SU944125A2 - Device for autoselection of discrete communication channel - Google Patents

Description

one

The invention relates to radio and can be used in systems with diversity reception of both synchronous and start-stop radio telegraph transmissions.

According to the main author. St. The device for auto-selecting a discrete communication channel is known, containing an antenna switch, the first output of which is connected to the input of the working path, consisting of the serially connected working receiver, the first time distortion analyzer and the distortion counter, and the second output is connected to the input of the measuring path, consisting of consecutive,. connected to the measuring receiver, the second time distortion analyzer, the block of distortion counters, the register block, the comparison block, the memory block and the first switch, the output of the trade is connected to the first control input of the antenna switch, the control unit |, the first, second and third outputs are connected to the control outputs, respectively, of the distortion counter block, the register block and the comparison block, and the fourth output of the control block through the second switch is connected to the second control input of the antenna comm a different output of the second switch is connected to the second input of the memory block il.

However, the known device does not have sufficient noise immunity.

The purpose of the invention is to improve noise immunity.

To achieve the goal in the discrete-link auto-selection device, the output of the working path distortion counter is connected to the control input of the working path co-commutator through the second memory unit, the second comparator unit and the OR element, the second output of the second comparator unit are connected , the second output of which is connected to the second input of the OR element, and the additional output of the block of registers via the second comparison block 39 is connected to the additional input of the block of registers. The drawing shows the principle of the electrical circuit of the proposed device. The discrete-channel auto-selection device contains an antenna switch 1, a working receiver 2 entering the working path, a first time distortion analyzer 3, a distortion counter 4, and also a measuring receiver 5 entering the measuring path 5, a second time distortion analyzer 6, block 7 counters distortions, block 8, register block comparison block 9, memory block 10, first switch 11, control unit 12, second switch 13, in addition, second memory block 14, second average block 15, element OR 16. The device operates as follows. The signal through the antenna switch 1 from the output of the measuring receiver 5 of the measuring path in the form of DC bursts arrives at the input of the second temporal distortion analyzer 6 which generates a pulse of error for each distorted above parcel of the analyzed sequence (above the amplitude of the time distortions determined correctable ability of the terminal equipment). During the set analysis time, the error pulses are summed up in block 7 of the distortion counters. After the channel analysis time has expired, the control signals of the control unit 12 control the second measuring path switch to switch the measuring path to the next source. The results obtained from the analysis of the previous channel are processed in the form of overwriting the contents of the distortion counter 4 into the first of the two registers of the 8 registers block. zeroing the distortion counter 4, comparing the readings of the first register with the readings of the second register in block 9 of the comparison. If the number of errors recorded in the first register is less than in the second, then a pulse appears at the Output of the comparison block 9, which arrives at the memory block 10, where the corresponding antenna number is fixed, and also gives the command to overwrite the readings of the first register in the second. If the number of error pulses recorded in the first register turns out to be equal to the number of errors recorded in the second register 5, then the output of the pulse matching unit 9 is not present, and the second register and memory block 10 stores the previous state. When switching the measuring path to the next antenna, the output of the second time distortion analyzer 6, by command from the control unit 12, is connected to the second counter of the distortion counter unit 7, which reaches the error pulse in the channel of this antenna during the same analysis time. During this time, the results are processed as described above. Thus, the counters of the distortion counters block 7 are connected to the second time distortion analyzer 6 alternately, the readings of these counters are alternately recorded in the first register of the registers block 8 and compared with the readings of the second register, which contains the smallest number of pulses counted by the counters of the 7 counters errors in the K-th of the simplified antennas, and the number of the K-th antenna is recorded in the iO memory block. In the working report, the signal passes through the working receiver 2, the first time distortion analyzer 3 to the distortion counter 4, which summarizes the error pulses from the output of the first time distortion analyzer 3 during the analysis time. If the distortion counter 4 is not filled within the set time interval, the contents of the distortion counter 4 are overwritten in memory block 10 and the distortion counter 4 is zeroed out. If the distortion counter 4 is filled before the end of the set time interval, then from its output to the first switch 11 a command is received to switch the working path to the number of the backup channel recorded in block 10 of memory (at the moment of the arrival of the command). If the distortion counter 4 is not filled within the set measurement interval, the information about the number of error pulses goes to the second memory block 14. If during the next time interval the number of error pulses does not exceed the threshold, then in the second block 15 comparison the number of errors is. The side signals in the first measurement interval are compared with the number of erroneous signals in the second measurement interval. If, as a result of the comparison, it turns out that the number of erroneous signals during the second interval changes more than the first, then the second counter in the 15 second comparison counter is set to 2, if the number of errors in the third interval does not fill the distortion counter 4, then this number is compared with the number of errors of the second interval, which was recorded in the second memory block 14, if, as a result of the comparison, it turns out that the number of errors of the third measurement interval is greater than the number of errors of the second, then the counter of the comparison block 15 is set to с of three hundred and generates a signal for switching the working path to the backup channel, which number is recorded in the memory unit 10. Switching the working path to the reverse channel through the element OR 16 and the first switch 11 under the action of the signal generated by the comparison unit G5 occurs only if h | 1 the layer of erroneous signals, which was fixed in block 8 of the backup channel registers, will be less than the number of erroneous signals in the third measurement interval of the working path.

Thus, the possibility in the proposed device to reveal the tendency of the working channel to deteriorate and switch to a higher quality communication channel allows to ensure the noise immunity of the system and to increase the reliability of the information.

Claims (1)

1. USSR author's certificate N9 658754, cl. H O4 B 7 / O2, 1977 (prototype).