KR200153719Y1 - A circuit for compensating tilt in a monitor - Google Patents

Abstract

The present invention relates to a tilt correction circuit of a monitor for correcting a screen tilt caused by a process or a geomagnetic field in a color picture tube (CPT) or a color display tube (CDT).

The tilt correction circuit of the present invention includes a rotation coil L _ROT , a first amplifier 310 for amplifying the tilt control signal input from the microcomputer, and a second amplifier for amplifying the tilt control signal input from the micon. A first push-pull amplifier 330 for driving a current flowing in the rotation coil L _ROT according to the output of the first amplifier 310 and the unit 320 and a single voltage Vcc, A voltage Vcc is applied and is configured as a second push-pull amplifier 340 that drives a current flowing through the rotation coil L _ROT according to the output of the second amplifier 320.

Therefore, the tilt correction circuit according to the present invention has the effect of obtaining the same swing width as using a positive voltage (+ Vcc, -Vcc) while using a single voltage (Vcc).

Description

Tilt Correction Circuit of Monitor

The present invention relates to a tilt correction circuit of a monitor for correcting a screen tilt (hereinafter referred to as tilt) generated during the manufacturing process or by a geomagnetic field in a color picture tube (CPT) or a color display tube (CDT). will be.

In general, a color display device focuses and accelerates hot electrons emitted from R (Red), G (Green), and B (Blue) electron guns, and collides with R, G, and B fluorescent surfaces through a point on a shadow mask to form pixels. In addition, the sawtooth current flows through the vertical and horizontal deflection coils to form a two-dimensional screen.

Since the color display device requires very precise operation to form a high density pixel on a narrow screen, various correction devices such as purity magnets and convergence magnets are mounted on the neck portion of the CRT. In order to prevent deterioration in image quality, element coils are provided on the panel of the CRT.

Figure 1 shows the structure of a general CRT. In FIG. 1, the CRT is composed of a base 1, an electron gun 2, a neck 3, a corner 4, a panel 5, a shadow mask 8, a fluorescent plate 7 and the like.

Here, the base 1 is for connecting an electrical signal to the CRT, and the neck 3 has an electron gun 2 for forming R, G, and B electron beams, which are emitted from the electron gun 2 to focus and The accelerated electron beam is focused on the shadow mask 8 and then impinges on the fluorescent surface 7.

In this general CRT, the display surface and the shadow mask 8 do not coincide in the manufacturing process, so that the displayed screen is slightly inclined. Thus, the overall tilt of the screen due to various causes is called tilt. In order to compensate for this electromagnetism, a rotation coil is used.

That is, the tilt correcting circuit of the monitor according to the prior art FIG. 2 can be seen as after winding the rotation coil (L _ROT) to the neck (3) portion of the CRT, it pushed through the full amplifier circuit the rotation coil (L _ROT illustrated in The tilt is corrected by rotating the tilted screen as a whole by controlling the direction and amount of current flowing through the circuit. At this time, the current flowing through the rotation coil L _ROT is the emitter current of the push-pull amplifier composed of the pair of transistors Q1 and Q2.

In addition, the current flowing through the rotation coil (L _ROT ) is the operational amplifier (OP1) for amplifying the tilt control signal input from the microcomputer (not shown) and the push-pull amplifier (Q1,) in accordance with the output of the operational amplifier (OP1) It is regulated by the operational amplifier OP2 which drives the base current of Q2).

Here, when the voltage input from the microcomputer is referred to as 'Vin' and the voltage input to the non-inverting (+) terminal of the operational amplifier OP1 is referred to as 'Vr', the output voltage Vo of the operational amplifier OP1 is as follows. It is obtained as in Equation 1.

The push-pull amplifiers Q1 and Q2 use '+ Vcc' and '-Vcc' as driving power to increase the variable amount (i.e., swing width) of the current flowing through the rotation coil L _ROT . .

However, when using the '+ Vcc' power supply and the '-Vcc' power supply together to increase the swing width as described above, there is a problem in that the -Vcc power supply terminal must be added.

Accordingly, the present invention has been made to solve the above problems, and an object thereof is to provide a tilt correction circuit of a monitor having a large swing width while using a single Vcc power supply.

In order to achieve the above object, the tilt correction circuit of the monitor according to the present invention includes a tilt correction circuit of the monitor which corrects the tilt of the screen by controlling the direction and magnitude of the current flowing through the rotation coil according to the tilt control signal from the microcomputer. The first amplifier unit amplifies the tilt control signal input from the microcomputer, the second amplifier unit amplifies the tilt control signal input from the microcomputer, and a single power source is applied to the first amplifier. A first push-pull amplifier for driving a current flowing through the rotation coil and a second push-pull amplifier for applying a current to the rotation coil according to the output of the second amplification unit is provided.

1 is a diagram showing the structure of a general CRT.

2 is a view showing a conventional tilt maintenance circuit.

3 is a diagram illustrating a tilt correction circuit according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

310: first amplifier 320: second amplifier

330: first push-pull amplifier 340: second push-pull amplifier

OP11, OP12: Operational Amplifier L _ROT : Rotation Coil

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

The tilt correction circuit of the monitor according to an embodiment of the present invention, as shown in FIG. 3, the first coil 310 and the second amplifier 310 amplifying the rotation coil L _ROT and the tilt control signal input from the microcomputer. The amplifier 320, a single voltage (Vcc) is applied, the first push-pull amplifier 330, a single voltage (Vcc) is applied and the rotation coil L in accordance with the output of the second amplifier 320 _And a second push-pull amplifier 340 for driving the current flowing in the _ROT ).

In the first amplifier 310 and the second amplifier 320, resistors R12 and R15 are connected between an inverting (-) terminal and a ground, and a feedback resistor R13, between the output terminal and the inverting (-) terminal. R16) is connected, and the microcomputer is composed of operational amplifiers (OP11, OP12) for amplifying the tilt control signal to the non-inverting (+) terminal through the resistors (R11, R14).

The first push-pull amplifier 330 includes a pair of NPN transistors Q11 and PNP transistors Q12 having a common base and an emitter. Here, the collector of the NPN transistor Q11 is connected to a single voltage Vcc, the collector of the PNP transistor Q12 is connected to ground, and the first amplifier is connected to the common base of the PNP transistor Q12 of the NPN transistor Q11. An output of the unit 310 is input, and a common emitter is connected to one end of the rotation coil L _ROT through the resistor R17.

In addition, the second push-pull amplifier 340 includes a pair of PNP transistors Q21 and NPN transistors Q22 having a base and a collector connected in common. Here, the emitter of the PNP transistor Q21 is connected to a single voltage Vcc, the emitter of the NPN transistor Q22 is connected to ground, and the second amplifier is connected to the common base of the PNP transistor Q21 and the NPN transistor Q22. The output of the unit 320 is input, and the common collector is connected to the other end of the rotation coil L _ROT through the resistor R18.

Referring to FIG. 3, the rotation coil L _ROT is wound around the neck portion of the CRT, and generates a magnetic field according to the direction and magnitude of the flowing current to correct the tilt of the displayed screen.

At this time, the degree to which the tilt is corrected is determined according to the tilt control signal input from a microcomputer (not shown). That is, when the user manipulates the key to display the menu of the microcomputer and selects the tilt correction, and adjusts the data with the up / down keys, the tilt control signal is input from the microcomputer to the tilt correction circuit correspondingly.

The first amplifier 310 amplifies the tilt control signal from the microcomputer and applies it to the base of the first push-pull amplifier 330 to control the current flowing through the rotation coil L _ROT , and the second amplifier 320 amplifies the tilt control signal and applies it to the base end of the second push-pull amplifier 340 to control the current flowing in the rotation coil L _ROT .

Here, when the voltages respectively input to the non-inverting (+) terminals of the operational amplifiers OP11 and PO12 provided in the first amplifier 310 and the second amplifier 320 are referred to as 'Vin1 and Vin2', respectively, The output voltages Vo1 and Vo2 are obtained as shown in Equation 2 below.

The first push-pull amplifier 330 and the second push-pull amplifier 340 adjust the direction and magnitude of the current flowing through the rotation coil L _ROT according to the base current. For example, the tilt control signal output from the microcomputer is 0. From 5V, it is designed to operate as follows.

When the microcomputer outputs a tilt control signal of about 2.5V, both ends of the rotation coil L _ROT are balanced so that no current flows.

If the microcomputer outputs a voltage of about 3V, the first amplifier 310 and the second amplifier 320 output a 'high' level voltage, and thus the first push-pull amplifier 330 The current flowing through the NPN transistor Q11 increases, and the current flowing through the PNP transistor Q12 decreases. In addition, the current flowing through the NPN transistor Q22 of the second push-pull amplifier 340 also increases, but the current flowing through the PNP transistor Q21 decreases.

Therefore, when the microcomputer outputs a tilt control signal of about 3 V, the current flowing through the rotation coil L _ROT is the NPN transistor Q11 of the first push-pull amplifier 330 and the NPN of the second push-pull amplifier 340. Current flows in the direction of arrow 1 through the transistor Q22.

On the contrary, when the microcomputer outputs a voltage of about 1 V, the first amplifier 310 and the second amplifier 320 output a 'low' level voltage, and thus the first push-pull amplifier 330 The current flowing through the NPN transistor Q11 decreases, and the current flowing through the PNP transistor Q12 increases. In addition, the current flowing through the NPN transistor Q22 of the second push-pull amplifier 340 also decreases, but the current flowing through the PNP transistor Q21 increases.

Therefore, when the microcomputer outputs a tilt control signal of about 1 V, the current flowing through the rotation coil L _ROT is transferred to the PNP transistor Q21 of the second push-pull amplifier 340 and the PNP of the first push-pull amplifier 330. The current flows in the direction of arrow 2 through the transistor Q12.

As described above, the current flowing through the rotation coil L _ROT according to the tilt control signal output from the microcomputer is adjusted in direction and magnitude, thereby obtaining a large swing width using a single power supply.

As described above, the tult correction circuit according to the present invention has an effect of obtaining the same swing width as using a positive voltage (+ Vcc, -Vcc) while using a single voltage (Vcc).

Claims (3)

A tilt correction circuit of a monitor for correcting tilt of a screen by controlling a direction and magnitude of a current flowing through a rotation coil (L _ROT ) in accordance with a tilt control signal from a microcomputer, the amplifying a tilt control signal input from the microcomputer A first amplifier 310, a second amplifier 320 for amplifying the tilt control signal input from the microcomputer, a single voltage (Vcc) is applied and the rotation according to the output of the first amplifier 310 The first push-pull amplifier 330 for driving the current flowing in the coil (L _ROT ), and the second push-pull amplifier (340) for driving the current flowing in a single voltage (Vcc) is provided, the tilt of the monitor Correction circuit. According to claim 1, wherein the first amplifier 310 and the second amplifier 320 is a resistor (R12, R15) is connected between the inverting (-) terminal and the ground, and between the output terminal and the inverting (-) terminal The feedback resistors R13 and R16 are connected to each other, and the operational amplifiers OP11 and OP12 receive and amplify the tilt control signal of the microcomputer through non-inverting (+) terminals through the resistors R11 and R14. Tilt correction circuit of the monitor. The method of claim 1, wherein the first push-pull amplifier 330 is composed of a pair of NPN transistors Q11 and PNP transistors Q12 having a base and an emitter connected in common, and the collector of the NPN transistors Q11 is a single power supply. (Vcc), the collector of the PNP transistor Q12 is connected to the ground, the output of the first amplifier 310 is input to the common base of the PNP transistor Q12 of the NPN transistor Q11, the common The emitter is connected to one end of the rotation coil L _ROT through a resistor R17, and the second push-pull amplifier 340 is a pair of PNP transistors Q21 and NPN transistors Q22 having a base and a collector connected in common. The emitter of the PNP transistor Q21 is connected to a single power supply Vcc, the emitter of the NPN transistor Q22 is connected to ground, and the PNP transistor Q21 and the NPN transistor Q22 The output of the second amplifier 320 is input to the common base. And a common collector resistor (R18) to rotate the coils (L _ROT) of the tilt correcting circuit of the monitor, characterized in that connected to the other terminal through.