DE1935210A1 - Transistor oscillator - Google Patents

Description

Transistor Oscillator The invention relates to a transistor oscillator in emitter circuit with strong inductive, aperiodic feedback between Collector circuit and base circuit for generating a stable pulse voltage.

It is known to avoid such transistor oscillators a dependence of the pulse voltage on the operating voltage of the base additional, the feedback opposite voltage via a further inductive Feed coupling that contains a Zener diode and a rectifier in series (DAS i'134 705). Zener diode and rectifier prevent interference there incorrectly polarized voltages that reach the base via the further inductive coupling could.

The invention is based on the object of stabilizing the To achieve pulse voltage against operating voltage fluctuations with little effort.

The invention consists in that: collector and base electrodes through a negative feedback capacitor are connected.

In a tried and tested embodiment, the is through a Zener diode limited pulse voltage from the collector across the capacitor to the connection point fed into the base with a base resistor.

To explain the invention in more detail, an exemplary embodiment is given below described on the basis of the drawing. This shows in 1 shows a circuit according to the invention Fig. 2 curves of the pulse voltage as a function of the operating DC voltage 3 to 5 oscillograms of the circuit shown in FIG.

In Fig. 1, a transsitor 1 (e.g. AC li7) is shown whose emitter connected to ground via a fixed resistor 2 and its collector and base via the primary winding 3 or via the secondary winding 4 of a transformer 5 are connected to the DC operating voltage UB = -2.4 V. Between base and Secondary winding 4, a decoupling resistor 6 is switched on. ie limiter resistors 7.8 in series with the secondary winding 4 are also used to generate a bias voltage for the base. The operating voltage source UB is by means of a capacitor 9 according to Mass blocked. The collector is connected to ground via a zener diode. The collector and base are connected to one another via a negative feedback capacitor 11. A high voltage is generated with the aid of a high-voltage winding 12, which is inductively connected the primary winding 3 is coupled, and generated with subsequent cascade stages 13.

The degree of feedback is due to the gear ratio of the Transformer 5 chosen so that the oscillator stage is heavily overdriven. Included a pulse with a steep rising edge results at the collector of the oscillator stage. The base bias is set automatically with the help of the base current through the resistors 7.8 generated. The small resistor 2 in the emitter ensures thermal stability the circuit.

A constant amplitude of the pulse in the event of fluctuations in the DC operating voltage To get the resulting impulse on the collector with the help of a Zener diode limited. There can be no greater voltage of the impulse than the Zener voltage at the collector develop. A good stability of the high voltage is already achieved by this measure. The negative feedback via the capacitor 11 is more effective at higher frequencies. It will be there.

with a flattening of the leading edge of the pulse and the oscillation process is strongly damped.

Some curves from measurements of the high voltage at the output of a four-stage cascade as a function of the DC operating voltage are shown in FIG. (Oscillator frequency f = 2 KHz). Curve A shows the high voltage at the output of the cascade as a function of the voltage UB without limitation with Zener diode 10 and without negative feedback capacitor 11 (unregulated). Curve B shows a curve with an amplitude limitation by the Zener diode 10 but without negative feedback. Curve C shows a curve with Zener diode 10 and connected negative feedback capacitor 11 (4.7 nF). You can see the significant one Improvement of the stability of the high voltage against fluctuations in the DC operating voltage due to the introduced negative feedback. This negative feedback creates stability the high voltage of approx. 2% with a fluctuation in the DC operating voltage of 1.5 to 3 V (100%) reached.

Achieved with amplitude limitation with the help of a Zener diode alone a high-voltage stability of approx. 10% with the specified operating DC voltage fluctuations (UB = 1.5 - 3 V).

The measurement was always carried out while the cascade was idling. Fig. 3 shows for three operating voltages the pulse at the collector without and with negative feedback (C1l = 3,000 pF); Fig. 4 shows the pulse at the base with and without negative feedback (C1l = 3 000 pF), each 1 cm 40 Zs.

A preferred field of application is the power supply of cathode ray tubes, especially image intensifiers. In a tried and tested embodiment, the Circuit elements used following rating secondary winding 4 20 turns .0.3 Cul primary winding 3 10 turns 0.3 Cul secondary winding 12 2,000 turns 0.07 Cul transformer 5 pot core: 36 x 22/2000 T26; AL 1600 transistor 1 AC 117 resistor 6 10 resistance 7 Resistor 8 50 Resistor 2 0.5 Capacitor 11 4.7 nF Capacitor 9 50 AP Zener diode 10 BZY 85 / C 18

Claims (4)

Claims%). Transistor oscillator in common emitter circuit with strong inductive aperiodic feedback between collector circuit and base circuit for Generation of a stable pulse voltage in the collector circuit, characterized in that that the collector and base electrodes are connected by a negative feedback capacitor (11) are. 2. transistor oscillator according to claim 1, characterized in that between the connection point of the capacitor (11) with the base electrode on the one hand and the feedback coil (4) in the base circuit has a decoupling resistor (6) switched on is. 3. Transistor oscillator according to claim 1 or 2, characterized in that that the end of the feedback coil (4) facing away from the base electrode with a Reference voltage UB is connected via a limiting resistor (7,8). 4. transistor oscillator according to one of claims 1 to 3, characterized characterized in that to limit the amplitude of the pulse voltage from the collector after Ground a Zener diode (10) is connected. L e r s e i t e