SU535741A1 - Device for transmitting and receiving data - Google Patents

Description

but, on the other hand, through the allocation unit 14 of the carrier frequency, while the output of the synchronous detector 13 is connected via a low-pass filter 15 to one input of a solving circuit 16 directly, and to another through a clock source 17, and the input of compensation filter 10 is connected to the input bandpass filter 9.

The device works as follows.

The sender 1 of the parcels on the transmitting side of the device generates from the input information supplied to its input a modulating signal fed to the modulator 2, to which a signal from the generator 3 of the carrier frequency is fed. Modulator 2 generates a modulated signal having a spectrum with two sidebands. The spectrum of one sideband signal is allocated by bandpass filter 4.

The portion of the signal spectrum adjacent to the group control frequency of 84, 14 kHz is cut by the fencing filter 5. A compensation signal is generated from the other sideband of the modulated signal. The signals from the outputs of the blocking filter 5 and the compensation filter 7 are added by the adder 6 and are fed to the apparatus 8 of a high-frequency transmission system containing notch filters of the group control frequency 84.14 kHz.

At the receiving side, the band-pass filter 9 and the compensation filter 10 isolate the spectrum of the signal that is transmitted to the communication channel and passes through the apparatus 8 of the high-frequency transmission system. The signals from the outputs of the band-pass filter 9 and the compensation filter 10 after passing through the phase shifter 11 are added by the adder 12. The received signal is applied to the inputs of the synchronous detector 13 and the carrier separation block 14. As a result of synchronous detection and post-detector filtering by the low-pass filter 15, the signal spectrum is transferred from the high-frequency to the low-frequency region.

The signal thus obtained is used to restore the clock frequency and further regeneration. For this, the output of the low-pass filter 15 is connected to the inputs of the decision circuit 16 and the source 17 of clock pulses. The decision circuit 16 regenerates the binary bursts by gating the output signal of the low pass filter 15 at the instants of the arrival of the clock pulses from the source of the 17 clock pulses, i.e., the polarity is determined in the resolver circuit 16 and the shapes of the bursts are restored.

The sum of the complex spectrum (for example, when transmitting the upper sideband) of a signal for frequencies above the carrier and the complex-conjugate spectrum of the signal below the carrier must be a constant value, which is necessary for the frequency characteristics of the bandpass filters 4 and 9. Spread this condition in case of switching on fencing filter 5 on the transmission side, it is possible to determine the requirements for the frequency characteristics of the fringe filter 5 and compensation filters 7 and 10.

The undesired phase shift of the spectral components of the signal generated

filters 7 and 10 and the primary broadband channel transmitted to the edge of the bandwidth is eliminated by means of a phase shifter 11. To facilitate setting up the phase shifter 11, it is adjustable, and can be adjusted manually or automatically. In the latter case, it is necessary to introduce a phase shifter adjustment unit connected to the output of the decision circuit 16.

The proposed device allows us to solve the actual problem of high-speed data transmission over the primary broadband channel with a small effect of notch filters of the group control frequency 84,

14 kHz per received data signal.

Claims (1)

1. Mizin, I.A., et al. Information Transmission on Message Switching Networks, ed. “Soviet radio., M., 1972, p. 138 (prototype).