DE1261549B - Pulse distributor for the cyclical distribution of a sequence of input pulses to the outputs of several stages - Google Patents

Description

Pulse distributor for the cyclical distribution of a sequence of input pulses on the outputs of several stages Addition to the patent: 1230 459 A pulse distributor known Art works according to FIG. 1 in such a way that after feeding a pulse train to the input E of the arrangement at the output A1 of the first distributor stage K1 the first Impulse of this impulse sequence appears. Part of this pulse energy is in this Level stored and on the one hand via the blocking line Bi and an AND circuit B brought into effect in such a way that the AND condition is not fulfilled if the second pulse arrives, d. that is, this second pulse does not go to the first stage K1 arrive and also cannot appear at the output A1. On the other hand will a part of the stored pulse energy in the AND circuit b used that here the AND condition is met when the second input pulse arrives, so this second impulse appears via the second distributor stage K2 at the output A2 thereof.

In the same way, part of the energy of the pulse is in the second Stored distributor stage K2 and used to turn over the blocking line Bi to block the first stage K1 and the third stage K3 for the third pulse prepare. In this way, the pulses up to the last stage K (n + i) passed on. The last stage is no longer connected to the blocking line Bi, d. In other words, it can no longer block the first stage K1 retrospectively. (The (n +2) th The pulse of the pulse train appears again at the output of the first distributor stage K1.

In Fig. 2, the first distributor stage K1 and the blocking circuit B are shown. The resistors R 1 and R 2 are chosen such that the voltage at point A is so low that the transistor TK i is blocked in stage K1. The diode DA is blocked by a positive pulse at input E. The potential at point A is now determined by the forward voltage of the diode DS and the base-emitter diode of the transistor TK I. The transistor TI <, switches on and the collector voltage jumps from the value + UB to the saturation voltage UCE (sat). The collector of the transistor TK i corresponds to the point A i in FIG. 1. When the input pulse has ended, the diode DA becomes conductive again and the voltage at point A is reduced so that the transistor TKi is blocked. As a result of the induction current which is effective in the transformer V1, the collector voltage UCE of the transistor TK exceeds the voltage UB. This overshooting voltage Uo can now be used with the help of two additional transformer windings to prepare the next stage and to block the first stage. However, the preparation of the following stage K2 for the next input pulse should not be described further because it is not the subject of the invention.

The blocking of the first stage takes place in such a way that the winding W3 is polarized in such a way that as a result of the overshooting voltage U, the diode Dz and the transistor TB become conductive. The voltage at point A is now also determined by transistor TB . If a second positive pulse hits input E during the overshoot, diode DA is blocked again, but the voltage at point A is held by transistor TB and transistor TK remains blocked. With the preparation by stage K1, this second impulse brings stage K2 into the conductive state, which is structured in the same way as stage K1. At the end of the second input pulse, the collector voltage in stage K1 will also overshoot and saturate transistor TB via a diode D2, thus blocking stage K1 for a third input pulse.

For the duration of the overshoot tü the condition applies: 2tf - ti > tiz > tf.

The time ti indicates the pulse width and the time tt the pulse spacing of the input pulse train. The duty cycle is the time tü is inversely proportional to the overshoot voltage U .. The main patent concerns - a blocking circuit that blocks the first stage especially for an input pulse train with a small duty cycle improved and in which with the help of the additional voltages U1 und_ U2 - the current flowing through the blocking line and the duration of the overshoot can be adjusted. ; The present invention represents a further development of the pulse distributor according to the main patent. The level of the overshoot voltage U., which causes the blocking, is determined by the equation Uo - UD2 + UBE + U1 - U2-The two diode voltages UD 2 and UBE are temperature-dependent . and thus also the overshoot voltage U .. The temperature dependency can be compensated with the additional voltages U1 and / or U2.

The invention is now directed to. that the compensation is carried out over a large temperature range with the help of the additional voltage U2, which is achieved in that the additional voltage U2 is taken temperature-stabilized from a transistor amplifier, - which consists of two stages with the transistors T 1 and T 2 in emitter circuit and in parallel to the input of the first transistor stage two series-connected, forward-biased diodes DT with temperature-dependent forward voltage are arranged and at the output of the second transistor stage a voltage divider with the partial resistors R 3 and R 4 is arranged, which is dimensioned so that the one removed at the partial resistor R 3 Output voltage U2 has the same temperature dependence as the sum of the forward voltages of the emitter-base path UB ″ of the blocking transistor TB and UD 2 of the diode D2.

The circuit arrangement according to the invention and its mode of operation are described in more detail below with reference to the drawings: The forward voltage UD 2 of a diode D 2 and UBE at the base-emitter path of the transistor TB according to FIG. 2 depend on the temperature. So that the pulse distributor works stably in a large temperature range, the influence of the temperature dependence of these forward voltages during the time period t. the overshoot balanced.

The stabilization process takes place according to FIG. 3 in the compensating arrangement according to the invention for the voltage U2 in such a way that the forward voltage of the diode DT decrease with increasing temperature. This also reduces the collector voltage at transistor T2. The resistors R 3 and R 4 arranged in series at the output of the compensation circuit as a voltage divider are dimensioned so that the additional voltage U2 which brings about temperature compensation is taken from resistor R 3 and fed to terminals 1 and 2.

In addition to the temperature compensation, the current dependency of the diode voltages D2 and UBE can also be compensated, which is particularly necessary when the additional voltages U1 and U2 are no longer significantly smaller than the diode voltages. In this case, the compensation is effected in that the additional voltages U1 and / or U2 are made current-dependent in such a way that they correspond to the current dependence of the diode voltages UD 2 or UBE, so that the resulting voltage U0 UBE + UD2 + U1 U2 is constant.

Claims (1)

Claim: Circuit arrangement for a pulse distributor for the cyclical distribution of a sequence of input pulses to the outputs of several stages according to Patent 1230 459, in which a switching transistor is used to block the first distributor stage, the emitter-base path of which is in series with two additional voltage sources (U1 and U2 ) and the parallel connection of the series connections each with a winding (Ws) of the input transformer of each stage with the exception of the last stage with a diode (D2), characterized in that for temperature compensation, the additional voltage (U2) is taken temperature-stabilized from a transistor amplifier, which consists of two stages with the transistors (TI and T2) in emitter circuit and in which two series-connected, forward-biased diodes (DT) with temperature-dependent forward voltage are arranged parallel to the input of the first transistor stage, and a voltage divider with the partial resistors at the output of the second transistor stage (R 3 and R 4), which is dimensioned so that the output voltage (U2) taken from the partial resistor (R3) has the same temperature dependency as the sum of the forward voltages of the emitter-base path (UBE) of the blocking element Transistors (TB) and (UD 2) of the diode (D 2).