CS254433B1 - Connection for closing the loop in transfer - Google Patents

Abstract

The solution relates to wiring for closure loops in the transmission in the relay repeater Pulse Code Modulation System - PCM. In operating state, it is on the first control terminal log 1 level and second control terminal level log 0. When a loop-closing command is received in the transmission changes the logic levels on both control terminals. The first transistor opens and from the input terminal passes a bipolar signal through a set of resistors and capacitors which forms an artificial conduit designed to the signal at the automatic corrector input after closing the loop in the transmission approached the signal in operating state. There is no signal to the automatic corrector input in the "back" direction of the line and therefore cannot influence transmitting the signal in the "over" direction through the second transistor. Connection for closing the loop in the transmission is designed for digital first and higher tracts orders. It is suitable for use in a monolithic repeater first-order PCM system.

Description

BACKGROUND OF THE INVENTION The invention relates to a loop-closed circuit in a repeater of a pulse code modulation (PCM) transmission system.

Remote looping in repeaters is used to remotely locate a faulty repeater. Connections are known which close the loop in transmission from the output of the unidirectional repeater in the "there" direction to the output of the unidirectional repeater in the "back" direction, in which the signal path is interrupted. The disadvantage of these circuits is that the loop in the transmission includes only some circuits of both unidirectional repeaters. Loop signal transmission conditions are different from line transmission conditions. Other known connections close the loop in the transmission from the output of the unidirectional repeater in the "there" direction to the input of the unidirectional repeater in the "back" direction, and this input is disconnected from the line. To bring the signal transmission conditions closer to the operating conditions, an artificial RLC line is inserted between the output of the unidirectional repeater in the "there" direction and the input of the unidirectional repeater in the "back" direction. However, this increases the complexity of the device. Another drawback is the use of mechanical contacts to close the loop.

The purpose of the invention is to overcome these disadvantages. According to the essence of the invention, this is achieved in that the input terminal connected to the primary winding of the unidirectional repeater output transformer in the "there" direction is connected to the first resistor via a first decoupling resistor and the first transistor collector whose base is connected to the first control terminal. the emitter is grounded. The other end of the first resistor is connected to ground through a parallel combination of the second resistor and the first capacitor, and through the second capacitor to the base of the second transistor, which is grounded through the second bias resistor and via the bias resistor connected to the positive terminal of the source to which the second collector is connected. transistor, whose emitter is connected both to the input of the automatic repeater of the unidirectional repeater in the "back" direction, partly through the load resistor to the ground and partly to the emitter of the fourth transistor. The base of the fourth transistor is connected via a fourth resistor to the upstream passive precursor of the unidirectional repeater and this output is simultaneously grounded via the fourth bias resistor and connected via a third bias resistor to the positive terminal of the source. To this is connected the collector of the fourth transistor, whose base is connected to the collector of the third transistor, whose emitter is grounded and the base is connected to the second control terminal via the third separating resistor.

The circuitry according to the invention allows the loop to be closed in the transmission from the output of the unidirectional repeater in the "there" direction via an artificial RC-type, ie not inductive, to the input of the unidirectional repeater in the "back" direction. No mechanical contact is used in the wiring. Wiring is not demanding in terms of parts and wattages.

An example of a circuit according to the invention is further described with reference to the drawing. The input terminal 1 is connected to the primary winding of the output transformer of the unidirectional repeater in the "there" direction. The first transistor T1 is connected to it via the first decoupling resistor Rol, the base of which is connected via the second decoupling resistor Ro2 to the first control terminal Y. The emitter of the first transistor T1 is grounded and the collector is connected to the second resistor R1 and the second capacitor C2. transistor T2. The common point of the first resistor R1 and the second capacitor C2 is grounded through a parallel combination of the second resistor R2 and the first capacitor C1. The base of the second transistor T2 is grounded through the second bias resistor Rp2 and connected to the + terminal of the + U source via the first bias resistor Rp1. The collector of the second transistor T2 is connected to the positive terminal + U of the source and its emitter is connected to the input of the automatic corrector B of the unidirectional repeater in the "back" direction and is grounded via the load resistor Rz. It is also connected to the emitter of the fourth transistor T4. The collector of the fourth transistor T4 is connected to the positive terminal + U of the source, to which the passive precursor A of the unidirectional repeater A is connected back through the third bias resistor Rp3 and this output is grounded via the fourth bias resistor Rp4 and connected via the fourth decoupling resistor Ro4 to the base of the fourth transistor T4. This base is connected to the collector of the third transistor T3, whose emitter is grounded and the base is connected to the second control terminal X via the third decoupling resistor Ro3.

In the operating state, where the unidirectional repeaters in both the direction "back" and "back" transmit a signal, the first control terminal Y is level 1 and the second control terminal X is level 0. The first transistor. T1 is open and the bipolar signal from input terminal 1 is brought to ground through the first decoupling resistor Rol. If the first decoupling resistor Rol is sufficient, ie tens of kiloohms, the signal transmission in the unidirectional repeater in the "there" direction is not affected. The third transistor T3 is closed so that the unidirectional repeater in the "back" direction is not affected. The logic levels at both control terminals X and Y change upon the command to close the loop in the transmission. The first transistor T1 opens and the bipolar signal passes through the terminal 1 through the resistor and capacitor set I1. a first decoupling resistor Rol, a first and a second resistor R1 and R2, a first and a second capacitor Cla C2, and a second transistor T2 acting as an emitter follower, at the backward direction of the automatic reverser B of the unidirectional repeater. The set of resistors and capacitor Rol, R1, R2, Cl, C2 forms an artificial line which is designed so that the signal at the input of the automatic corrector B is closed when the loop is closed

254 433 in the transmission approached the signal that appears on it during operation. Level log 1 on the second control terminal X causes the opening of the third transistor T3. The fourth transistor T4 is closed. The input of the automatic corrector B does not receive the transmitted signal coming to the input of the unidirectional repeater in the "back" direction from the line and therefore cannot influence the transmission of the "there" signal through the second transistor T2. The loop in the transmission is closed and includes all the circuits of the unidirectional repeater in the 'back' direction except for the passive precursor A. The probability of a failure in the passive precursor A is low due to its circumferential simplicity.

The loop closed circuit in a PCM repeater system is designed for both first and higher order digital tracts. It is suitable for use in a monolithic repeater system with first order PCM.

Claims (1)

SUBJECT OF THE INVENTION Circuit closed loop transmission in a pulse coded PCM repeater system, characterized in that the input terminal (1) connected to the primary winding of the unidirectional repeater output transformer in the "lam" direction is connected to the first isolation resistor (Rol) a resistor (R1) and a collector of a first transistor (T1) whose base is connected to the first control terminal (Y) and whose cmilor is grounded, while the second end of the first resistor (R1) is through a parallel combination of the second resistor (R2) and the first capacitor ( C1), connected to ground and at the same time via a second capacitor (C2) to the base of the second transistor (T2), which is grounded via the second bias resistor (Rp2) and connected to the positive terminal (+ U) of the source to which the collector of the second transistor (T2) is connected, the emitter of which is connected to the input of the automatic repeater (B) of the unidirectional repeater in the "back" direction, dak, through the load resistor (Rz) to ground and to the emitter of the fourth transistor (T4), whose base is connected via the fourth resistor (R4) to the output of the passive precursor corrector (A) of the unidirectional repeater the bias resistor (Rp4) is grounded and connected via a third bias resistor (Rp3) to the positive terminal (+ U) of the source to which the collector of the fourth transistor (T4) is connected, the base of which is connected to the collector of the third transistor (T3) grounded and the base is connected to the second control terminal (X) via a third isolation resistor (Ro3).