RU21260U1 - SIGNAL TRANSMISSION AND RECEIVING SYSTEM ON THE COMMUNICATION CHANNEL - Google Patents

Abstract

A system for transmitting and receiving signals over a communication channel, consisting of two similar devices, the first of which is located on one side of the communication channel, and the second on the other side, and each of which contains a transmitter, one input of which is connected to the analog channel output, having power inputs, telephone, telephone automation and a high-frequency output, a receiver with a high-frequency input, power input, telephone, telephone automation and analog outputs, the last of which is connected to the analog channel input, a telephone interface unit with a telephone input, telephone automation input and corresponding outputs , equipped with a bidirectional telephone junction and a power input, a high-frequency interface unit with a high-frequency input and a high-frequency output, a power input, equipped with a bidirectional high-frequency junction, a power supply with an input and an output, and the high-frequency output of the transmitter is connected to the corresponding input of the high-frequency interface unit ds, and the high-frequency output of the latter - with the high-frequency input of the receiver, the telephone input and the input of the telephone automation of the transmitter are connected respectively to the telephone output and the output of the telephone automation of the telephone interface unit, the telephone input and the telephone automation output of the telephone interface unit are connected, respectively, to the telephone output and the telephone automation output receiver, the telephone interface of the telephone interface unit is connected to the telephone channel, the high-frequency joint of the high-frequency interface unit is connected to the high-frequency channel, the output of the power supply unit is connected to the input�

Description

A system for transmitting and receiving signals over a communication channel.

The utility model relates to the field of electric power and can be used to organize high-frequency (HF) channels for combined transmission of telephone signals, telemechanics, emergency control commands and relay protection.

Known systems for transmitting and receiving signals through the HF communication channels of power lines (power lines), operating according to the general principle: the transmitter converts the input low-frequency analog and discrete signals from information sources (telephone channel, telemechanics devices) into an HF signal, which is through a separation signal the device enters the communication channel; the receiver receives the RF signal from the channel, detects it, and converts it back to the low-frequency region, separates the original telephone signals and telemechanics signals and distributes them to the consumers of information.

A known system for transmitting and receiving signals through power lines, consisting of two similar devices ABC-1, each of which contains a transmitter, a receiver, a telephone interface unit, an RF interface unit, and is capable of bi-directional transmission of one speech signal and one telemechanics signal via a communication channel. (High-frequency communication equipment single-channel AVS-1. Technical description and operating instructions. ATG 2.133.039 TO).

The main disadvantages of the prototype are the instability of the main parameters, the complexity of their adjustment, the limited set of transmitted signals, the lack of the ability to carry out automated control of the communication channel and the device as a whole.

The disadvantages are mainly due to the fact that the signal processing in the transmitter and receiver is performed on analog elements (filters, modulators, demodulators).

The technical task of the utility model is to improve the characteristics of the device, as well as giving it new qualities, such as the ability to transmit and receive on the same RF channel simultaneously signals for various purposes (speech, discrete, automation commands and relay protection), the ability to quickly change operating parameters (carrier frequencies , transmission speed, number of discrete data channels, etc.), automated control of communication channel parameters.

This problem is solved in that in a known system consisting of two similar devices, the first of which is located on one side of the communication channel, and the second on its other side, and each of which contains a transmitter 1, one input of which is connected to the output of the analog channel having inputs

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power supply, telephone, telephone automation and high-frequency (HF) output, receiver 2 with RF input, power input, telephone, telephone automation and analog outputs, the last of which is connected to the analog channel input, telephone interface unit 3 with telephone input, telephone automation input and corresponding outputs, equipped with a bi-directional telephone interface and a power input, an RF interface unit 4 with an RF input and an RF output, a power input equipped with a bi-directional RF interface, a power supply 5 with an input and output, wherein The output of the transmitter is connected to the corresponding input of the RF interface unit, and the RF output of the latter is connected to the RF input of the receiver, the telephone input and the telephone automation input of the transmitter are connected respectively to the telephone output and the telephone automation output of the telephone interface unit, the telephone input and the telephone automation input of the telephone interface unit connected respectively to the telephone output and the telephone automation output of the receiver, the telephone interface of the telephone interface unit is connected to the telephone channel, the RF interface is As the RF interface is connected to the RF channel, the output of the power supply unit is connected to the power inputs of the transmitter, receiver, telephone interface unit and RF interface unit, the RF interface of the device located on one side of the channel is connected to the RF interface of the device located on its other side, one a pair consisting of a transmitter on one side and a receiver on the other side of the communication channel, and accordingly a second similar pair, are tuned to different carrier frequencies, in addition, a control unit having N + 1 in odes and outputs of the first group, according to S inputs and outputs of the second and third groups, the input and output of the differential system control (DS). bidirectional joint, power input, additional M, P, Q and R outputs and inputs of analog, digital channels, automation and relay protection commands respectively, as well as a control channel joint and N bi-directional telephone joints, the transmitter is equipped with additional M, P, Q, R , S, N and N inputs respectively of the first, second, third, fourth, fifth, sixth and seventh groups, the receiver has corresponding outputs of the same groups, the transmitter also has additional S outputs, the receiver has S inputs, and the telephone interface unit is equipped with additional N in passages and N inputs of the first and second groups, respectively, N + 1 outputs and N + 1 inputs of the third group and N bidirectional joints, the RF interface unit is equipped with a control input and output, with P outputs of digital channels connected to P inputs of the second group of the transmitter, Q outputs automation commands with Q inputs of the third transmitter group, R relay protection outputs with R inputs of the fourth transmitter group, R relay protection inputs with R outputs of the fourth receiver group, Q inputs of automation commands with Q inputs of the third receiver group, P

the inputs of the digital channels are connected to the P outputs of the second group of the receiver, S inputs of the fifth, N inputs of the sixth and N inputs of the seventh group of the transmitter, respectively, are connected to the S outputs of the second group of the control unit. N outputs of the second and N outputs of the first group of the telephone interface unit, and S outputs of the transmitter are connected to S inputs of the second group of the control unit, S outputs of the fifth, N outputs of the sixth and N outputs of the seventh group of the receiver are respectively connected to S inputs of the third group of the control unit, N inputs the second and N inputs of the first group of the telephone interface unit, and S inputs of the receiver are connected to the S outputs of the third group of the control unit, N + 1 outputs of the third group of the telephone unit are connected to N + 1 inputs of the first group of the control unit, and N + 1 outputs the first group of the control unit are connected to the N + 1 inputs of the third group of the telephone interface unit, the junction of the control channel is connected to the bi-directional junction of the control unit, the M outputs of the analog channels are connected to the M inputs of the first group of the transmitter. M inputs of these channels are connected to M outputs of the first group of the receiver. N bidirectional telephone joints are connected to N bi-directional joints of the telephone interface unit, the power input of the control unit is connected to the output of the power unit, the control input of the RF interface unit is connected to the control output of the control unit DC, the control output of the RF interface unit is connected to the control input of the control unit, where N, M, P, Q. R, S - the number of telephone channels, analog channels, digital channels, automation commands, relay protection, control signals, respectively, and all the above blocks are made on digital solvers.

The figure shows a block diagram of the claimed utility model, where each of their devices consists of a transmitter 1, a receiver 2, a telephone interface unit 3, an RF interface unit 4, a control unit 5, a power supply 6. The transmitter 1 o receives signals from various information sources (dedicated analog channels, digital low-speed and high-speed digital data transmission channels, emergency control and relay protection commands) and telephone interface unit 3 and performs their conversion (modulation) into an RF signal, which ory is transmitted to the opposite side. Receiver 2 Receiver 2 performs the inverse transformation (demodulation) of the RF signal coming from the opposite side, the detection of primary signals and their delivery to consumers of information. The telephone interface unit converts a two-wire telephone termination into a four-wire and vice versa, also converts telephone call, end, dialing signals from the telephone line into the corresponding logical signals, and logical signals corresponding to the call, end, dialing signals into the corresponding telephone signals . The RF interface unit contains a differential system

and performs the separation of the signal from the transmitter to the RF cable and the signal from the RF channel to the receiver. The difference from the existing circuit solutions - it is possible to carry out an automated balance of the differential system. The control unit communicates the decisive devices of the transmitter and receiver, as well as the telephone and high-frequency interface units with an external control device (computer), which is necessary for setting the device parameters, monitoring its operation and monitoring the communication channel. The power supply provides power to the device. Its input is connected to an external power source, the output to the power inputs of the respective units.

The fundamental difference from the prototype is that the operations for generating an RF signal (modulation) in transmitter 1 and demodulation in receiver 2 are not performed on the analog signal itself, which exists continuously in time, but on its mathematical representation by a sequence of discrete quantized reports. In this case, the conversion method is implemented in the form of the program of work of the corresponding decisive device. Application of decisive devices (in the form

microprocessor, programmable logic gate array, digital discrete logic) in the transmitter and receiver provides higher quality and more stable signal processing parameters compared to the prototype.

The system operates as follows.

The duplex communication channel over the HF channel is organized by two similar devices: for clarity, we call device A (side A) and device B (side B), and, as mentioned above, the transmitter of device A and the receiver of device B are tuned to the same carrier frequency, and the transmitter of the device B and the receiver of device A to another.

N inputs of the telephone interface unit 3 of device A are connected to N telephone communication channels. Moreover, external connections can be both from the side of the subscriber (telephone set), and from the telephone exchange. The telephone interface unit 3, made using decisive devices, converts the bi-directional input telephone signal of each of the N channels into unidirectional and vice versa. Moreover, the telephone signal is divided into tonal and logical (with an outgoing connection), and vice versa, their combination (with an incoming connection). The tone signal corresponds to the transmission of speech and auxiliary audio information (call control, end tone, dial tone), logical - line status (key closure / open, dialing pulses, call signals).

the transmitter 1 (side A), through its respective inputs, receives signals: N tone and N logical from the outputs of the telephone interface, M analog from the outputs of the analog communication channels, P digital from the outputs of the digital communication channels, Q emergency control commands and R relay commands protection. The transmitter transmitter, operating with sequences of digital samples corresponding to the mentioned input signals, according to a given program, converts the original sequences of digital samples into the resulting sequence of digital samples corresponding to a group RF signal having certain specified parameters (carrier frequency, width of the frequency band, etc.) .

The RF signal from the transmitter of device A, through the RF interface unit 4, enters the communication channel, and, propagating in it, reaches the receiver of device B, also arriving parasitically to the receiver of device A. At the same time, the RF signal from the transmitter of the device is sent to the RF interface unit from the communication channel B. The RF interface unit 4 of device A separates the output and input RF signals by a known method of separating two multidirectional signals using a differential separation system (differential system). In this case, the differential system of device A should ensure the transmission of the RF signal from its transmitter towards the communication channel and prevent it from passing in the direction to the receiver of the device, and, conversely, ensure the transmission of the signal from the transmitter of device B to the receiver of device A and prevent its passage towards the transmitter of the device A. Unlike similar devices of the RF interface, the differential system is tuned to the parameters of the RF channel (by the minimum value of the leaky spurious signal of the own transmitter ) can be done in an automated way through the control unit 5.

The differential system of the RF interface unit in device B works similarly.

The RF signal in device A, which came through the communication channel from the transmitter of device B, is demodulated in receiver 2. The broadcasting device of receiver 2 according to a given program, operating with a sequence of digital samples corresponding to the input RF signal, generates other sequences of samples corresponding to output signals from this sequence : N tone and N logical telephone interface, M analog, P digital, Q automation commands and R relay protection commands. In this case, the output signals of the receiver 2 of the device A completely correspond to the signals of the same name received at the input of the transmitter B.

The analog and logical signals of the telephone interface of the receiver 2 are received in the telephone interface unit, where they are converted into a telephone signal, which enters the telephone communication channel.

The control unit carries out continuous monitoring of the functioning of all units of the device, exchanging information with an external control device (for example, a computer), allows you to quickly change the device parameters (carrier frequencies, the number and type of transmitted signals, etc.) and conduct automated monitoring of the communication channel. Interacting with the transmitter of device A, the control unit allows you to change its parameters, as well as transmit the remote control signals of device B and signals for measuring the parameters of the RF channel in the direction A-B and B-A to the communication channel.

According to the above scheme, the transmitter 1, receiver 2, the telephone interface unit 3, and the RF interface unit 4 of device B operate.

Thus, the input signals of the transmitter 1 of device A fully correspond to the output signals of the receiver 2 of device B, and vice versa, and two devices A and B, operating in the described manner, realize a duplex communication channel.

Claims (1)

A system for transmitting and receiving signals over a communication channel, consisting of two similar devices, the first of which is on one side of the communication channel, and the second on its other side, and each of which contains a transmitter, one input of which is connected to the output of the analog channel, having power inputs, telephone, telephone automation and high-frequency output, a receiver with a high-frequency input, power input, telephone, telephone automation and analog outputs, the last of which is connected to the input of the analog channel, unit telephone interface with telephone input, telephone automation input and corresponding outputs, equipped with a bi-directional telephone line and power input, a high-frequency interface unit with a high-frequency input and high-frequency output, power input, equipped with a bi-directional high-frequency interface, a power supply with input and output, and a high-frequency output of the transmitter connected to the corresponding input of the high-frequency interface unit, and the high-frequency output of the latter is connected to the high-frequency input of the receiver, t the telephone input and the telephone automation input of the transmitter are connected respectively to the telephone output and the telephone automation output of the telephone interface unit, the telephone input and the telephone automation output of the telephone interface unit are connected respectively to the telephone output and the telephone automation output of the receiver, the telephone interface of the telephone interface unit is connected to the telephone channel, the high-frequency junction of the high-frequency interface unit is connected to the high-frequency channel, the output of the power supply is connected to the input and powering the transmitter, receiver, telephone interface unit and high-frequency interface unit, the high-frequency junction of the device located on one side of the channel is connected to the high-frequency junction of the device located on its other side, one pair consisting of a transmitter of one side and a receiver of the other side of the channel communication, and accordingly the second similar pair is tuned to different frequencies, characterized in that a control unit having N + 1 inputs and outputs of the first group, S input of the second and third groups, the input and output of the differential system control are a bi-directional joint, a power input, additional M, P, Q and R outputs and inputs of analog, digital channels, automation and relay protection commands, as well as a joint of the control channel and N bidirectional telephone connections, the transmitter is equipped with additional M, P, Q, R, S, N and N inputs of the first, second, third, fourth, fifth, sixth and seventh groups, respectively, the receiver has corresponding outputs of the same groups, the transmitter also has additional S outputs c, the receiver has S inputs, and the telephone interface unit is equipped with additional N outputs and N inputs of the first and second groups, N + 1 outputs and N + 1 inputs of the third group and N bi-directional joints, the high-frequency interface unit is equipped with a control input and output, moreover P outputs of digital channels connected to P inputs of the second transmitter group Q outputs of automation commands with Q inputs of the third transmitter group, R relay protection outputs with R inputs of the fourth transmitter group, R relay protection inputs with R outputs of the fourth group receiver, Q inputs of automation commands with Q inputs of the third group of the receiver, P inputs of digital channels are connected to P outputs of the second group of the receiver, S inputs of the fifth, N inputs of the sixth and N inputs of the seventh group of the transmitter are respectively connected to S outputs of the second group of the control unit, N the outputs of the second and N outputs of the first groups of the telephone interface unit, and S outputs of the transmitter are connected to S inputs of the second group of the control unit, S outputs of the fifth, N outputs of the sixth and N outputs of the seventh group of the receiver are respectively connected to S inputs of group of the control unit, N inputs of the second and N inputs of the first group of the telephone interface unit, and S inputs of the receiver are connected to S outputs of the third group of the control unit, N + 1 outputs of the third group of the telephone connection unit with N + 1 inputs of the first group of the control unit, and N + 1 outputs of the first group of the control unit are connected to N + 1 inputs of the third group of the telephone interface unit, the junction of the control channel is connected to the bi-directional junction of the control unit, M outputs of analog channels are connected to M inputs of the first group of the transmitter , M inputs of these channels are connected to M outputs of the first group of the receiver, N bidirectional telephone joints are connected to N bidirectional joints of the telephone interface unit, the power input of the control unit is connected to the output of the power supply, the control input of the high-frequency interface unit is connected to the control output of the differential system of the control unit, the control output of the high-frequency interface unit is connected to the control input of the differential system of the control unit, where N, M, P, Q, R, S is the number of telephones, respectively channel channels, analog channels, digital channels, automation commands, relay protection, control signals, and all of the above blocks are made on digital decision devices.