SU604174A1 - Information validity checking arrangement - Google Patents

Description

The invention relates to a technique for transmitting information and can be used in digital data transmission and processing systems using multibasic codes. A device for controlling the reliability of information is known, which contains on the transmitter side a test signal sensor connected to the input of a communication channel through a switching unit, to the second input of which the sensor output of the measuring signal is connected, and on the receiving side a synchronizer and analog-to-digital converter (ADC), the inputs of which are connected to the output of the communication channel, and the low-order decoder, the signal output of which through the calculator of the confidence index for all signals is connected to the signal input sensor reliability signal to the calibration input through which the reliability index calculator on testing signals output connected to the counter 1. The disadvantage of the known device is the low accuracy of monitoring reliability of the information arising from the use of only one type ispytatellogo signal. The purpose of the invention is to improve the accuracy of monitoring the reliability of information. It is achieved by the fact that the device. A test signal sensor on the transmitting side, connected to the input of the communication channel through a switch unit, to the second input of which the sensor output of the measuring signal is connected, and on the receiving side - a synchronizer and ADC, whose inputs are connected to the output of the communication channel, and a low-resolution decoder Dov, the signal output of which through the calculator of the confidence index for all signals is connected to the signal. | at the input of the sensor of the signal of reliability, to the calibration input of which through calculator: 1. the index user reliably In accordance with test signals, the output of the counter is connected, the high-order decoder and the distribution law estimator are entered, while the output of the higher-order ADC bits via the high-bit decoder is connected to the signal input of the counter, the clock input of which is connected to the synchronizer output, and the output of the lower bits The ADC is connected to the low-order decoder, the outputs of the types of deviations of which are connected to the inputs of the block for estimating the laws of distribution. The drawing shows the structural electrical circuit of the device described.

On the transmitting side, the device contains a test signal sensor 1, a measuring signal sensor 2 and a switching unit 3, and an ADC 4, a synchronizer 5, a low-order decoder, a distribution law estimator 7, a confidence index calculator 8 but all signals the decoder is the 9 most significant bits, the counter 10, the calculator 11 of the confidence index on the test signals and the sensor 12 of the signal of reliability.

On the transmission side of it, sensor 1 of the test signal is connected to the input of communication channel 13 via switching unit 3. The output of the sensor 2 is connected to the second input of block 3

On the receiving side, the inputs of the ADC 4 and the synchronizer 5 are connected to the output of channel 13. The signal output of the decoder b is connected via the calculator 8 to the signal input of the sensor 12, to the calibration input of which through the calculator 11 the output of the counter 10 is connected. The output of the high bits of the ADC 4 through the decoder 9 connected to the signal input of the counter 10. the clock input of which is connected to the output of the synchronizer 5. The output of the lower bits of the ADC 4 is connected to the decoder 6, the outputs of the types of deviations of which are connected to the inputs of block 7.

A device for controlling the reliability of information works the following1, by them.

The sensors of test I and measuring 2 signals are alternately connected by means of unit 3 to the input of communication channel 13. The output signal of channel 13 is converted into digital form by the ADC 4 on the interval of each character. This recognizes the symbols of the multi-position code transmitted from sensors 1 and 2. The high-order characters contain the transmitted information and enter the decoder 9. In the decoder 9, the high-order bits are decrypted and then grouped into two groups, one of which contains combinations test characters, and the other all others, including distorted test characters.

Combinations of distorted test symbols are sent to the counter 10, which is controlled by the synchronizer 5 on the clock input. Synchronizer 5 synchronously with the operation of block 3 produces clock pulses only during the clock intervals corresponding to the transmission of test signals, therefore the counter 10 counts only the number of distorted test characters. The readings of the counter 10 are used in the calculator 11 to evaluate the reliability of the test signals. The calculator 11, as well as the calculator 8, may consist of a serially connected decoder, an ILR element and a counter, the readings of which correspond to finding the count number of the counter 10 in a certain zone of count numbers. For example, counter 10 per count cycle of 256 clocks may have

account number from 1 to 256. The number 256 can be divided, for example, into 16 zones; 1 - 10 - first

zone, 11-25 - second zone, etc. The zone index gives the output counter of the calculator 11. The zone index indicates a certain zone of the range for measuring the probability of an error per symbol.

In the decoder 6, the lower bits of all types are decrypted, each of which corresponds to a certain amount of deviation from the transmitted code position. The distribution of deviations (types of combinations) is determined by

0 in block 7 by counting combinations of all types. Checking the counting numbers for compliance with certain thresholds makes it possible to identify the laws of the distribution of deviations for compliance with defined types, based on the expected interference and distortion. In calculator 8, the number of combinations of the selected types is counted and a judgment is made that the account number belongs to a specific area of numbers corresponding to a certain probability of errors per symbol.

0 Two digital words from the outputs of calculators 8 and 11 are supplied to the inputs of the sensor of the pre-test signal 12. The signal from the output of calculator 11 is received relatively rarely, after calculating the distortions in a certain amount of test information. The signal from the output of the calculator 8 comes often, but carries a less accurate assessment of the reliability.

Sensor 12 may consist of index registers coming from calculators 8 and AND, index comparison circuits, memory circuits.

0 of the comparison result and the comparison scheme of the comparison result with the index coming from the output of the calculator 8. Thereby, an amendment is introduced, which reduces the error in calculating the confidence estimate for all the signals being deleted. At the same time, the amount of test information can be made reasonably small, since it is not used to assess the accuracy itself, but to adjust the readings of another confidence meter.

When operating in a real communication channel, the proposed device can produce an accurate estimate of the reliability over several tens, hundreds and thousands of any characters in the range of estimates corresponding to the probability of error.

5 per character on the order of 10–10–10. In this case, the reasons for the decrease in the reliability of the transmitted information can be identified.

Claims (1)

1. For the number 2330246/09, class: H 04 L 1/00, dated 03.03.1976, according to which the decision to issue an author's certificate was made.