5.105-5.109 /.

The read-only memory device 15.2 is intended for storing control information in the form of instruction codes. At the same time, information for controlling the operation of the switching unit 3 (setting the transmission rate in individual channels) is recorded in the initial r-bit of the command, and the rest of the command is information about the value of the group information transfer rate. An implementation option for read-only memory is known and described, for example, in / 9, p. 303, 304 /.

The bus transceiver with a shift register 15.3 is used to transmit in a serial code commands with the value of the group information rate. An embodiment of a bus transceiver with a shift register is known and described, for example, in / 5, p. 386, Fig. 5.111 /.

Code converter 14 is used to convert the command code with the value of the group information transfer rate into the control code of the elements And 13 ¹ , ..., 13 ^m .

An embodiment of the code converter 14 is shown in FIG. 7. The code converter consists of a bus transceiver with a memory register 14.1 and a read-only memory device 14.2. The outputs of the bus transceiver with a memory register 14.1 are connected to the address inputs of the read-only memory device 14.2, the i-th output of which is the i-th output of the code converter 14. The input of the bus transceiver with the memory register 14.1 is the input of the code converter 14.

A bus transceiver with a memory register 14.1 serves to receive in a serial code a command with the value of the group information transfer rate, its temporary storage and the formation of an address signal on its basis for read-only memory 14.2. An embodiment of a bus transceiver with a memory register is known and described, for example, in / 5, p. 377, Fig. 5.105-5.109 /.

The read-only memory device 14.2 is intended for storing control information in the form of instruction codes. In this case, for a specific value of the group information transfer rate, such a command is selected for the elements AND 13 ¹ , ..., 13 ^m to ensure the output of the OR element 11 of the clock sequence corresponding to the set transmission speed in the group path. An implementation option for read-only memory is known and described, for example, in / 9, p. 303, 304 /.

The radiation power control unit 17 is used to calculate the required transmitter power in accordance with the value of the information transfer rate in the group path. An embodiment of the radiation power control unit is known and described in / 10, Fig. 3 block 8 /.

The transmitter 18 serves to amplify the signal to a value necessary to compensate for losses in the propagation medium. This ensures a change in the carrier radiation power, depending on the information transfer rate in the group path, by commands from the radiation power control unit 17. An embodiment of the transmitter is known and described, for example, in / 10, Fig. 3 block 4 /.

The block of the common signaling channel 19 serves to extract from the common signaling channel information about calls and requirements for the bandwidth of individual channels. The common signaling channel block is a well-known CCS module, the implementation of which is known and described, for example, in / 12, p. 92, fig. 3.1 a and 13 p. 202, fig. 1.119 /.

The receiving group unit 6 is designed to restore the original sequence of pulses of the group signal and the allocation of the cyclic clock signal. An embodiment of a receiving group block 6 is shown in FIG. The receiving group unit consists of a demodulator 6.1, a clock receiver 6.2 and a buffer driver 6.3. The output of the demodulator 6.1 is connected to the information input of the clock receiver 6.2 and the input of the shaper 6.3, the j-th output of which is the j-th information output of the receiving group block 6. The output of the clock signal 6.2 is the output of the clock signal of the receiving group block 6. Information input of the demodulator 6.1 is the information input of the receiving group block 6. The clock input of the demodulator 6.1 is connected to the clock input of the clock receiver 6.2 and is the clock input and output of the receiver group unit 6.

Demodulator 6.1 serves to restore the pulse train of a group signal from a received modulated carrier wave.

The demodulator implementation option is known and described, for example / 3, p. 46 fig. 2.7 and 6, p. 274, fig. 11.4 /.

The clock receiver 6.2 serves to detect the temporary position of the cyclic clock signal in the group signal and generate a short pulse at the time when the clock signal ends in the transmission cycle. This signal is designed to synchronize the cycles of the receiving part. An embodiment of a clock receiver is known and described, for example, in / 11 and 7, p. 41, Fig. 2.8 and 2.9 /.

The buffer driver 6.3 serves for branching the group signal from the output of the demodulator 6.1 into n information outputs. An embodiment of the buffer driver is known and described, for example, in / 9, p. 48, 59, 75 and 76 /.

The receiving individual unit 7 ^{j is} designed to extract information from the group signal of the jth channel under the control of the clock signal from the jth output of the switching unit 10.

An implementation option of the receiving individual unit 7 ^j is presented in Fig.9. The scheme of the receiving individual unit is known and described, for example, in / 1, p. 87, Fig. 3.24 / (in this book, this unit is called the synchronous pairing receiving unit).

The receiver of control commands 9 is used to receive a control command code and generate control signals in accordance with it to set the value of the information transfer speed separately in each individual channel, as well as a control code for elements And 16 ¹ , ..., 16 ^m in accordance with the speed value group signal transmission of a multi-channel digital communication system.

An embodiment of a control command receiver 9 is shown in FIG. 10. The receiver of control commands consists of a shift register 9.1, an adder of binary numbers 9.2 and read-only memory 9.3. The outputs of the shift register 9.1 are connected to the inputs of the adder of binary numbers 9.2 and are p additional control outputs of the receiver of control commands 9. The outputs of the adder of binary numbers 9.2 are connected to the address inputs of read-only memory 9.3, the i-th output of which is the i-th control output of the control command receiver 9. The information and clock inputs of the shift register 9.1 are respectively the information and clock inputs of the receiver of control commands 9.

The shift register 9.1 is used to convert the serial code of the control command received from the output of the receiving individual unit 7 ^j in parallel. An embodiment of the shift register is known and described, for example, in / 9, p. 155, 262, 325 /.

The adder of binary numbers 9.2 is used to add n q-bit binary numbers (j-oe q-bit number is the value of the information rate in the j-th individual channel). At the output of the adder binary numbers 9.2 in binary code will be the value of the transmission speed of the group signal, which is the address code for read-only memory device 9.3. An implementation option for the binary adder is known and described, for example, in / 5, p. 537, Fig. 6.111 and 9, p. 140, 293 /.

Read Only Memory 9.3. completely similar to read only memory device 14.2.

The inventive device operates as follows.

In the initial state, the instruction codes for controlling the operation of the switching unit 3 and the corresponding information about the value of the transmission speed in the group path are recorded in the read-only memory 15.2. In read-only memory devices 14.2 and 9.3, codes of the control commands for the elements And 13 ¹ , ..., 13 ^m , 16 ¹ , ..., 16 ^m, respectively, are recorded.

The exchange of command codes occurs over time upon receipt of a call signaling from a subscriber on a common channel, indicating the required bandwidth of the individual channel. Depending on the needs of subscribers, the following are installed:

- one of 2 ^q possible gradations of information transfer rate individually in each information channel;

- the transmission rate of information in the group path, as the sum of the transmission speeds in the individual n-1 information channels, the transmission speed in the service n-th channel and the transmission speed of the clock signal;

- the minimum required radiation power of the transmitter, allowing to provide the required quality of information transmission over the communication line.

Depending on the current point in time, the last operation of the reconstruction of a multi-channel digital communication system is as follows.

Upon receipt of a call from the subscriber via the common signaling channel indicating the required information rate in the individual channel, the corresponding command will be generated at the output of the common signaling channel block 19, which will be sent to the incoming load estimation unit 15. In this case, the code will be read from the permanent storage device 15.2 the new command, the initial p bits which are transmitted on p outputs a switching control unit 3 and via the signal transmission unit 8, a transmitting unit 4 seperate ^n, group pAKT, individual receiving unit 7 ⁿ are transmitted to the receiver control commands 9. p additional control receiver outputs control commands 9 active command code is transmitted to the switching unit 10. In addition, a further control output of the evaluation unit entering load 15 is formed in the sequential code rate value information transfer in the group path. Based on this code, a command to control the elements AND 13 ¹ , ..., 13 ^m is generated at the m outputs of the code converter 14. A similar command is generated at m control outputs of the receiver of control commands 9 - for elements And 16 ¹ , ..., 16 ^m . If unit potentials arrive at the second inputs of some elements AND 13 ¹ , ..., 13 ^m , (16 ¹ , ..., 16 ^m ), then these AND elements open and pass certain clock elements through themselves and OR 11 (12) sequences from specific outputs of generators 1 (2) (sequences are out-of-phase with respect to each other). Thus, at the output of the OR elements 11 (12), a clock sequence is formed with the required pulse repetition rate equal to the information transfer rate in the group path.

In accordance with the submitted control command, the switching unit 3 (10) generates such a packet of clock pulses at the jth output to provide the required information transfer rate in the jth individual channel.

In addition, based on the code with the value of the information transfer rate in the group path in the radiation power control unit 17, a command is generated to establish the minimum required signal power at the output of the transmitter 18.

The sequence of digital information signals are fed through the connecting lines to the information inputs of the transmitting individual units 4 ¹ , ..., 4 ^n-1 , and the signal of the common signaling channel is sent to the information input of the transmitting individual unit 4 ⁿ . In the transmitting group unit 5, the signals of the individual channels are temporarily combined, the cyclic synchronism signal is input and converted to a form convenient for transmission in a particular guide medium. The generated group signal is amplified by the transmitter and transmitted through the communication line to the receiving group block 6. The receiving group block provides demodulation of the group signal and extracts the clock signal from it. The individual individual blocks 7 ¹ , ..., 7 ^n-1 extract the sequences of digital information signals from the group signal and transfer them to the output of a multi-channel digital communication system.

The positive effect of the use of the claimed device will demonstrate the following example.

Let at a certain point in time t ₀ along r (where r <n) information channels carry information from subscribers. Moreover, in each j-th "active" individual channel, one of the 2 ^q possible information transfer rates declared by the subscriber, V _{j, is} set by the subscriber. In the remaining nr individual channels, the transmission rate is Vj = 0. Group Link Transfer Rate:

where V _si is the transmission rate of service information (service n-th channel information and a clock signal).

The output of the transmitter sets the signal power proportional to VΣ.

Thus, the bandwidth of the communication line is used only for the transmission of useful information from active subscribers and provides a reduction in energy costs on the communication line.

LITERATURE

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3. V.L. Banquet, V. M. Dorofeev. Digital methods in satellite communications. - M.: Radio and Communications, 1988 .-- 240 p.

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5. G.I. Pukhalsky, T.Ya. Novoseltseva. Digital devices: Textbook for technical colleges. - St. Petersburg: Polytechnic, 1996. - 885 p.

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Claims (1)

A multi-channel digital communication system, including at the transmitting end m elements And, a generator, the i-th output of the generator, where i = 1, 2, ..., m, is connected to the first input of the i-th element And, the output of the i-th element And connected to the i-th input of the m-input OR element, the output of which is connected to the clock input of the transmitting group unit, the clock and loop outputs of which are connected respectively to the clock and loop inputs of the switching unit, the j-th clock output of which, where j = 1 , 2, ..., n, is connected to the input of the jth transmitting individual of the nth unit, and the nth clock output of the switching unit is also connected to the clock input of the control signal transmission unit, the output of which is connected to the information input of the nth transmitting individual unit, the information inputs of the remaining transmitting individual units are the corresponding information inputs of the multi-channel digital system connection, the output of the j-th transmitting individual block is connected to the j-th information input of the transmitting group block, at the receiving end a generator, m elements And, receiving a group block, the clock and loop synchronization outputs of which are connected respectively to the clock and loop synchronization inputs of the switching block, the j-th clock output of which is connected to the clock input of the j-th individual receiver block, and the n-th clock output of the switching block is also connected to the clock input of the control command receiver, the i-th control output of which is connected to the second input of the i-th element And, p additional control outputs of the control command receiver are connected to the corresponding p control To the switching inputs, the first input of the i-th AND element is connected to the i-th output of the generator, and the output of the i-th AND element is connected to the i-th input of the m-input OR element, the output of which is connected to the clock input of the receiving group block, j the information output of which is connected to the information input of the j-th receiving individual block, the information output of the n-th receiving individual block is connected to the information input of the control command receiver, and the information outputs of the remaining receiving information blocks are corresponding information outputs of a multi-channel digital communication system, characterized in that an additional code converter, an incoming load estimation unit, a radiation power control unit, a transmitter and a common signaling channel unit, the input of which is connected to the information input of the control signal transmission unit, are additionally introduced at the transmitting end the input of the common signaling channel of a multi-channel digital communication system, the output of the common signaling channel unit is connected to the input of the evaluation unit and the incoming load, the p control outputs of which are connected to the corresponding p control inputs of the switching unit and p additional information inputs of the control signal transmission unit, and the additional control output of the incoming load estimation unit is connected to the input of the radiation power control unit and the input of the code converter, i-th output which is connected to the second input of the i-th element AND, the output of the radiation power control unit is connected to the control input of the transmitter, the information input of which dklyuchen to the data output of the transmitting unit group, and the transmitter output via the transmission path connected to the data input of the receiving unit group.

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