DE1058549B - Self-oscillating multivibrator - Google Patents

Description

GERMAN

The invention relates to a flip-flop output stage for generating a sawtooth-shaped current for the deflection of an electron beam in a cathode ray tube for television sets. For cheaper of televisions, efforts are made to train the horizontal output stage as a self-oscillating device.

For a more detailed explanation, a known circuit is first described with reference to Fig. 1:

The tube Ro ₁ is the synchronizing tube and the tube Ro _{2 is} the horizontal end tube. The deflection coils 5 are coupled to this tube via the transformer Tr. Tube B is the booster tube and C _{3 is} the booster capacitor. A feedback winding L is mounted on the transformer, and the negative flyback pulses occurring on it are fed to the grid of the tube Ro _{2 via a capacitor C 2} and a variable resistor R ₁ , an integrated pulse voltage being produced at C _1. The period of oscillation of the self-oscillating multivibrator is determined by the time constant C ₁ , R ₁ . The capacitor C ₂ is used to automatically generate the grid bias of the tube Ro ₂ . It is considerably larger than the capacitor C ₁ . R _R is the grid leakage resistance of the self-oscillating multivibrator output stage

Applicant:

Community of interests

for broadcast protection rights G. m. b. H., (IGR), Düsseldorf, Am Wehrhahn 30

Dr. Hans-Werner Paehr, Bad Homburg vd Höhe,
has been named as the inventor

L ^ ₁ - Jl

Tube Ro ₂ . The synchronization takes place via the capacitor C ₄ on the screen grid of the tube Ro ₂ by means of pulses which come from the tube Ro ₁ , which in turn is controlled by positive pulses via the capacitor C ₅ as a synchronization amplifier or separation tube. R ₅ is the grid leakage resistance of the tube Ro ₁ . At the anode of this tube is the voltage divider from the resistors R ₃ and i? _4th In addition, the pulse voltage dropping across the screen grid resistor R _{2 of} the end tube Ro ₂ is applied to the anode of the pre-tube Ro _1.

In Fig. 2, the integrated pulse voltage that occurs across the capacitor C ₁ is shown as a function of time. The pulse voltage occurring across the resistor R ₆ is shown in Fig. 3 as a function of time.

The known circuit according to Fig. 1 has the disadvantage that no direct synchronization on the control grid of the tube Ro _{2 is} possible. In addition, the synchronization has the character of an edge synchronization. Often, however, an entrainment synchronization is desired in order to achieve synchronization within a certain range around the pulse frequency.

The invention consists in that in a self-oscillating multivibrator, the feedback winding L is switched between the capacitor C ₂ and the variable resistor R ₁ , that one end of the feedback coil L with one end of the resistor R ₁ , which is at the same time at the anode of Tube Ro ₁ is connected, with the other end of the resistor R _{1 connected} to ground. The other end of the coil L lies on one electrode of the capacitor C ₁ , the other electrode of which is connected to ground.

The circuit according to the invention is shown in Fig. 4, the same circuit parts in Fig. 1 and 4 have the same designation.

The tube Ro ₂ is again the flip-flop output stage, in whose output circuit the transformer Tr is located, via which the deflection coils 6 ″ are coupled. B is the booster tube and C _{3 is} the booster capacitor. R ₆ is the grid leakage resistance of the tube Ro ₂ , and C ₂ is used to generate the automatic bias for the tube Ro _2. The tube Ro ₁ is the synchronizing tube, which is controlled by positive pulses _{via the capacitor C 5.} R ₅ is the grid leakage resistance of this tube. In contrast to Fig. 1 the feedback coil L is now between the resistor R ₁ and the capacitor C _1. There is an alternating voltage at the resistor R ₁ , which is shown as a function of time in FIG the positive pulse peaks at the resistor _R1 facing the winding end of the feedback coil L are together. the synchronization of self-oscillating multivibrator by means of the tube through the ro ₁ flowing impulses. Only the positive peaks shown in FIG. 5 serve as anode voltage for the tube Ro ₁ , so that current can flow through the tube Ro ₁ only during these return peaks. These. Currents are superimposed on _{the feedback voltages at the capacitor C 1} , and a voltage curve over C ₁ results, which is shown in Fig. 6 as a function of

909 529/187

Time is drawn out in the non-synchronized case and shown in dashed lines in the synchronized case. The energy content of the synchronization pulses is used to adjust the waveform accordingly Maintain Fig. 6. This synchronization according to Fig. 4 does not have the character of edge synchronization, in which the multivibrator to be synchronized has a lower frequency than the synchronization pulses has the character of an entrainment synchronization in which the impulses the Flip-flop to be synchronized within a certain range around the pulse frequency take along.

Claims (1)

Claim: Self-oscillating flip-flop output stage for the generation of sawtooth-shaped currents for the deflection of the electron beam of a cathode ray tube in televisions with an output transformer using a feedback voltage which is taken from a separate winding of the output transformer and fed to the control grid via a low-pass filter consisting of a resistor and capacitor, characterized in that the feedback winding is switched into the low-pass filter formed by the capacitor (C ₁ ) and the resistor (R ₁ ) in such a way that one end of the winding connects to one end of the resistor (R ₁ ), at which the anode of the synchronizing tube (Ro ₁ ) is connected, the other end of the resistor (R ₁ ) being connected to ground, and that the other end of the feedback coil (L) is connected to the one assignment of the capacitor (C ₁ ), the other end of which is connected to ground and that also the pulse voltage taken from the output transformer Annung is used as the anode voltage of the synchronizing tube. 1 sheet of drawings © 909 529/187 5.59