SU1587655A1 - Correlation system for transmission and reception of optical signals - Google Patents

Abstract

The invention relates to communication technology and can be used for crypto-resistant transmission of additional discrete information without the use of additional communication lines. The system contains N sources of discrete messages 1, N optical transmitters 2, N optical lines of communication 3, N optical receivers 4, N recipients of discrete messages 5, N - 1 additional sources of discrete messages 6, N - 1 correlometers 7 of the transmitting side, N - 1 receiver 8 side correlators, N - 1 drivers 9, synchronizers 10 and 11 of the transmitting and receiving sides, N - 1 meters 12 average value of photoelectrons, N - 1 subtractors 13, clock frequency multiplier 14. The purpose of the invention is to increase the reliability of reception - achieved , what System mutual dependence additional signals transmitted absent, since when transmitting one additional message, all other transmitted signals on the main channels are not distorted, but only one of the N - 1 main signals is distorted, and this distortion practically does not affect the quality of its reception in receivers 4 due to the use of meters 12. 1 sludge.

Description

The invention relates to communication technology and can be used for critical transmission of additional discrete information without the involvement of additional optical communication lines.

The aim of the invention is to increase the reliability of the reception.

The drawing shows a functional diagram of the system.

The system contains N sources 1 of discrete messages, N optical transmitters 2, N optical communication lines 3, N optical receivers 4, 15

N recipients of 5 discrete messages, N - 1 additional sources of 6 discrete messages, N. - 1 correlometers of the transmitting side., N - 1 correlometers of 8 receiving side, 20 N - 1 formers of 9 discrete symbols of received additional messages, synchronizer 10 of the transmitting side, synchronizer 11 of the receiving side, 'N - 1 meters 12 of the average 25th value of the photoelectrons, N · - 1. Subtractors 13, a clock multiplier 14.

Correlation communication system works as follows. 39

The signals from the outputs of sources 1 of discrete messages using transmitters 2 of electromagnetic radiation of the optical range are transmitted via communication lines through a receiver 4 to 55 inputs of the respective recipients 5 discrete messages. A decision is made in the receiving units 4 about the presence or absence of a discrete signal by comparing the calculation of the secret number N of photoelectrons with a threshold value n ₀ in each time interval with a given probability p (n).

When transmitting discrete messages over long distances via communication lines at regeneration points, unauthorized disclosure of the contents of transmitted messages is possible.

In the transmission and reception system, each correlation between the N - 1 and N main channels for transmitting signals of the optical range individually is measured using N - 1 correlometers 7 on the transmitter. side. The measured correlation signals are compared with the corresponding discrete transmitted sources 6 by additional signals at the inputs of the corresponding subtractors 13. The mismatch signals are processed in the direction of decreasing them by acting on the transmitted signals of the main channels using transmitters 2, for example, increasing or decreasing the number N of photoelectrons so that the correlation the dependence between the signals of the corresponding main channels was stepwise changed at clock intervals. Moreover, there is no mutual dependence of the transmitted additional signals, which distinguishes the proposed correlation communication system from the known one, since when transmitting one additional message, all the other transmitted signals on the main channels are not distorted, and only one of the N - 1 main signals is distorted.

This distortion of the transmitted signal through the main channel does not affect the quality of its reception in the receivers 4, since in the proposed correlation system using a block of 12 meters of the average value of the number of photoelectrons, the value of these photoelectrons with a higher sampling clock frequency than the measurement frequency is kept constant correlations .. For this, the clock inputs of the correlometers 7 are connected directly to the output of the synchronizer 10, and the clock inputs of the meters 12 of the average value of photoelectrons with are integrated with the output of the synchronizer 10 through the clock multiplier 14.

Due to automatic stabilization of the average value of the number η of photoelectrons, the indicated distribution law (Poisson or Bose-Einstein) 'is preserved, which provides a given probability of exceeding the η threshold by _the photoelectrons of the main N channels.

Claims (1)

Claim A correlation system for transmitting and receiving optical signals, containing N circuits from a series-connected source of discrete messages, an optical transmitter, an optical communication line, an optical receiver and a receiver of discrete messages, on the transmitting side ⁵ 1587655 N - 1 additional sources of discrete messages, N - 1 subtractors, N - 1 correlometers and synchronizer, the output of the synchronizer is connected to the clock input of each of N - 1 correlometers and the clock input of each of N - G additional sources of discrete messages, the output of each of which is connected with the first input of the corresponding subtractor, the output of each of which is connected to the control input of the corresponding transmitter, the output of each of the N - 1 transmitters is connected to the first input of the corresponding correlometer, the output of the Nth transmitter connected to the second inputs of each of N - 1 correlometers, on the receiving side - N - 1 correlometers, N - 1 discrete symbol shapers and a synchronizer, the output of which is connected to the clock inputs of each of N - 1 correlometers and to the clock inputs of each of N - 1 shapers of discrete symbols, the output of each of the N - 1 optical receivers is connected to the first 10 input of the corresponding correlometer, the output of each of which is connected to the input of the corresponding shaper of discrete messages, the output of the Nth optical receiver is connected to by the input of each of N - 1 correlometers, the output of the transmitter side synchronizer is connected to the input of the receiver side synchronizer, characterized in that, in order to increase the reliability of reception, a clock multiplier and N - 1 meters of average photoelectrons are introduced, the inputs of which are connected to the outputs of the corresponding optical transmitters, the synchronizer output is connected through a clock multiplier to the clock inputs of each of the N - 1 meters of the average value of photoelectrons, the output of each correlometer is connected nen to a second input of a respective subtractor, the output of each meter average photoelectrons connected to the third input of the corresponding subtractor.