عمل المذبذب الأفقي .. كتاب التلفزيون الملون والعادي

Chapter sixteen

Horizontal Oscillator and AFC Circuit

16-1 The work of the horizontal oscillator:

The horizontal oscillator used in the horizontal deflection circuit is generally similar to the vertical oscillator in its operation. Both are barrier or multivibration oscillator types - in addition to that some horizontal deviation circuits use sinusoidal oscillators. In general, the horizontal oscillator of monochrome and color television are similar, although some color devices, as in the vertical deviation, have a special design.

Since the horizontal oscillator has a frequency greater than the vertical frequency by more than (300 times), this makes the problem of its stability more important and difficult. In addition to the problem of jamming pulses, which give false trigger signals to the horizontal oscillator, they may cover and confuse the synchronization pulses. While the vertical oscillator is not affected by the same amount because the vertical synchronization pulses enter through an integrated circuit which is itself a low-pass filter. Vertical synchronization pulses pass through this filter, the disturbance pulses that may accompany them are rejected by this filter, and never reach the vertical oscillator. While this form differs with the horizontal synchronization pulses, which enter through a differential circuit that represents a high-pass filtering circuit, thus the jamming pulses almost pass and are not rejected.

This serious problem is specific to the horizontal oscillator because it has a higher frequency, and the accompanying problem of stability and preservation of synchronization and frequency.

If the horizontal oscillator synchronization is made directly linked to the horizontal synchronization pulses, and this has been used sometimes in very old devices, then its stability is weak, because it is affected by distortion pulses that lead to a withdrawal in the image. It is tuned by the AFC automatic frequency control circuit, which in turn is tuned by the horizontal synchronization pulses and the same horizontal deviation wave. This indirect method of frequency tuning leads to an improvement in the stability of the horizontal oscillator and guarantees its immunity against being affected by interference pulses.

16-2 Basic Principle of Automatic Horizontal Frequency Control (AFC) Circuit:

The box diagram (Fig. 1-16) shows the horizontal deflection circuit, in which we find that the horizontal synchronization pulses coming from the synchronization separator (or the amplifier or the page reflector feed the AFC circuit. With these pulses and others, the oscillator can be determined if it is in its correct frequency or not, and if it is not Also, the AFC circuit creates a continuous DC voltage that is applied to the horizontal oscillator and returns it to its correct frequency.The oscillator generates the deflection voltage to pass to the output amplifier, and from there to the horizontal deflection coils.The deflection circuit performs its usual work, and we will investigate the extent of the effect of the distortion pulses on the work of the horizontal oscillator.
The effect of jamming pulses:

The synchronization pulses trigger and adjust the vertical and horizontal scanning oscillators, which move the electron beam across the surface of the screen. This method is the least expensive and the most simple, but it contains various disadvantages that may disturb the work of these circuits, and the biggest of these disadvantages is the vulnerability of this method to interference from nearby electrical equipment. The jamming pulses enter with the visual signal, and they may take the same amplitude and direction as the synchronization pulses, so they enter with them the same stages until they reach the horizontal oscillator, and their damage is greater when they are presented in the intervals between the synchronization pulses. more late. If this happens to the vertical oscillator, the image slides up or down until a correct synchronization pulse arrives and resets it. If this happens to the horizontal oscillator and it is triggered at the wrong time, narrow lines will cross or withdraw across the image, and when the interference is intense, the entire image will It mixes irregularly, and it has already been said: that the horizontal deviation circuit affected more in all cases of interference and interference

Working principle of AFC circuit:

The horizontal oscillator operates at a frequency of 15625 Hz. Then it has to synchronize the horizontal synchronization pulses coming to the composite visual signal. The circuit that performs the synchronization process between them is called the control circuit or the AFC circuit, the phase detector (Figure 2-16), or the discriminator. When there is a difference, it generates a continuous voltage that feeds back the oscillator, to change its frequency until it becomes exactly the same frequency as the synchronization pulses. DC voltage that rectifies the oscillator frequency and makes it synchronous

This continuous voltage passes through a filter whose time constant is large before it reaches the scanning oscillator, to control and adjust its frequency, and it can limit the effects of pulses only for relatively slow changes in the frequency of the synchronization pulses due to the effect on the scanning oscillator. Similar to what is in the vertical scanning system in the AFC circuit, this filter cannot be used directly in the horizontal circuit because it prevents the horizontal synchronization pulses as well as the jamming pulses from reaching the horizontal oscillator, and therefore we need an indirect way to achieve this. The methods used in AFC circuits are:


1 - Diode or silicon diode phase detector, Fig
(16-2).

2- A multi-vibrator with a cathode junction.