DE1033711B - Runtime chain made up of individual stages - Google Patents

Description

GERMAN

The subject of patent 958 127 is one of individual Runtime chain built up in stages, the task of which is to generate output pulses that are temporally shifted from one another to deliver. For this purpose, external input pulses are either fed to the input of the chain, or the chain's own output pulses are fed back to the input of the same. the Output pulses can be picked up at the individual stages for any use. The single ones Steps in the chain consist of amplifier elements locked in the rest position, which also have Are locked using special switches. They are coupled to one another via resonant circuits. The oscillating circles are each caused by the pulse occurring at the output of the preceding amplifier element stimulated to vibrations that decay in a suitable manner, the decay being caused by special damping resistances is determined. The vibrations set in with such a phase position that during the second half-wave the following amplifier element can be made conductive, provided that it is also through the associated switch is unlocked. The oscillation now decays in such a way that the fourth half-wave, which occurs with the same polarity as the second has such a small amplitude that it is the following amplifier element can no longer make it conductive. The switches are controlled by a pulse, its Period sufficiently coincides with the transit time of a pulse between two stages and at which the phase position of the pulses is such that the unlocking time in the time of the control of the amplifier elements falls through the second half-times.

The present invention provides a particularly advantageous development of the one described above Maturity chain according to the main patent. These advantages are shown here only after the illustration and Explanation of the new arrangements according to the invention indicated, whereby a better recognition of the Benefits is made possible.

The circuit arrangement according to the invention is thereby characterized in that between the poles of the operating voltage source a switch operated by the controlling pulse, which is provided for all stages together, and the series connection for each stage a resonant circuit is connected to the emitter-collector path of a flat transistor, in such a way that that the oscillating current from the damping resistor of each oscillating circuit alternates depending on its direction via the base-emitter path of the connected transistor and via one between the base and the directional conductor lying at the pole of the operating voltage source that feeds the emitter.

According to a further embodiment of the invention, the is built up from individual stages
Maturity chain

Addendum to patent 968 127

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Otto Kneisel, Munich,
has been named as the inventor

pulse-controlled switch through a flat transistor shown, whose collector-emitter path acts as a switching path, with the control pulse of the base is fed. It is expediently built up here by means of two flat transistors Pulse generator delivered. In addition, according to a further embodiment of the invention, the second Pole of the operating voltage source for one or more Stages each via the emitter-base path of a dual transistor used in the stage be connected, which is switched so that power-amplified delay chain pulses at its collector are removable.

With reference to the drawing, the essence of the circuit arrangement according to the invention in the various Stages of their training explained. In detail shows or show

Fig. 1 shows an embodiment of the delay chain according to the invention using p-n-p junction transistors,

Fig. 2 shows the structure of one to be used for the chain Switch and an example of a pulse generator,

FIGS. 3a and 3b each show the structure of one stage of a chain using an additional output transistor to increase the power of the impulses,

4 shows the series connection of the output transistors of two different chains with a consumer.

The exemplary embodiment for the delay chain shown in FIG. 1 contains η amplifier stages. The first

809 560/162

Stage consists of your pnp transistor T 1, the resonant circuit coil Ll with a coupling winding, the resonant circuit capacitor C1, the damping resistor Rl and the directional conductor G 1. The others are accordingly. Levels built up. The emitters of the transistors are connected to ground via the common switch 5 *. The transistor of a certain stage, for example the transistor T 2, is coupled with the coupling winding located between the pole with the voltage - U of the operating voltage source and its collector to the coil L2 of the resonant circuit following in the chain and is controlled by the current of the damping resistor Rl of the preceding oscillating circuit in the chain. In the idle state, each transistor is blocked by means of the positive base bias voltage supplied by the terminal with the bias voltage -hUv via the relevant resonant circuit coil and the relevant damping resistor. The modes of operation of maturity chains shown and 16 of the main patent can be carried out with this chain.

■ · For the construction of the illustrated embodiment p-n-p transistors were used in the delay chain according to the invention. With the help of n-p-n transistors, where the operating voltages are required in reverse polarity, but which are otherwise in electrically analogous function can be used, a delay chain can be created accordingly build up. This can be particularly advantageous if two runtime chains are to work together, then with different. Transistors can be built.

In FIG. 2, a particularly advantageous one in cooperation with the delay chain according to the invention is shown Embodiment of the switch 5 "indicated. Er is formed by the transistor Tj in a common emitter circuit. The emitter of the transistor is connected to ground

Voltage drop in the forward direction at the rectifying potential. At the base, the conductors that lie between the bases and ground have a positive bias voltage + Uv across the in the idle state. Resistance ί? is sufficient to achieve the blocking safely. aside from that
each transistor in the cycle of the pulse generator P

the end. Therefore, the transistor is not conductive in the idle state and locks the transistors T 1 to Tn of the chain. From a pulse generator, which is constructed with the help of the two transistors TpI and Tp2 , negative pulses are fed through the capacitor C to the base of the transistor Ts , for the duration of which this is made conductive and the other transistors in the chain are unlocked. The pulse generator itself is

delivered pulse is locked and unlocked with the aid of the switch "S". A current can only flow through a transistor if the positive bias voltage is rendered ineffective and switch S is closed at the same time.

If so, like it in this circuit for example

is provided, is constructed from the last stage of the chain through 30 in a known manner. In the base-emitter the damping resistor Rn to the base of the Tran circuit of the transistor TpI is an oscillator sistorsTl of the first stage, a negative pulse flows from the emitter into the base of an injection current of defect electrons during the associated

circle in three-point circuit. The generated vibrations are cut with the help of the transistor Tp 2, which works as an amplitude limiter, and

the. Switch S. During this time, the transistor is conductive and a current pulse flows from the switch via the emitter-collector path of the transistor Tl and the coupling winding of the

Time span of unlocking the transistor by 35 corner pulses fed to the transistor Ts .

The decoupling of the occurring in the individual stages of the chain. Pulse can be done in several ways take place. Several methods have already been specified in the main patent that are also used here

CoilLl. The current pulse can initiate an oscillation, for example decoupling with the help of a force in the oscillating circuit from the coil L1 and the collector and oscillating circuit coupling capacitor C 1. If the decoupling transformer is appropriately selected, or if the coupling winding has a direct sense of winding, the first is from the collector, with one then positive between this and the half-wave of the oscillation. The resonant circuit coupling winding then flows, expediently, from the damping resistor R 1 via which another resistor is switched on. If the

head G 2 to ground. The next half-wave is negative, and the current associated with it during the unlocking time makes transistor T 2 conductive. This process corresponds to the previous making of the transistor Tl. It is made possible by the fact that, as already assumed, the pulse transit time between two stages is equal to the period of the pulse supplied by the pulse generator P and controlling the switch vS ". It can be seen that pulses The circuit shown in Fig. 3a is very advantageous. Only one stage of a delay chain is shown here of a dual transistor T 20 used in the chain stage is switched on

both half-waves of the oscillation can flow away, 55 use a power transistor. Whose collector is

one via the directional conductor G 2 and the other via the base-emitter path of the transistor T2. During this time the resistor R 1 acts as a damping resistor. There is therefore a damped and therefore decaying oscillation, which means that the next negative half-cycle of the same can no longer make the transistor conductive. The same process takes place in an analogous manner between the other stages of the runtime chain.

Instead of taking the pulses fed to the first stage of the chain from the last stage, they can also be taken from the pulse generator P from other, appropriately selected stages or via a pulse repetition frequency divider. Such procedures are already in the

Main patent indicated. The polarity in FIGS. 13, 14, 70 is also connected.

connected to the other pole of the operating voltage source via a load resistor R 20. The impulses can be picked up here by connecting the consumer to the collector, i.e. to terminal B, or by allowing the current flowing in the circuit shown through resistor R 20 to flow directly through the consumer. When the transistor T 2 is made conductive, its collector current flows through the base-emitter path of the transistor Γ20, so that it also becomes conductive and can emit an amplified pulse. In Fig. 3b, the corresponding stage of a chain with dual transistors is shown. It works exactly like that in Fig. 3a, only the operating voltage source is reversed

It arises if the emitters of the transistors used as switches Ts 2 and. Ts 3 is uniformly connected to ground in both different chains, so that the collectors of the transistors T 20 and T 30 used for decoupling both work via a resistor to ground. This enables a consumer V, as shown in FIG. 4, to be switched on between these collectors. These collectors then act as outputs from two different chains. A current can only flow through the consumer if the two transistors T 20 and T 30 are made conductive at the same time. Only in this case is the consumer supplied with c-in pulse. This circuit acts as a coincidence circuit without the use of additional switching elements being necessary. Such coincidence circuits are required for certain applications of delay chains.

In addition to the advantages known from transistors, such as the elimination of cathode heating, low heat generation, low space requirement, low operating efficiency, the use of flat transistors also has particular advantages here. In comparison to the circuit with tip transistors indicated in the main patent in FIG. 10, the directional conductors Gl'1, Gl'2 , etc. used there for the construction of coincidence circuits are saved here. The possibility of using dual transistors in the construction of delay chains, given here, allows a power transistor to be connected to any stage of the chain in a simple manner in order to decouple. To carry out impulses of this level. For some applications, pulses with a certain power are required. This method is particularly advantageous here. In addition, the delay chains themselves can be constructed in various ways with the aid of dual transistors. This results in the advantageous possibility of having the dual decoupling transistors work on a common load without using additional switching elements and thereby achieving the effect of a coincidence circuit. The control electrodes of these decoupling transistors, that is to say their bases, each have a potential which is close to that of the associated pole of the operating voltage source. This potential determines, among other things, the operating state of the relevant transistor. The voltage between the base and emitter of one decoupling transistor is independent of the operating state of the respective other transistor, since a fixed potential, namely one of the potentials of the poles of the operating voltage source, is present at each of the emitters. A disruptive reaction of these transistors to one another can therefore not take place. If, on the other hand, two similar output transistors connected in series were to work together, the emitter of one of the two transistors would inevitably not be able to be at a fixed potential.

Claims (4)

Patent claims: 1. Runtime chain built up from individual stages for the delivery of output pulses that can be removed from the individual stages, the individual stages consisting of amplifier elements locked in the rest position, which are coupled to one another via sufficiently damped resonant circuits in such a way that they can be controlled with the help of a controlling pulse when the respective second half-wave of the vibrations supplied by the circles can be unlocked after. Patent 958 127, characterized in that between the poles (- U, ground) of the operating voltage source, a switch (S) actuated by the controlling pulse, which is provided for all stages, and. The series connection of an oscillating circuit (L, C, R) with the emitter-collector path of a flat transistor (Tl, T2 ... Tn) is connected per stage, so that the oscillating current from the damping resistor (Rl, R2... Rn) each oscillating circuit, depending on its direction, alternately via the base-emitter path of the connected transistor (Tl, T2 ... Tn) and via one between the base and the one that feeds the emitter. Pole of the operating voltage source lying directional conductor (Gl, G2 ...) flows. 2. Delay chain according to claim 1, characterized in that the switch (S) contains the collector-emitter path of a flat transistor (T.?) As a switching path, which is controlled by a pulse fed to the base. 3. Time chain according to claim 2, characterized in that the pulse is supplied by a pulse generator (P) constructed with the aid of two flat transistors (TpI and Tp2). 4. Delay chain according to one of the preceding claims, characterized in that that pole (-U) of the operating voltage source which is not connected to the relevant transistor via the common switch (S) , in one or more stages, in each case via the emitter-base Path of a dual transistor (Γ20, T 30) used in the stage is connected, which is connected in such a way that power-amplified delay chain pulses can be tapped at its collector. Plierzu 1 sheet of drawings © 809 560/162 7.58