SU862377A1 - Binary signal receiver - Google Patents

Description

(54) BINARY SIGNAL RECEIVER

Claims (1)

The invention relates to a technique for transmitting discrete data and can be used in a device for transmitting discrete information, using redundant block code in the detection or detection mode and partial error correction and decisive feedback to ensure the required accuracy of the transmitted information. The receiver of binary signals, the contents of the first distributor, two keys, three control units, two memory blocks, a second distributor whose output is connected to the first input of the first element OR a signal conditioner, a receiving unit and a decoder whose output is connected to the input of the first block are known control, which is connected to the signal sensor, while the outputs of the keys are connected to the first inputs of the GO memory blocks. . However, the known receiver does not allow reception of signals over half-duplex communication channels. The purpose of the invention is to provide the possibility of receiving signals over half-duplex communication channels. To do this, a binary receiver containing the first distributor, two KJB04a, three control units, two memory blocks, the second distributor, the output of which is connected to the first input of the first OR element, the signal conditioner, the reception unit and the decoder, the output of which is connected to the input the first control unit, which is connected to the signal sensor, and the output | keys are connected to the first inputs of the memory blocks, three delay elements and a second OR element are introduced, the inputs of which are connected to the first output of the first control unit and the output of the first distributor, to the input of which the output of the first delay element is connected, the inputs of which are connected respectively to the second output of the first control unit and the output of the second delay element, the input of which is connected to the output of the first OR element, the second input of which is connected to the third output of the first control unit. The corresponding output of the first distributor is connected to the first inputs of the keys, the second inputs of which are connected respectively to the outputs of the second control unit and. receiving unit. The output of the second element OR is connected via the third delay element to the input of the second distributor, the corresponding output of which is connected to the second inputs of the memory blocks, the outputs of which are connected respectively to the inputs of the signal conditioner and the third control unit. The drawing shows a structural electrical circuit of the proposed receiver. The binary signal receiver contains a signal sensor 1, a decoder 2, the first, second and third blocks, controls 3, 4.5, respectively, the first and second elements OR 6.7, respectively, the first, second and third delay elements 8.9,10, the driver of the P signals, two keys 12.13, two memory blocks 14.15, the receiving block 16, the first and second distributors 17.18, respectively. The receiver works as follows. Sending and receiving code combinations over half-duplex communication channels is the same as with duplex communication channels, only the time for transmitting information and service commands is provided alternately first in one direction, then in the other, and the mode also changes joining. Communication at the calling station begins with the transmission of the Start command. This command must include a sync sequence and a phased sequence (as well as the address of the called station and its address if the stations operate on the network). The Start operation command forms with in the sensor of signals 1. After the transfer of this command in the first block of control 3, an indication is made of the beginning of the measurement of the delay, which teaches propagation of the signal in the forward and reverse communication channels. At the called station, after receiving the Start command from the output of the decoder 2 to the first control unit 3, a signal is issued to switch the station to transmission mode. Moreover, the signal for switching from the output of the first control unit 3 is output with a delay relative to the input signal equal to the capacity of the switching delay line (although the radio station transmitter may turn on earlier), and the permission to transmit from the sensor output signal 1 of the Start command is close to the clock one. the pulse of the second distributor 18. At the called station, after receiving the Start operation command, the phase will be set according to the pulse and the phase according to the cycle of the distributor 17, as well as in the control unit 3 tmetka the start command frame delays during transmission on the forward and reverse communication channels. If the stations are working. In the network, then the transmitters of other stations of the network, having accepted the Start command with another address, are blocked. At the called station, after receiving the Start operation command, in addition to establishing the phase by pulse and cycle, control unit 3 will determine the time corresponding to the delay of the signal during its transmission over the forward and reverse communication channels. This time will be determined from the total delay determined in the control unit 3 from the moment the transfer of the Start command to the reception of this command is completed by subtracting the switching delay from it and the reception time of the Start command. After receiving the Start command from the output of the decoder 2, a signal is sent to the control unit 3, from which the signal for setting the capacitance of the delay element 8 is output, and then a signal sensor is launched with a delay equal to the capacity of the second delay element to work. At the station, after receiving the Ready for Work command in control unit 3, it is determined and the signal from its output determines the capacitance of the first delay element I, then with a delay determined by the second delay element j the next clock pulse of the second distributor triggers zi team Ready to work. The Ready for operation command contains information about the cycle length of the second distributor depending on whether information from the station will transmit information or only Service Signals Request or Confirmation. Depending on this, the cycle length of the first distributor of the opposite station will be set. After receiving the caller, the Ready to Work command transmits the first packet of the code combinations to the communication channel; (. corresponds to the use of all -intended register memory blocks). After transmission, the packet from (, code combinations, the station switches to receive mode, but the reception permission is issued with a delay relative to the end of the transmission equal to the capacity of all the delay elements. At the calling station, feedback signals are received h, then the calling station again switches to the transmission mode of the next packet from t rAcivtc code combinations.At the same time, in the next packet at the places corresponding to the reception of the Confirmation signal, as well as during transmission over the duplex communication channel, the next the code combination of the corresponding sequence, and at the places corresponding to the reception of the signal, the Request is re-transmitted, the combination of this subsequence transmitted in the previous packet. During the exchange of information during the reception of the next packet, in the memory 14 via the key 12, the data from the output of the control unit 4 on the presence or absence of an HII error in each of the N | laus: with the received code combinations, and in the memory block 15 through the key 13 - data from the output of the receiving unit 16. During transmission, the data of these blocks The bits are alternately read into the signal conditioner 11 and into the control unit 5 for transmission in each subsequence or the following code pattern from the corresponding memory register register or the requested pattern from the repeater .j In duplex mode, the first and second distributors operate continuously and provide alternate code recordings combinations into the corresponding registers of the memory block and alternately combining code combinations from the corresponding registers of another memory block. In half duplex mode, the distributors perform the same functions, but due to the sequential operation, it is necessary to ensure timely start and stop of these distributors. To this end, during the data exchange process, the valves are started alternately from each other, taking into account the launch delays determined by the delay lines between them. The capacity of the second and third delay elements is set such that the delay time of the signal in the line is not less than the maximum possible time of switching the radio station from reception to transmission (or from transmission to reception). In this case, fluctuations in the switching time of the station do not change the phase of the transmitted signal when switching compared to the phase of the signal transmitted before switching. In the event that the delay time of the signal of the second and third delay elements is not a multiple of the transmission duration of the code combination when switching the station from reception to transmission of signal / IOM from the output of the delay line, it is necessary to set the phase of the second distributor, and when switching the station from transmission to reception - phase the first distributor. In this case, the phase shift of the distributors is produced by a previously known constant value, so that both distributors exchanging information of the stations remain in phase. In this way, signals are received over half duplex communication channels. Claims of the invention A binary signal receiver comprising a first valve, two keys, three control units, two memory blocks, a second valve, a smartly connected to the first input