DE3129523C2 - Multi-stage square-wave amplifier circuit - Google Patents

Abstract

Each stage of the amplifier circuit, in which, in a known manner, several transistors with their emitter-collector paths in the same direction one behind the other and with the load resistor in series are applied to the DC supply voltage source and the first transistor with its control circuit is applied to the control pulse source, has according to the invention as an auxiliary voltage source a capacitor which, when the step transistor is unblocked, supplies the control current to unblock the downstream stage and, when the step transistor is blocked, the bias voltage required for rapid discharge of charge carriers. The capacitors are charged to the prescribed partial voltages during the pulse pauses via a voltage divider, which includes the emitter resistance and at least parts of the collector resistances of the stages. The auxiliary current that the circuit according to the invention requires is much weaker than the current through a voltage divider permanently connected to the DC supply voltage source, used in a known circuit, at which the control voltages required for evenly distributing the output voltage to the individual stages are tapped, so that, in contrast, there is a better degree of efficiency. The acceleration of the charge carrier outflow after the termination of the control pulse increases the edge steepness of the output pulses and thus improves the transmission quality of the amplifier circuit. The circuit is used after

Description

transistor and part of the collector resistor bridging resistor and the Emitterwiderstai.d of the step transistor consists, and that the series connection of parts of all resistor groups together with the load resistor, a voltage divider connected to the DC supply voltage source forms so that the capacitors on this voltage divider during the pulse pauses one of the voltage divider ratio and the load resistance specified part of the DC supply voltage.

The voltage at the amplifier output is thus also applied to the individual at any point in time Amplifier stages evenly distributed. The current output potential of an amplifier stage is included at the same time the ground or reference potential of the downstream stage (harmonica circuit). The one when blocked of the step transistor to its collector via a ', switching transistor supplied bias voltage is used -? fast discharge of the load carriers.

From a different context, namely with a control circuit with positive and negative output current and, downstream push-pull power output stages, especially for vertical deflection circuits of television receivers, it is known from DE-OS 27 53 126, as an auxiliary voltage source Provide a capacitor that, when the one belonging to the push-pull power output stage is unlocked Transistor supplies the control current for it.

The invention and further developments thereof are explained below using an exemplary embodiment shown in three figures. The F i g. 1 to 3 form a single circuit and must be joined together. The multi-stage amplifier shown in the figures is intended to amplify square-wave pulses with an amplitude of 18 V. * s to 1.8 kV at a load resistor Rl of 3 kΩ with a parallel capacitance of 170 pF. The duration of the pulses to be amplified should be 30 ... 70 μ5 and their duty cycle should be 1:20 to 1:10. When changing the pulse duration and / or the duty cycle, the base point potential and the amplitude of the output pulses should remain constant. The amplifier stages are galvanically coupled for this purpose

Because the required output amplitude is a multiple of the maximum permissible collector-emitter voltage suitable available transistors, the output voltage will be uniform at all times eight amplifier stages 1 to 8 distributed in emitter circuit. This is the current output potential an amplifier stage at the same time the base or reference potential of the downstream; Level (»harmonica principle«).

The pulses at the amplifier output should be positive. Therefore, pnp transistors, which are only unlocked for the duration of the pulses and thereby emit positive pulses at the collector, are expediently used as step transistors 71 to 78 for amplification. During the much longer pauses between the pulses, the pnp transistors 71 to 78 are blocked, whereby an unnecessary load on the supply voltage source U is avoided.

If the transistors 71 to Ti are blocked, a quiescent current flows through the series-connected. Routes that each stage from the emitter resistor R 1 of z. B. 27 Ω, as well as the blocked step transistor bridging series connection of a resistor R 2 of, for example, 56 kO and a collector part resistor R 3 of z. B. 330 Ω exist. This quiescent current also flows through the load resistance Ri. Of 3 kΩ. Thus, the emitter-collector voltage at each pnp step transistor Ti to Ti is a little less than 1/8 of the DC supply voltage U of z. B. 2 kV. Charging capacitors C of 2.2 μΡ, for example, are charged to the same partial voltages in each amplifier stage.

Now the step transistor Ti of the first amplifier stage 1 through one of its base from the input

ι » E supplied negative square-wave control pulse 5 / unlocked, so flows from the charging capacitor C of this stage 1 current via the first emitter resistor R 1, the emitter-collector path and the collector resistance, which consists of the resistors R 3, R 4 of z . B. 82 Ω and 7? 5 of z. B. 2.2 kΩ, as well as the parallel to the resistor A3 in series with the second emitter resistor R 1 lying emitter-base path of the pnp stage transistor 72 of the second amplifier 2, whereby this transistor 72 is also unlocked.

'Between its collector and the tap between the two resistors R 4 and Λ 5 on the collector resistance of the first stage 1 there is a diode D !, which becomes conductive as soon as the base-collector voltage in amplifier stage 2 falls below a certain value. Then that of the Sasis des is diminished

. Current supplied to transistor 72, thereby preventing transistor 72 from being driven into saturation.
The pnp step transistors are made in the same way

ίο 73 to 78 of the amplifier stages 3 to 8 unlocked and saved from being controlled into saturation. The saturation of the step transistor 71 is prevented with the help of a diode D 1, which is between the collector of 71 and an auxiliary DC voltage source Ux of, for example -24 V and becomes conductive as soon as the unlocking of the amplifier stage 1, the collector potential of the potential has reached the negative terminal of the auxiliary DC voltage source U \ . Then the diode D 1 prevents a further increase in the collector potential of the

ίο transistor 71, so that its base-collector voltage cannot fall below a certain value that depends on the difference between the amplitude of the negative square-wave control pulse 5 / and the auxiliary DC voltage Ux.

If the amplifier transistors 71 to 78 of all stages 1 to 8 are unlocked, then each of these transistors Ti to 78 besides the base current of the respective downstream transistor supplied by the charging capacitor C flows through the emitter-collector path

- ■ 'current supplied by the supply voltage source U of several magnitudes through the load resistor Rl, the potential at the amplifier output A increases accordingly.
After termination of the negative input pulse 5 /, the pnp step transistor 71 of the amplifier stage 1 first blocks. As a result, the pnp step transistor 72 of the amplifier stage 2 no longer receives a base current and also blocks. Amplifier stages 3 to 8 are now blocked in the same way. The potential at the amplifier output A thus falls back to the value it had before the start of the pulse.

A sufficiently steeply falling edge of the output pulse is achieved in that in each amplifier stage 1 to 8 the outflow of charge carriers from the transition zone between the base and the collector of the respective pnp step transistor 71 to 78 is accelerated with the aid of an npn switching transistor 79 to 716 whose collector each has one of one

BUNDESORUCKEREI 12. 83 308 163/279

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Inductance L of ζ. Β. 6 μΗ and a resistor R 6 of z. B. 27 Ω existing series circuit with the collector of the pnp step transistor 71 to 78 and its emitter is connected to the negative pole of the charging capacitor C , for example designed as an electrolytic capacitor. The base of each of these switching transistors 79 to 716, which act as "clearing transistors", is connected to the emitter of the respective pnp step transistor 71 to 78 via a capacitor Ci of, for example, 30nF. If the step transistors 71 to 78, 'are blocked, the. Switching transistors 79 to 716 receive a positive control pulse, are thereby unlocked and pull the collector potential of the respective step transistor 71 to 78 down via the inductance L and the resistor β 6.

Immediately after the start of this lowering of the collector potential, the step transistor of the downstream stage must already be completely blocked * so that the falling edge of the output pulse runs cleanly and in a straight line, ie without superimposed oscillations. Such a lock that will last until the end of the. The lowering of the collector potential is caused by a capacitor C2 of, for example, 1 η F, connected to the base of the downstream step transistor, which is charged during the pulse via a resistor R 7 of, for example, 22 kΩ and, after the end of the pulse, is discharged via a diode connected in parallel with this resistor Rl . In parallel with the resistor R and the diode D 2 is connected yet ejn capacitor C3 for example 15ÖpF. Part of the discharge current flows through the partial collector resistor R 3 of the respective upstream amplifier stage and there generates the voltage required to block the downstream Toi stage transistor.
'; The step-and Schalttransistoreh 71-716 are η- jdurch anti-parallel to their base-emitter junctions' connected diodes D3 and DA protected against excessive blocking pulses

After the end of the pulse, the charging capacitors C are ayfladen again. In order to accelerate the charging process, the partial resistances R 4 and R 5 of the electrical resistances are bridged by diodes £> 5.

Above the levels 1 to 8, the pulses pending at their inputs are shown in the figure. It can be seen from this that the pulse amplitude increases uniformly from step to step, and the desired pulse of 1.8 at output A of the entire amplifier circuit

For this purpose 3 sheets of drawings

Claims (5)

Patent claims: 1. Multi-stage square-wave amplifier circuit using a number of step transistors which are connected with their emitter-collector paths in the same direction one behind the other and with a load resistor in series with a DC supply voltage source and the first of which is connected to a control pulse source with its control circuit in such a way that it is at The occurrence of a control pulse is unlocked and is locked at the end of a control pulse, characterized in that each stage (1 to 8) has a capacitor (C) as an auxiliary voltage source which, when the step transistor (Ti to 78) is unlocked, the control current to unlock the step transistor ( Ti to 78) of the respective downstream stage and when the stage transi- ^ stors (Ti to Γ8) supplies a bias voltage to the collector of this .-, 'transistor via a switching transistor (T9 to 716) and which is connected in parallel to a resistor group (Ri, R 2, R 3, R 4, RS) , which consists of the collector resistor divided into partial resistances (R 3, R 4, RS) , a resistor (R 2) bridging the emitter-collector path of the respective step transistor (Ti to 78) and a partial resistor (R 3) of the collector resistor the emitter resistor (R 1) of the step transistor (Ti to 78), and that the series connection of parts (R 1, R2, A3) of all resistor groups together with the load resistor (Rl) forms a voltage divider connected to the DC supply voltage source (U), so that the capacitors (C) are charged via this voltage divider to a part of the DC supply voltage determined by the voltage divider ratio and the load resistor (Rt.) during the pulse pauses. 2. Multi-stage square-wave amplifier circuit according to claim 1, characterized in that the stage transistor (Ti to 78) and the switching transistor (T9 to 716) of each stage (1 to 8) are of different conductivity types. 3. Multi-stage rectangular pulse amplifier circuit according to claim 1 or 2, characterized in that with the base of each stage transistor (T2 to 78) with the exception of that in the first stage, one electrode of a capacitor (C 2) is connected, the other electrode of which is connected via a resistor (R7) and a diode (D2) connected in parallel to the emitter of the switching transistor (T9 to 715) of the upstream stage (1 to 7). 4. Multi-stage square-wave amplifier circuit according to one of the preceding claims, characterized in that between the collector of each stage transistor (T2 to 78) - with the exception of that in the first stage - and a tap (R 4 / R 5) on the collector resistor (R 3 , R 4, RS) of the upstream amplifier stage (1 to 7) has a diode (D i) . 5. Multi-stage square-wave amplifier circuit according to one of the preceding claims, characterized in that parts of the collector resistance (R 4, RS) of each stage transistor (Ti to 78) are bridged by a respective diode (DS). The invention relates to a multi-stage square-wave amplifier circuit using a number of step transistors with their emitter-collector paths in the same direction one behind the other and are connected in series to a DC supply voltage source with a load resistor and the first of which is connected to a control pulse source with its control circuit in such a way that when a Each control pulse is unlocked and blocked when a control pulse ends. If square-wave pulses of constant amplitude are to be amplified in such a way that the Pulse voltage amplitude a multiple of the maximum permissible collector-emitter voltage available Transistors is and the base point potential as well as the pulse voltage amplitude when changing the pulse duration and / or the duty cycle remain constant, then it is from DE-PS 10 21926 known several transistors with their emitter-colilector paths in the same direction with one another and with the load resistor in series with the supply current source to put on. The control circuit of the first transistor is at the output of the square-wave pulse generator, and the base electrodes of the series-connected transistors are tapped of a voltage divider connected with its end connections to the supply current source of the system lies. If the first transistor is unlocked by the control pulse, the voltage divider flows through the Base-emitter path of the second transistor to the collector of the first transistor a current that the second transistor unlocked. The following transistors are also unlocked, so that finally on Load resistance drops a voltage that is approximately is equal to the sum of the collector-emitter voltages when the transistors are blocked. Will with termination of the control pulse the first transistor is blocked, the second and all subsequent transistors also block, so that no more current flows through the load resistor and the voltage of the supply current source is uniform is distributed to the collector-emitter path of the transistors. In this known circuit flows constantly a relatively large auxiliary current through the permanently connected to the supply current source Voltage divider, on which the for uniform Distribution of the output voltage to the individual Levels required control voltages are tapped. The object of the invention is in a multi-stage Square-wave amplifier circuit of the aforementioned Way of increasing the efficiency compared to the known circuit with a fixed voltage divider, i.e. to lower the constantly flowing auxiliary current required for transistor control and at the same time the transmission quality by increasing the steepness of the falling edges of the pulses at the amplifier output to improve. According to the invention, this object is achieved in that each stage as an auxiliary voltage source Has capacitor which, when the step transistor is unlocked, the control current to unlock the Step transistor of the respective downstream step and, when the step transistor is blocked, one of the collector this transistor supplies bias voltage supplied via a switching transistor and the parallel to a Resistance group is connected, which consists of the collector resistance divided into several partial resistances, one the emitter-collector path of the step