SU536606A2 - Long-distance monitoring system - Google Patents

Description

(54; LONG COMMUNICATION CONTROL SYSTEM

Claims (1)

The invention relates to the monitoring and measurement of multichannel long-distance communication systems with frequency division multiplexing. By bus. St. NP 371694 is well-known for monitoring long-distance communication lines, which contains a terminal station with a sinusoidal voltage frequency generator f, unattended amplifying stations (LEL) with a sinusoidal frequency voltage generator „yn. and serviced amplifying stations (PMO; selective level meters at frequency f + S ISAL-NCHL. However, the known system does not provide simultaneous control of the non-linearity of LUP amplifiers on all sections of the trunk between the PMO. The purpose of the invention is to enable simultaneous control of the non-linearity of LUP amplifiers on all sections of the trunk between the PMO. For this purpose, the control system of the communication line containing the terminal station with the generator of sinusoidal voltage f, with the generators of sinusoidal voltage f „vn. and GCC with selective level meters at frequency and,., t is a quadrupole, which is connected in parallel to one of the linear path elements in the GCC. The drawing shows the block diagram of the control system. contains terminal station 1 with generator 2 sinusoidal voltage of frequency f NUP 3, each of which consists of amplifier 4, generator 5 of sinusoidal voltage of frequency i ' telemechanics 6 and switch 7, and OUP 8, each of which consists of ntov linear path: amplifiers9, 10, 11, phase corrector 12 and the cosine corrector 13, as well as the selective level meter 14 at the frequency Iam. Hvn. quadrupole 15, which is connected in parallel to one of the elements of the linear path of the OUP 8, for example, to a cone corrector 13. The monitoring system of long-distance communication lines works as follows: To monitor the nonlinearity of amplifier 4 of one of the LUP 3 from terminal station 1 in the first path The transmission system from generator 2 is supplied with a sinusoidal signal of frequency f meas. On the controlled LCP 3, remotely using a telemechanic device 6, the generator 5 is connected to the input of the amplifier 4 through a switch 7. A sinusoidal voltage frequency f у y В is connected as a result of the interaction of frequency currents i and f in the controlled PTH amplifier 4 harmonic and combination nonlinearity products, the levels of which characterize the degree of nonlinearity of the amplifier 4. The level of the combination product of nonlinearity f c,;,. , ", Is measured at the next subsequent GTC 8 using a selective level meter 14. The parallel connected inputs of the cosine corrector 13 and the quadrupole 15 receive a signal of a nonlinearity product to be suppressed. By manual adjustments in the quadrupole 15, a change is made in the phase and amplitude of the signal of the nonlinearity product, in which the amplitude of this signal at its output becomes equal to the amplitude of the analogous signal at the output of the cosine corrector 13, and its phase is shifted 06 relative to the phase of the latter by 180. Due to this, the non-linearity product signal at the common output of the cosine corrector 13 and quadripole 15 is absent. The four-quadrupole 15 is designed so that the mutual compensation of signals at the parallel connected outputs of the cosine corrector 13 and the quadrupole 15 is provided only at the frequency of the suppressed signal or in a narrow band near it. The display during manual adjustment of the four poles 15 to the maximum suppression is carried out using a selective level meter 14, which in this case is included in some point of the path on the PMO 8 after switching on the quadrupole 15. Claims of the autonomous lines monitoring system St. No. 371694, in connection with the fact that, in order to enable simultaneous control of the non-linearity of amplifiers in unattended amplifying points (Hynj in all sections of the trunk between the serviced amplification points (GCC), a quadrupole is connected in parallel to one of the elements of the linear path in the PMO.