CS242654B1 - Wiring to control the frequency response of a variable corrector - Google Patents

Abstract

The solution concerns a circuit for controlling the frequency characteristic of a variable corrector in repeaters of a digital signal transmission system. The transmission frequency characteristic of a variable corrector (PK) is automatically controlled by changing the size of the resistor D connected to its control input (3). The output signal from the linear amplifier (LZ) is, after rectification, fed to the control electrode of the field-controlled transistor (T). At the nominal length of the cable section, the internal resistance of the field-controlled transistor (T) has the value required for frequency-independent transmission of the variable corrector (PK). If the cable section is shorter than the nominal length, the negative bias voltage of the control electrode decreases and the internal resistance of the field-controlled transistor (T) also decreases. If the length of the cable section is greater than the nominal length, the internal resistance of the field-controlled transistor (T) increases. The connection is suitable for repeaters and terminal devices, especially transmission systems and pulse code modulation - PCU - for low and high transmission speeds.

Description

The invention relates to a circuit for controlling the frequency response of a variable concealer in repeaters of a digital signal transmission system.

In digital repeaters a variable corrector with an automatically controlled frequency response is connected. The variable corrector corrects for frequency-dependent attenuation changes that result from changes in cable lengths between repeaters and attenuation changes due to temperature fluctuations and cable aging. The variable corrector frequency response is automatically controlled by varying the magnitude of the variable resistance depending on the magnitude of the amplitude of the corrected pulses at the repeater decision point.

In the known circuit, the control loop is supplied from a separate winding of the output transformer. This signal comes through a peak detector to one input of a differential amplifier, the other input of which is connected to a reference voltage source. The output of the differential amplifier is connected to a transistor which controls the dynamic resistance of the diode string divided into two symmetrical branches by its collector current. The variation of the diode string resistance controls the waveform of the variable corrector.

Other known connections differ only in that the variable resistance is realized by a thermistor or a field-controlled transistor. The disadvantage of these circuits is the considerable circuit complexity and the necessity to use a differential amplifier. The high power consumption is due to the high power consumption of the diode chain and differential amplifier.

The purpose of the invention is to overcome these disadvantages. By nature

242 654 of the invention is accomplished in that a collector of a field-controlled transistor whose emitter is grounded is connected to the control input of the variable corrector. The control electrode is grounded via a blocking capacitor and connected to a common point of the first and second bias resistors. The other end of the first bias resistor is connected to the negative terminal of the power supply. The other end of the second bias resistor is connected to ground through both a filter capacitor and a load resistor and through a first diode to a common point of the second diode whose anode is grounded and a decoupling capacitor connected to the output of the linear amplifier.

The circuit for controlling the frequency response of the variable corrector according to the invention is circumferentially simple and has a low power consumption.

It does not require a differential amplifier or a DC amplifier to control the variable resistance;

An example of a wiring for controlling the frequency response of a variable concealer is described below with reference to the drawing. A variable corrector PK is connected to the input terminal 1, whose output 2 is connected to the input of the decision circuit RO via a linear amplifier LZ. The collector of the field-controlled transistor T is connected to the control input J of the variable concealer PK, the emitter of which is grounded. The control electrode of the field-effect transistor T is grounded via the blocking capacitor C1 and connected to the negative terminal -U of the power supply via a first bias resistor R1. The other end of the first bias resistor R1 is grounded through the second bias resistor R2, the first diode D1 and the second diode D2. The common point of the second biasing resistor R2 and the first diode D1 is connected to ground through both the filter capacitor C2 and the load resistor R3. The common point of the first and second diodes D1, D2 is connected via a separating capacitor C3 to the output of the linear amplifier LZ.

The signal comes from the line to the input terminal 1 of the variable corrector PK, whose transmission frequency response is automatically controlled by changing the magnitude of the resistor connected to control input 3. This resistance changes the transmission amount of the variable corrector PK in the low frequency range and the slope of its frequency response in the high frequency range depending on the signal size at the repeater decision point. The linear amplifier LZ amplifies the signal to the magnitude required for the function of the decision circuit RO and the variable corrector PK circuits. The output signal from the linear amplifier LZ is applied via a decoupling capacitor C3 to the rectifier formed by the first and second diodes D1, D2. On its load resistor and filter capacitor C2 there is a positive DC voltage equal to the amplitude of the output signal of the linear amplifier LZ. This voltage is applied to the control electrode of the field-controlled transistor T, which is coupled to ground through a blocking capacitor C1. By the first and second bias resistors R1, R2 the negative electrode bias is set so that at the nominal length of the cable section, the internal resistance of the field-controlled transistor T has the value required for the frequency independent transmission of the variable corrector PK. If the cable section is shorter than the rated section, the positive DC voltage at the load resistor R3 will increase, thereby reducing the negative bias of the control electrode and the internal resistance of the field-controlled transistor T. This will automatically change the transmission of the PK corrector variable. If the length of the cable section is greater than the nominal one, the internal resistance of the field-controlled transistor T increases and changes the transmission of the variable corrector PK in the desired sense.

The wiring for controlling the frequency response of the variable corrector is suitable for repeaters of transmission systems with digital signal and terminal equipment of transmission systems with pulse code modulation for both low and high transmission rates.

Claims (1)

SUBJECT OF THE INVENTION 242 654 Arrangement for controlling the frequency response of a variable corrector in repeaters of a digital signal transmission system with a field-effect transistor, where the variable corrector output is connected to a decision circuit input via a linear amplifier, characterized in that the variable corrector (PK) control input (3) is connected to a collector of a field-effect transistor (T), the emitter of which is grounded, the control electrode being grounded via the blocking capacitor (C1) and connected to a common point of the first and second bias resistors (R1, R2) is connected to the negative terminal (-U) of the source and the other end of the second bias resistor (R2) is connected to ground through the filter capacitor (C2), through the load resistor (R3) and through the first diode (D1) to the common point of the second diode (D2), whose anode is grounded, and the decoupling capacitor (C3) connected to the output of the linear amplifier (LZ).