KR20010010980A - Horizontal linearity compensating circuit in a monitor - Google Patents

Abstract

PURPOSE: A circuit for compensating a horizontal linearity of a monitor is provided to vary a current flowing into one horizontal linearity coil by a micro controller(MCU) of the monitor, to compensate horizontal linearity according to horizontal frequencies, so as to stably and exactly compensate horizontal linearity in accordance with low-resolution or high-resolution horizontal frequencies. CONSTITUTION: A second coil of a current driving horizontal linearity coil(L5) is connected between a horizontal deflection yoke coil(L2) and a Cs compensating capacitor(C3). If a current and a magnetic field applied to the second coil are changed, according to a driving process of a linearity coil driving transistor(Q2), the current driving horizontal linearity coil(L5) compensates horizontal linearities according to horizontal frequencies, and maintains balance of a horizontal left/right screen. A micro controller(MCU)(10) outputs different pulse width modulation(PWM) control signals according to the horizontal frequencies, to compensate the horizontal linearity. A resistor condenser(RC) integrated circuit(IC)(20) integrates the PWM control signals, and makes the PWM control signals predetermined direct current(DC) voltages. A linearity coil driving transistor(Q2) is driven, when the DC voltages are applied to a base through a current controlling resistor(R2).

Description

Horizontal linearity compensating circuit in a monitor}

The present invention relates to a horizontal linearity compensation circuit of a monitor, and more particularly, to a horizontal linearity compensation circuit of a monitor configured to compensate horizontal linearity for each horizontal frequency by the monitor's MCU.

In general, the conventional monitor uses a horizontal linearity compensation circuit to balance the screen displayed on the left and right sides around the center of the CRT.

For example, the conventional LOW-END monitor, which is a low resolution monitor, is formed by a magnetic field formed in accordance with the current flowing in L3 by adding one horizontal linearity coil L3 with a magnet to a horizontal deflection circuit as shown in FIG. The balance of the horizontal left and right screens is maintained.

However, the conventional LOW-END monitor configured to compensate for the horizontal linearity using only one horizontal linearity coil L3 as described above has a disadvantage in that the horizontal linearity cannot be compensated when the horizontal frequency becomes 60 Hz or higher indicating high resolution characteristics.

On the other hand, the conventional high-end monitor, which is a high-resolution monitor of 60 KHz or more, adds two horizontal linearity coils L3 and L4 with magnets to a horizontal deflection circuit as shown in FIG. 2, and two horizontal linearity coils L3 and L4. By selectively switching to switch SW1 according to the horizontal frequency, the magnetic field formed according to the current flowing through L3 and L4 maintains the balance between the horizontal resolution of the horizontal left and right screens for the low resolution horizontal frequency and the high resolution horizontal frequency of 60KHz or more. have.

However, the conventional HIGH-END monitor, which uses two horizontal linearity coils L3 and L4 to compensate for horizontal linearity for low resolution and high resolution horizontal frequency, uses two horizontal linearity coils and separate switching means. There is a disadvantage in terms of cost because it must be used.

1 and 2, L1 is a horizontal drive transformer which outputs a horizontal drive voltage by a horizontal drive pulse, R1 and C1 are horizontal drive current control elements, and Q1 is a horizontal output transistor.

In addition, the horizontal output signal output through the collector of Q1 is applied to the horizontal deflection yoke coil L2 via the damping diode D1 and the resonant capacitor C2.

At this time, C3, which is connected in series with the horizontal deflection yoke coil L2 and the horizontal linearity coil L3, is a Cs correction capacitor.

Accordingly, the present invention is to overcome the above-mentioned conventional problems, and an object of the present invention is to use a single horizontal linearity coil and vary the current flowing through the one horizontal linearity coil by the monitor's MCU to change the low resolution horizontal frequency. It is to provide a horizontal linear compensation circuit of the monitor to compensate for both horizontal linearity according to the high resolution horizontal frequency.

The horizontal linearity compensation circuit of the monitor for achieving the object of the present invention is a horizontal deflection yoke via the damping diode D1 and the resonant capacitor C2 when the horizontal output transistor outputs the horizontal output signal as the horizontal drive transformer outputs the horizontal drive voltage. A horizontal deflection circuit configured to send a horizontal deflection current to a Cs correction capacitor connected in series to a coil L2 and the horizontal deflection yoke coil L2,

As the secondary coil is connected between the horizontal deflection yoke coil and the Cs correction capacitor and the linear coil driving transistor is driven, if the current and the magnetic field applied to the secondary coil are changed, the horizontal linearity is compensated differently for each horizontal frequency. Integrating a current-driven horizontal linearity coil to maintain the balance, a PWM for outputting a different PWM control signal for each horizontal frequency to compensate for the horizontal linearity, and a PWM control signal output from the MCU to convert a predetermined DC voltage An RC integrating circuit and a linearity coil driving transistor for driving when a DC voltage output from the RC integrating circuit is applied to the base through a current control resistor.

In the horizontal linearity compensation circuit of the monitor according to the above configuration, when the MCU outputs different PWM control signals for each horizontal frequency in order to compensate for horizontal linearity, the RC integrating circuit integrates the PWM control signal to provide a predetermined DC. When the voltage is applied and the DC voltage of the RC integrating circuit is applied to the base through the current control resistor, the linearity coil driving transistor varies the current flowing from the collector to the emitter to change the current and the magnetic field applied to the horizontal linearity coil. The horizontal linearity is compensated differently for each horizontal frequency to maintain the balance of the horizontal screen.

1 is a circuit diagram showing a horizontal deflection circuit equipped with a horizontal linearity compensation circuit for a conventional low resolution monitor;

2 is a circuit diagram showing a horizontal deflection circuit equipped with a horizontal linearity compensation circuit for a conventional high resolution monitor;

Figure 3 is a circuit diagram showing a horizontal deflection circuit with a horizontal linearity compensation circuit of the monitor according to the present invention.

<Explanation of symbols for main parts of drawing>

10: MCU 20: RC Integral Circuit

R1, R2, R3: Resistor C1, C2, C3, C4: Capacitor

D1: Diode Q1, Q2: Transistor

L1, L2, L3, L4, L5: Transformer

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 3, the MCU 10 outputs different PWM control signals for each horizontal frequency to compensate for horizontal linearity.

The RC integrating circuit 20 integrates the PWM control signal output from the MCU 10 to make a predetermined DC voltage.

In the present invention, the DC voltage output through the resistor R3 and the capacitor C4 of the RC integrating circuit 20 is variable from 0 to 5V.

The linearity coil driving transistor Q2 drives when a predetermined DC voltage output from the RC integrating circuit 20 is applied to the base through the current control resistor R2 to vary the current flowing from the collector to the emitter.

The horizontal linearity coil L5 is a current-driven coil in which a secondary coil is connected between the horizontal deflection yoke coil L2 and the Cs correction capacitor C3. As the linearity coil driving transistor Q2 is driven, the secondary linear coil L5 is driven. When the current and the magnetic field applied to the side coil change, the horizontal linearity is compensated differently for each horizontal frequency to maintain the balance of the horizontal left and right screens.

In Fig. 3, L1 is a horizontal drive transformer that outputs a horizontal drive voltage by a horizontal drive pulse, R1 and C1 are horizontal drive current control elements, and Q1 is a horizontal output transistor.

In addition, the horizontal output signal output through the collector of Q1 is applied to the horizontal deflection yoke coil L2 via the damping diode D1 and the resonant capacitor C2.

At this time, C3 connected in series with the secondary coil of the horizontal deflection yoke coil L2 and the horizontal linearity coil L5 is a Cs correction capacitor.

With the above configuration, the horizontal linearity compensation circuit of the monitor according to the present invention operates as follows.

When the MCU 10 determines the video mode and outputs a PWM control signal for compensating for the horizontal linearity with respect to the low resolution horizontal frequency, the RC integrating circuit 20 integrates the PWM control signal and converts the predetermined DC voltage into 0 to 0 ~. A DC voltage for a predetermined low resolution horizontal frequency that is variable within a range up to 5V is output.

In addition, when the DC voltage for the low resolution horizontal frequency output from the RC integrating circuit 20 is applied to the base of the linearity coil driving transistor Q2 through the current control resistor R2, the linearity coil driving transistor Q2 flows from the collector to the emitter. To vary the current and magnetic field applied to the horizontal linearity coil L5.

Accordingly, the horizontal linearity coil L5 compensates the horizontal linearity with respect to the low resolution horizontal frequency to maintain the balance of the horizontal left and right screens.

On the contrary, when the MCU 10 determines a video mode and outputs a PWM control signal for compensating horizontal linearity with respect to a high resolution horizontal frequency, the RC integrating circuit 20 integrates the PWM control signal and converts it into a predetermined DC voltage. A DC voltage for a predetermined high resolution horizontal frequency that is variable within the range of 0 to 5V is output.

In addition, when the DC voltage for the high resolution horizontal frequency output from the RC integrating circuit 20 is applied to the base of the linearity coil driving transistor Q2 through the current control resistor R2, the linearity coil driving transistor Q2 flows from the collector to the emitter. To vary the current and magnetic field applied to the horizontal linearity coil L5.

Accordingly, the horizontal linearity coil L5 compensates the horizontal linearity with respect to the high resolution horizontal frequency to maintain the balance of the horizontal left and right screens.

As described above, since the horizontal linearity compensation circuit of the monitor according to the present invention is configured to compensate horizontal linearity for each horizontal frequency by varying the current flowing through one horizontal linearity coil by the MCU of the monitor, not only a low resolution but also a high resolution horizontal frequency It is possible to implement a circuit capable of compensating for both stable and accurate horizontal linearity at low cost.

What has been described above is only one embodiment for implementing the horizontal linearity compensation circuit of the monitor according to the present invention, and the present invention is not limited to the above-described embodiment, but the present invention claims in the following claims. Various changes can be made by those skilled in the art without departing from the gist of the present invention.

Claims (1)

As the horizontal driving transformer L1 outputs the horizontal driving voltage, the horizontal output transistor Q1 outputs the horizontal output signal to the horizontal deflection yoke coil L2 and the horizontal deflection yoke coil L2 via the damping diode D1 and the resonant capacitor C2. In a horizontal deflection circuit configured to send a horizontal deflection current to a Cs correction capacitor C3 connected in series, When the secondary coil is connected between the horizontal deflection yoke coil L2 and the Cs correction capacitor C3 and the linear coil driving transistor Q2 is driven, the current and the magnetic field applied to the secondary coil change for each horizontal frequency. A current-driven horizontal linearity coil L5 for compensating horizontal linearity differently to maintain the balance of the horizontal left and right screens; MCU 10 for outputting a different PWM control signal for each horizontal frequency to compensate for the horizontal linearity, An RC integrating circuit 20 for integrating a PWM control signal output from the MCU 10 to a predetermined DC voltage, and The linearity coil driving transistor Q2 is driven when the DC voltage output from the RC integrating circuit 20 is applied to the base through the current control resistor R2. Horizontal linearity compensation circuit of the monitor, characterized in that consisting of.