DE1958755A1 - Threshold switch with a response threshold that can be controlled as a function of the amplitude of the input signals - Google Patents

Description

Threshold switch depending on the amplitude of the input signals controllable response sci'welie When transmitting information by means of impulses with a uniform A.! malitude there is, as is known, the advantage that the useful signals can be separated from interfering signals in a simple manner. This separation takes place Usually by means of a threshold value switch that only emits a signal when the input signal. its certain value has exceeded the threshold.

It is also known that instead of rectangular pulses advantageously given pulses in the form of a sine half-wave on the transmission path as these contain far fewer harmonics than impulses with a different shape, in particular rectangular, which thereby to an increased extent on other lines crosstalk and in these Stdrsignale cause. In the reception facilities the end points and generally also in the intermediate points, in the case of impulse transmission stretch usually called regenerative intensifiers, must be the original rectangular Signal can be restored. The threshold switch also fulfills this task which quickly delivers a powerful output signal after crossing the threshold.

Finally, it is known that when transmitting a sequence of unipolar Impulse the cores of transformers in the course of the transmission path in disadvantageous Way to be premagnetized. This is avoided by having two consecutive Pulses of opposite polarity are transmitted The pulse train transmitted in this way is referred to as pseudo- or quasiternary. Here, too, must be in the receiving devices the original unipolar pulse train, released by a separate full-wave rectifier or advantageously by a rectifying threshold switch that is required anyway to be restored.

The given by the transmitting facilities on the transmission line > 3eudoternary impulse sequence comes through unavoidable conduction properties distorted and strongly attenuated to the receiving device. A first approximate equalization the received pulse train is passed through an equalizer immediately after the input of the regenerative amplifier causes.

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

The separation of larger interfering signals from the useful signals also requires the highest possible threshold of the threshold switch, the reliable detection of the Useful signals through the threshold switch an amplitude of the useful signals to a greater extent Distance above the threshold voltage. A threshold voltage is expedient viewed from about half the value of the amplitude of the received pulses. From it it follows that it takes into account the fluctuating magnitude of the amplitude of the received Pulses is advantageous, depending on the threshold voltage of the threshold switch to control and thus to achieve an optimal effect.

The threshold switch according to the invention which fulfills this task with a response threshold that can be controlled depending on the amplitude of bipolar input signals, in particular to separate the useful signals from interfering signals in regenerative amplifiers in pulse transmission links is characterized; that the actual threshold switch consists of two, based on their input signals antiphase controllable transistors whose collectors are connected in parallel to a common Collector series resistor are connected to which the output signal can be taken off, and their emitters are connected in parallel and one has the response threshold of the threshold switch controlling transistor are fed, and that the Response threshold controlling transistor in turn is controlled by an off the input signals obtained by peak rectification and the respective amplitude of the input signals proportional DC voltage The invention is described below on the basis of a simplified; Ialt plan Fig. 1 and an exemplary detailed one Circuit diagram Fig 2 explained in more detail.

Fig. 1 shows the actual rectifying threshold switch, consisting of an input differential transformer that is earthed with the center tap of its secondary winding autor Tr, two transistors Ts1 and Ts2, whose bases each end with one end of the Secondary winding of the transformer, the collectors of which are connected in parallel and via a common collector series resistor Ri with one pole of the supply voltage and their emitters are connected in parallel and via a common emitter series resistor RP with the second pole of the supply voltage are connected. So far previously described, the arrangement forms a full-wave rectifier with active Rectifier elements, these due to the voltage drop across the common emitter series resistor R2 firstly received an increased, constant response threshold and secondly with a sufficiently large emitter series resistor R2 in the manner of a differential amplifier work, whereby when conducting one of the transistors Tsl or Ts2 the blocking effect of the respective other transistor is increased.

One fed to the primary winding of the transformer via input E. Vibration of any shape has an effect each time the threshold voltages are exceeded one of the two transistors Tsi or Ts2 a unipolar, connected to the parallel The collectors of the transistors at output A, the signal Belcallnt, which can be picked up, is in Differential amplifier circuits replace the common emitter series 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 depending on the amplitude the input signals controllable response threshold is in the common emitter circuit the two rectifying transistors Tsl and Ts2 also have a transistor circuit used with the transistor Ts3 which however does not have the task of the sum the To keep the emitter currents of the two rectifying transistors Tsl and Ts2 constant, in turn controlled by the size of the input signals of the threshold switch the response threshold of the two rectifying transistors relative to the The amplitude of the input signals changes. The control variable for the transistor Ts3 is obtained from the input signals by a full wave peak rectifier Gr, its input expediently with the ends of the secondary winding of the transformer Tr is connected and the output of which leads to the base of the control transistor Ts3 a voltage divider at the output of the peak rectifier Gr can set the response threshold the threshold switch to a desired proportion of the amplitude of the input signals can be set.

In the exemplary detailed circuit diagram, FIG. 2 corresponds to FIG actual threshold switch with the transformer Tr1 dcn transistors Tsl, Ts2 and Ts3 and resistors R1 and R2 as described in connection with FIG The peak value rectifier consists essentially of each with their bases transistors connected to one end of the secondary winding of the transformer Tr Ts4 and Ts5, their collectors in parallel at one pole of the supply voltage and their Emitter in parallel via a common emitter resistor R3, R4 a second pole the supply voltage, and a charging capacitor C, whose first Covering via a protective resistor R5 with the parallel-connected emitters of the Transistors Ts4, Ts5 connected and whose second plate is grounded.

In parallel with a larger part R4 of the common emitter series resistor R3, R4 of the transistors Ts4, Ts5 are the collector-emitter path of a switching transistor Ts6, which acts as a full-wave rectifier through the input signals of the threshold switch working diodes Di, D2 and a base voltage divider can be controlled conductive can.

Dew charging capacitor C is the high-impedance input of a parallel two-stage amplifier acting as an impedance converter with the mutually complementary Transistors Ts7 and Ts8.

The control signal for the control transistor Ts3 is at the tap of a Voltage divider R6, R7 in the emitter circuit of the output transistor Ts8 of the amplifier detachable.

The complete circuit arrangement for obtaining the control voltage for the control transistor Ts3 operates in the manner described below: Es it is assumed that the charging capacitor C has one from a previous charge medium charge voltage. For each input signal z of any polarity, the Switching transistor Ts6 is turned on, since its threshold voltage and the threshold voltage one of the diodes Di or D2 through the Diodes D3 and D4 fully compensated are. If the amplitude of the input signal is smaller than the sum of the charging voltage of the capacitor C and the threshold voltage of one of the transistors Ts4 or Ts5, so these two transistors remain blocked and the capacitor C is over the Resistors R5 and R3 and the collector-emitter path of the transistor Ts6 are discharged. The capacitor C serves as a supply voltage source for the transistor Ts6. Then the falling charge voltage of the capacitor C reaches the value of the Threshold voltage of the transistors Ts4, Ts5 reduced voltage of the input signal, so, depending on the polarity of the input signal, either transistor Ts4 begins or to conduct the transistor Ts5 and a current now flows from the supply tZ -sparmungsquelle U via one of the transistors Ts4 or Ts5, the resistor R3 and the transistor Ts6 to -U. The voltage across capacitor C equals that around the threshold voltage of the transistors Ts4 or Ts5 reduced amplitude voltage of the input signal is maintained and decreases even after the end of the input signal until it rises of the next input signal from only a little, because with blocked transistor Ts6, large Resistance value of the series connection of resistors R3, R4, R5 and high input resistance of the amplifier Ts7, Ts8 the time constant of the arrangement is large. On the other hand, is that The amplitude of the input signal is greater than the sum of the charging voltage of the capacitor C and the threshold voltage of one of the transistors Tslf and Ts5, respectively, and this becomes because of the between temporal slight discharge of the capacitor C also be the case if the amplitude of the input signal is just as large like the amplitude of the preceding signal, so conducts depending on the polarity of the Input signal either the transistor Ts4 or the transistor Tß5, it flows a current from the supply voltage source + U via the conductive transistor Ts4 or Ts5 and the protective resistor R5 and charges the capacitor C to the threshold voltage of the conductive transistor reduced voltage of the amplitude of the input signal on. As the charging voltage of the capacitor C increases, the transistor becomes conductive Ts4 or Ts5 high resistance and blocks when the charging voltage don the value of the input voltage minus the threshold voltage. The value of the protective resistance R5 is small, as is the resistance of the conducting transistor during charging Ts4 or Ts5, so that the capacitor C is charged quickly with a small time constant. On the other hand, the resistance R3 is comparatively large, so that in spite of the simultaneous conductive switching transistor Ts6 does not interfere with the charge of the capacitor C will.

In the one with its input parallel to the charging capacitor C. The impedance converting amplifier compensates for the threshold voltage of the local transistor Ts7 is the threshold voltage of the conductive transistor Ts4 or Tg5 of the peak voltage rectifier and the diode D5 between the emitter of the first transistor Ts7 and the BaFio des second transistor Ts8 is the threshold voltage of the second transistor Ts8, so that the voltage at the emitter of the transistor Ts8 corresponds to the peak value of the last input signal. The through the tap between the Emitter series resistor of transistor Ts8 forming resistors R6 and R7 fixed Part of this voltage determines the respective threshold voltage of the threshold switch.

The load on the input and thus attenuation of the input signals due to the peak rectifier connected in parallel to the input is low, because the base voltage divider of the switching transistor Tsg is high impedance, and because of the each conductive transistor Ts4 or Ts5 of the actual peak value rectifier the input only with a value of the Ijade current that is smaller by the current amplification factor of the capacitor C.

The circuit arrangement has the advantages that it is not balanced must be, and that it is fully temperature compensated

Claims (3)

Patent claims l) Threshold switch with depending on the Amplitude of bipolar input signals controllable response threshold, especially for Separation of the useful signals from interfering signals in regenerative amplifiers in pulse transmission lines, characterized in that the actual threshold switch consists of two, Transistors controllable in phase opposition via their base by the input signals (E) (Tsi, Ts2) their collectors in parallel on a common collector resistance (Rl) are connected to which the output signal (A) can be removed, and their emitter are connected in parallel and via a threshold of the threshold switch controlling transistor (wo3) are fed, and that controlling the response threshold Transistor (Ts3) in turn is controlled by one of the input signals obtained by peak rectification and the respective amplitude of the input signals proportional DC voltage. 2) threshold switch according to claim l, characterized in that the peak rectifier for generating the control transistor (Ts3) controlling DC voltage consists of two, out of phase with their base due to the input signals controllable transistors (Ts4, Ts5) serving as rectifiers, their collectors and their emitters are connected in parallel, one in parallel to the common emitter series resistor (R3, R4) of the transistors (Ts4, Ts5) lying Charging capacitor (C) and one with its high-impedance input parallel to the charging capacitor lying, serving as an impedance converter DC amplifier (Ts7, Ts8), at its The control voltage for the control transistor (Ts3) can be removed from the low-resistance output is. 3) Schwelllfertschalter according to claim 2, characterized -characterized, dan the larger part (R4) of the common emitter series resistor (R3, R4) than Rectifier serving transistors (Ts4, Ts5) the collector-emitter path of a by each input signal conducting switching transistor ITs6) in parallel is switched.