DE1958755B2 - Bipolar threshold amplitude trigger - is for regenerative pulse amplifier with parallel transistors supplied out of phase through base terminals - Google Patents

Abstract

The bipolar threshold amplitude trigger, for separating signal from noise in regenerative amplifiers in pulse transmission paths, has its actual triggering circuit consisting of two parallel-coupled transistors (Ts1, Ts2) supplied at their bases with oppositely-phased input signals, via a transformer. The threshold is determined bya third transistor (Ts3) connected by its emitter to the emitters of the other transistors and by its collector to the supply end of the two transistor common collector resistor (R1). The third transistor emitter is coupled via a resistor (R2) to the supply, and its base to a rectifier.

Description

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When information is transmitted by means of pulses with a uniform amplitude, this is known to result the advantage that the useful signals can be separated from interfering signals in a simple manner. This separation is usually done by a threshold switch that only emits a signal when the input signal has exceeded a certain value, the threshold.

It is also known that instead of rectangular Pulses are advantageously given pulses in the form of a sine half-wave on the transmission path as these contain far fewer harmonics than other shaped pulses, especially square-shaped, which thereby crosstalk to other lines to an increased extent and cause interfering signals in these. In the receiving devices in the terminal and generally also in the intermediate stations, at Pulse transmission lines, usually called regenerative amplifiers, must be originally rectangular Signal can be restored. This task is also fulfilled by the threshold value switch, which is activated after the value has been exceeded the threshold quickly delivers a powerful output signal.

Finally, it is known that when transmitting a Consequence of unipolar impulses the cores of transformers in the course of the transmission line in disadvantageous Way to be premagnetized. This is avoided in that two consecutive pulses be transmitted with opposite polarity. The pulse train transmitted in this way is called pseudo or Quasiternary termed Here too, the original unipolar pulse sequence must be used in the receiving devices, either by a separate full-wave rectifier or advantageously by a rectifying, Threshold switches, which are required anyway, can be restored.

The pseudo-ternary pulse train sent by the transmitting devices to the transmission line arrives Distorted by unavoidable line properties and strongly attenuated to the receiving device. An initial, approximate equalization of the received pulse train is done immediately by an equalizer after the input of the regenerative amplifier.

The completely equalized and amplified to its original value pulse train is only available at the output of the regenerative amplifier available. The input of the threshold switch connected downstream of the equalizer a pre-equalized, damped pulse train is thus supplied. Due to the particular dependency Cable attenuation that fluctuates with temperature also changes the amplitude of the received Impulses.

The separation of even larger interfering signals from the useful signals requires the highest possible threshold the threshold switch, the reliable detection of the useful signals by the threshold switch an amplitude the useful signals at a greater distance above the threshold voltage. A The threshold voltage is considered to be about half the amplitude of the received pulses. From it it follows that it is advantageous in view of the fluctuating magnitude of the amplitude of the received pulses is to control the threshold voltage of the threshold switch as a function of this and thus to achieve an optimal effect.

The threshold value switch according to the invention which fulfills this task as a function of the amplitude bipolar input signals controllable response threshold, in particular for separating the useful signals of interfering signals in regenerative amplifiers in pulse transmission lines is characterized by this net, that the actual threshold switch consists of two, on their base by the input signals out of phase controllable transistors whose collectors are connected in parallel to a common collector series resistor are connected, at which the output signal can be removed, and their emitters are connected in parallel and are fed via a transistor controlling the response threshold of the threshold value switch, and that the transistor controlling the response threshold is in turn controlled by one obtained from the input signals by peak rectification and DC voltage proportional to the respective amplitude of the input signals.

The invention is illustrated below with the aid of a simplified circuit diagram F i g. 1 and an exemplary one

detailed circuit diagram F i g. 2 explained in more detail.

Fig. 1 shows the actual rectifying threshold switch, consisting of an input differential transformer Tr grounded with the center tap of its secondary winding, two transistors TsI and Ts 2, whose bases are each m <t one end of the secondary winding of the transformer, whose collectors are connected in parallel and Via a common collector series resistor A1 with a Po 'of the supply voltage and its emitter are connected in parallel and are connected to the second pole of the supply voltage via a common emitter series resistor R 2. As far as described so far, the arrangement forms a full-wave rectifier with active rectifier elements, whereby these firstly receive an increased, constant response threshold due to the voltage drop at the common emitter series resistor R 2 and, secondly, when the emitter series resistor R 2 is sufficiently large, they work like a differential amplifier, with one of the transistors being conductive Ts 1 or Ts 2 the blocking effect of the respective other transistor is increased.

An oscillation of any shape fed to the primary winding of the transformer via the input £ causes a unipolar signal that can be picked up at the parallel-connected collectors of the transistors at output A whenever the threshold voltages of one of the two transistors Ts 1 or Ts 2 are exceeded.

It is known in differential amplifier circuits to replace the common emitter pre-resistor by a transistor circuit that keeps the sum of the emitter currents of the two transistors constant. In the threshold switch according to the invention with a response threshold that is controllable as a function of the amplitude of the input signals, a transistor circuit with the transistor Ts 3 is also used in the common emitter circuit of the two rectifying transistors Ts 1 and Ts 2, but this does not have the task of calculating the sum of the emitter currents of the two rectifying transistors To keep transistors TsI and Ts 2 constant, but which in turn, controlled by the size of the input signals of the threshold switch, changes the response threshold of the two rectifying transistors in proportion to the amplitude of the input signals. The control variable for the transistor Ts 3 is obtained from the input signals through a full-wave peak rectifier Gr , whose input is conveniently connected to the ends of the secondary winding of the transformer Tr and whose output leads to the base of the control transistor Ts 3 through a voltage divider at the output of the peak rectifier Gr the response threshold of the threshold switch can be set to a desired proportion of the amplitude of the input signals.

In the exemplary detailed circuit diagram F i g. 2 corresponds to the actual threshold switch with the transformer Tr, the transistors Ts I, Ts 2 and Ts 3 and the resistors R 1 and R 2 in connection with F i g. I described. The peak value rectifier essentially consists of the transistors Ts 4 and Ts 5 connected with their bases to one end of the secondary winding of the transformer Tr , their collectors in parallel on one pole of the supply voltage and their emitters in parallel via a common emitter series resistor R 3, R 4 on the second f> 5 pole of the supply voltage, and a charging capacitor C, the first layer of which is connected to the parallel-connected emitters of the transistors Ts4, Ts 5 via a protective resistor /? 5 and the second layer of which is grounded.

The collector-emitter path of a switching transistor Ts6 is parallel to a larger part /? 4 of the common emitter precursor R 3, R 4 of the transistors Ts4, Ts5 can be controlled.

The charging capacitor C is connected in parallel to the high-impedance input of a two-stage, 8 as an impedance converter acting amplifier with mutually complementary transistors Ts 7 and Ts The control signal for the control transistor Ts 3 is connected to the tap of a voltage divider R 6, AE7 in the emitter circuit of the Ausgangstnsnsistors Ts 8 of the amplifier detachable.

The complete circuit arrangement for obtaining the control voltage for the control transistor Ts 3 operates in the manner described below:

It is assumed that the charging capacitor C has an average charging voltage from a previous charge. With each input signal E of any polarity, the switching transistor Ts 6 is turned on, since its threshold voltage and the threshold voltage of one of the diodes DX or D 2 are fully compensated by the diodes D 3 and DA. If the amplitude of the input signal is less than the sum of the charging voltage of the capacitor C and the threshold voltage of one of the transistors Ts 4 or Ts 5, then these two transistors remain blocked and the capacitor C is connected via the resistors R 5 and R 3 and the collector Discharge the emitter path of the transistor Ts 6. The capacitor CaIs serves as the supply voltage source for the transistor Ts6. If the falling charge voltage of the capacitor C then reaches the value of the voltage of the input signal reduced by the threshold voltage of the transistors Ts 4, Ts 5, either the transistor Ts4 or the transistor Ts5 begins to conduct, depending on the polarity of the input signal, and it now flows in Current from the supply voltage source + U via one of the transistors Ts 4 or Ts 5, the resistor A3 and the transistor Ts6 to -U. The voltage across the capacitor C is equal to the amplitude voltage of the input signal reduced by the threshold voltage of the transistors Ts 4 or Ts 5 and is retained and only drops slightly after the end of the input signal until the next input signal occurs, because when the transistor Ts 6 is blocked, there is a high resistance value the series circuit of the resistors R 3, R 4, R 5 and high input resistance of the amplifier Ts 7 Ts 8, the time constant of the arrangement is large However, if the amplitude of the input signal is greater than the sum of the charging voltage of the capacitor C and the threshold voltage of the transistors Ts 4 or Ts 5, and this will also be the case because of the slight discharge of the capacitor C in the meantime, if the amplitude of the input signal is the same as the amplitude of the previous signal, either transistor Ts4 conducts depending on the polarity of the input signal or the transistor Ts5, a current flows from the feed voltage source + U via the conductive transistor Ts4 or Ts 5 and the protective resistor R 5 and charges the capacitor C to the voltage of the amplitude of the input signal reduced by the threshold voltage of the conductive transistor. As the charging voltage of the capacitor C increases, the conductive transistor Ts 4 or Ts 5 is high-

ohmic and blocks when the charging voltage has reached the value of the input voltage minus the threshold voltage. The value of the protective resistor / 5 is small, as is the resistance value of the conductive transistor 7s 4 or 75 5 during charging, so that the capacitor C is charged quickly with a small time constant. On the other hand, the resistance R 3 is comparatively large, so that despite the switching transistor 7s 6 being conductive at the same time, the charge of the capacitor C is not adversely affected.

In the impedance-converting amplifier with its input parallel to the charging capacitor C, the threshold voltage of the first transistor Ts 7 compensates the threshold voltage of the conductive transistor 7s 4 or Ts 5 of the peak voltage rectifier and the diode D 5 between the emitter of the first transistor 7s 7 and the base of the second Transistor Ts 8 is the threshold voltage of the second transistor Ts 8, so that the voltage at the emitter of transistor 7s8 corresponds in each case to the peak value of the last input signal. The part of this voltage which is fixed by the tap between the resistors R 6 and R7 forming the emitter series resistor of the transistor Ts 8 determines the respective threshold voltage of the threshold value switch.

The load on the input and thus attenuation of the input signals due to the input signal connected in parallel Spkzenwertrectrichter is low because

ίο the base voltage of the switching transistor 7s6 is high resistance, and vi-eil the respective conductive transistor 7s 4 or Ts 5 of the actual peak value rectifier loads the input only with a value of the charging current of the capacitor C which is smaller by the current amplification factor.

The circuit arrangement has the advantages that it does not have to be adjusted and that it is fully temperature-compensated is.

1 sheet of drawings

Claims (3)

Patent claims: 1. threshold switch with a function of the amplitude of bipolar input signals controllable response threshold, in particular for separating the useful signals from interference signals in regenerative amplifiers in pulse transmission paths, characterized in that the actual threshold value switch consists of two opposite phase drivable about their base by the input signals (E) transistors ( Ts 1, Ts 2) whose collectors are connected in parallel to a common collector resistor (R 1), from which the output signal (A) can be picked up, and whose emitters are connected in parallel and fed via a transistor (7s 3) which controls the response of the threshold switch be, and that the The transistor (Ts 3) controlling the response threshold is in turn controlled by a direct voltage obtained from the input signals by peak rectification and which is proportional to the respective amplitude of the input signals. 2. Threshold switch according to claim 1, characterized in that the peak rectifier for generating the control transistor (7s 3) controlling DC voltage consists of two transistors (Ts 4, Ts 5) which can be controlled in phase opposition by the input signals via their base and which serve as rectifiers The collectors and their emitters are each connected in parallel, a charging capacitor (C) lying parallel to the common emitter series resistor (R 3, A4) of the transistors (7s 4, Ts 5) and a DC amplifier (7s) which has its high-resistance input parallel to the charging capacitor and serves as an impedance converter 7, TsS), at whose low-resistance output the control voltage for the control transistor (Ts 3) can be removed. 3. Threshold switch according to claim 2, characterized in that the larger part (A4) of the common emitter series resistor (R 3, R 4) of the transistors serving as rectifiers (7s4, Ts 5) is the collector-emitter path of a switching transistor ( 7s 6) is connected in parallel.