KR200161007Y1 - Circuit for switching simultaneously linear correction condenser and horizontal coil - Google Patents

Abstract

The present invention relates to a linearity correction capacitor and a horizontal coil simultaneous switching circuit for selectively switching a value of a horizontal coil and a value of a linearity correction capacitor (Cs) for compensating a slope of a resonance during scanning in a deflection circuit. .

Conventional linearity correction capacitors and horizontal coil switching circuits drive and switch one or more field effect transistors, thereby requiring expensive devices, and complicated circuits, resulting in a problem of reduced productivity.

In the present invention, when the coil value is changed by the driving of the relay according to the frequency to solve the above problems, the correction capacitor (Cs) can be simultaneously switched to the terminal of the relay through a circuit configuration, The relay is driven so that the coil and the linearity correction capacitor can be simultaneously switched.

Description

Linearity correction capacitor and horizontal coil simultaneous switching circuit.

The present invention relates to a linearity correction capacitor and a horizontal coil simultaneous switching circuit for selectively switching a value of a horizontal coil and a value of a linearity correction capacitor (Cs) for compensating a slope of a resonance during scanning in a deflection circuit. .

The structure of the linearity correction capacitor and the horizontal coil switching circuit in the conventional deflection circuit includes a transistor Q1 for switching the transformer T1 by switching on / off by receiving a horizontal driving voltage as a base as shown in FIG. A damping diode (D1) and a resonant capacitor (C1) connected to the collector terminal of the transistor (Q1), a horizontal deflection coil (H-DY1) for generating a horizontal deflection current in accordance with charging and discharging of the resonant capacitor (C1), Horizontal coils L1 and L2 for giving the coil value of the horizontal deflection coil H-DY1, Relay RL1 for selecting and determining the circuit connection of the coils L1 and L2, and an input frequency fh0. Circuit connection between transistor Q4 for switching relay RL1 to control relay RL1, linearity correction capacitors C2, C3 and C4 for correcting slope according to frequency, and capacitors C2 and C3. Gradient selection, which allows selection to compensate for skew Consists of a hip (1),

The inclination selection controller 1 is driven by transistors Q2 and Q3 that are switched on / off according to the input frequency and a power supply voltage B ₂ + that is transmitted in accordance with switching of the transistors Q2 and Q3. It is composed of field effect transistors FET1 and FET2.

Unexplained symbols R1 and R2 are resistors.

In the conventional switching circuit having such a configuration, the transistor Q1 is switched by receiving the horizontal driving voltage as a base, and the charge and discharge of the capacitor C1 and the horizontal deflection coil H-DY1 are switched when the transistor Q1 is switched. The horizontal output voltage Vp is generated in the transformer T1 by the energy of the horizontal coils L1 and L2.

The horizontal output voltage (Vcp) is The resonance time (Tr) for this is to be.

Here, the coil value L is the sum of the coil values of the horizontal deflection coils H-DY1 and the values of the configured horizontal coils L1 and L2, and C = C1 + C _F (C _F is the flyback transformer distribution capacity). to be.

At this time, the current i = flowing through the horizontal deflection coil H-DY1 The scanning time T _S may be obtained by subtracting the resonance time Tr from the total time.

The transistor Q4 is switched on and off by the input horizontal frequency fh0, so that the relay RL1 is driven to select the horizontal coils L1 and L2. Therefore, it is necessary to correct the slope according to the frequency,

As described above, the current i flowing in the horizontal deflection coil H-DY1 flows to the linearity correction port Port through the horizontal coils L1 and L2, and the resonance point of the scanning time is Ts = Where Ca is the sum of the linearity correction capacitors (Cs).

Therefore, the value of the correction capacitor Cs should be adjusted with respect to the frequency.

That is, the gradient selection control unit 1 with respect to the frequency to selectively adjust the values of the capacitors (C2, C3, C4),

The field effect transistors FET1 and FET2 of the slope selection control unit 1 are driven with respect to the input horizontal frequencies fh0 and fh1 to select the capacitors C2 and C3 to select and adjust the values of the correction capacitors Cs. Done.

When the horizontal frequency fh0 is low and the horizontal frequency fh1 is low, the transistors Q2 and Q3 are turned off, so that the power supply voltage B ₂ ^{+ is} applied to the gate of the field effect transistors FET1 and FET2. ) Is transferred to drive the field effect transistors FET1 and FET2, so that the capacitors C2 and C3 are selected to form the value of the correction capacitor Cs as the sum of the capacitors C4.

As shown in FIG. 2, when the horizontal frequency fh0 is low and the horizontal frequency fh1 is high, only the capacitor C2 is selected and the sum with the capacitor C4 is the correction capacitor Cs. Is the value of.

Here, when the horizontal frequency fh0 is high, the change in the coil value is such that the relay RL1 is connected to the coil L2 terminal so that the combined coil value of the horizontal coil becomes L1 + L2, and the horizontal frequency fh1. If low, the relay RL1 is short-circuited to the coil L2 terminal and the composite coil value of the horizontal coil is L1.

That is, the coil value is controlled according to the frequency.

However, such a conventional linearity correcting capacitor and a horizontal coil switching circuit drive and switch one or more field effect transistors, thereby requiring expensive elements, and complicated circuits, resulting in a problem of reduced productivity.

In the present invention, when the coil value is changed by the driving of the relay according to the frequency to solve the above problems, the correction capacitor (Cs) can be simultaneously switched to the terminal of the relay through a circuit configuration, The relay is driven so that the coil and the linearity correction capacitor can be simultaneously switched.

1 is a conventional linearity correction capacitor and a horizontal coil switching circuit diagram

2 is a diagram showing the combined capacitance of a correction capacitor Cs according to frequency in a conventional switching circuit.

3 is a circuit diagram of simultaneous linearity correction capacitor and horizontal coil switching

Figure 4 is a diagram showing the combined capacitance and the horizontal coil value of the correction capacitor (Cs) according to the frequency in the present invention

Referring to the configuration of the present invention with reference to Figure 3 as follows.

A transistor Q11 for switching the transformer T11 by switching the T11 on and off by receiving a horizontal driving voltage as a base; a damping diode D11 and a resonant capacitor C11 connected to a collector terminal of the transistor Q11; A horizontal deflection coil (H-DY11) for generating a horizontal deflection current according to charging and discharging of the capacitor (C11), horizontal coils (L11, L12) for giving a coil value of the horizontal deflection coil (H-DY11), and A linearity correction capacitor comprising, as a component, a relay RL11 for selecting and determining the circuit connection of the coils L11 and L12, and a transistor Q12 for switching the relay RL11 according to an input frequency fh0; In the horizontal coil switching circuit,

When the relay RL11 is switched, one terminal is connected to one of the linearity correcting capacitors Cs, C12, and the linearity correcting capacitors C12, C13, and C14 are connected to the input horizontal frequency fh1. Field effect transistors that drive the field effect transistor FET11 and are driven by switching control of the transistor Q13, and select the circuit configuration of the linearity correction capacitor C14 to correct the slope. It comprises a component of the transistor FET11.

The present invention simultaneous switching device having such a configuration is capable of simultaneously switching the values of the horizontal coil L11 + L12 and the correction capacitor Cs according to the frequency fh0 input as one relay RL11.

The relay RL11 has one side terminal A formed in the horizontal coil L12, and the terminal B formed in the correction capacitor C12. When the relay RL11 is driven and switched, the horizontal coil value and The correction capacitor value will fluctuate.

Referring to FIG. 4, when the horizontal frequency fh0 is input as high, the transistor Q12 is switched on so that a current flows in the relay RL11, so that the switch of the relay RL11 is connected to the terminal. Switch to A.

Since the switch of the relay RL11 is connected to the terminal A, the correction capacitor C12 is shorted to the circuit.

At this time, when the horizontal frequency fh1 is input as high, the transistor Q13 is switched on, and as the on-switched power supply voltage B ₂ ⁺ is not applied to the gate of the field effect transistor FET11, the field effect transistor is applied. (FET11) is turned off.

Since the field effect transistor FET11 is turned off, the correction capacitor C14 is shorted to the circuit.

That is, when both the horizontal frequencies fh0 and fh1 are high, the horizontal coil value becomes L11 + L12, and only the capacitor C13 is selected as the correction capacitor Cs.

On the other hand, when the horizontal frequency fh0 is low, the relay RL11 is turned off, connected to the B terminal, and the capacitor C12 is connected to the circuit.

At this time, when the horizontal frequency fh1 is low, since the transistor Q13 is turned off, the power supply voltage B ₂ ⁺ is supplied to the gate of the field effect transistor FET11, and the capacitor C14 connected to the drain is connected to the circuit. It is composed.

That is, when the horizontal frequencies fh0 and fh1 are all low, the correction capacitor Cs is selected for both C12, C13, and C14, and the horizontal coil value is made of only L11.

As described above, as the switching of the relay, at the same time by switching the horizontal coil value and the correction capacitor to correct the slope according to the frequency, there is an effect of improving the productivity and reliability of the device by simplifying the circuit configuration .

Claims (1)

In the linearity correction capacitor and the horizontal coil switching circuit to switch the horizontal coil value and the composite capacitance value of the linearity correction capacitor (Cs) according to the input frequency to correct the slope according to the frequency, One side terminal is connected to one of the linearity correcting capacitors (Cs), the relay (RL11) and the input horizontal frequency (fh0) to selectively switch the horizontal coil value and the value of the linearity correcting capacitor (Cs) In accordance with the transistor Q12, the linearity correction capacitors C12, C13, and C14, and the input horizontal frequency fh1 to control the field effect transistor FET11. Of the field effect transistor FET11 which is driven according to the switching control of the transistor Q13 and the transistor Q13 to select and determine the circuit configuration of one of the capacitors C14 of the linearity correction capacitor Cs. A linearity correction capacitor and a horizontal coil simultaneous switching circuit comprising a component.