KR100575167B1 - A circuit for compensating voltage of a horizontal drive transformer in a multi-mode video display system - Google Patents

Abstract

The present invention relates to a drive voltage compensation circuit of a horizontal drive transformer in a multi-mode video display device.

The present invention is a multi-mode provided with a horizontal drive transformer (HDT) is supplied to the horizontal output transistor (TR2) to generate the induced electromotive force by the on / off time of the horizontal drive transistor (TR1) receives the drive voltage (Vcc) An image display device comprising: a microcomputer (10) for outputting a control signal of high or low level in accordance with a horizontal frequency; Switching on / off by the control signal is configured to further include a switching unit 20 for selectively supplying the first driving voltage (Vcc1) and the second driving voltage (Vcc2) to the horizontal drive transformer (HDT),

In the low horizontal frequency band, the drive voltage Vcc supplied to the horizontal drive transformer HDT is increased, and in the high horizontal frequency band, the drive voltage Vcc is decreased, thereby keeping the output voltage of the horizontal drive transformer HDT constant. As a result, the drive condition of the horizontal output transistor TR2 can be kept constant regardless of the horizontal frequency.

Multi-mode, Video Display, Horizontal Deflection Circuit, Horizontal Drive Transformer

Description

A circuit for compensating voltage of a horizontal drive transformer in a multi-mode video display system

1 is a circuit diagram showing a horizontal deflection circuit of a general video display device;

2 is a circuit diagram illustrating a driving voltage compensation circuit of a horizontal driving transformer in a multi-mode image display device according to the present invention.

* Names of symbols according to the main parts of the drawings

10: microcomputer 20: switching unit

Q 11,12: first and second transistors R 11,12,13,14,15: resistor

Vcc1: First drive voltage Vcc2: Second drive voltage

HDT: Horizontally Driven Transformers HD.Y: Horizontal Deflection Coils

TR1: Horizontal Drive Transistor TR2: Horizontal Output Transistor

The present invention relates to a drive voltage compensation circuit of a horizontal drive transformer in a multi-mode image display device.

More specifically, in a multi-mode video display device in which the drive voltage supplied to the horizontal drive transformer (HDT) is increased or decreased according to the horizontal frequency to maintain the drive condition of the horizontal output transistor TR2 regardless of the horizontal frequency. A drive voltage compensation circuit of a horizontal drive transformer.

In general, a cathode ray tube (CRT) used in an image display device is a solid color or R, G, B (red, green, blue) fluorescent material coated with a different amount of electron beam on the surface of the cathode ray tube according to the intensity of the image signal. It uses the principle of producing light of different brightness or color and is widely used because of its excellent price and display performance.

That is, a cathode ray tube (CRT) image display device receives an image signal and a synchronization signal received from a video card of a computer system and displays information on a screen. The video system for processing an image signal, and a vertical and horizontal deflection It consists of deflection system and power system.

Here, the video card supports various video modes as shown in Table 1 below. The video mode outputs a horizontal frequency and a vertical frequency differently according to a resolution to be implemented, and the screen flickers as the horizontal and vertical frequencies increase from low to high frequencies. By preventing blurring, the eyes of the user are reduced.

   Video mode    Horizontal frequency (KHz)    Vertical frequency (Hz)     Resolution (H * V)      CGA      15.75       60    640 * 200      EGA      21.8       60    640 * 350      VGA      31.5      60/70    720 * 350 640 * 480      SVGA     35 to 37    INTERLACE   1024 * 768  High resolution mode     64 to 75      50-90   1024 * 768 1280 * 1024

As shown in Table 1 above, the horizontal and vertical frequencies are different according to the modes supported by the video card, and in particular, the video card supporting various modes, for example, a video card supporting VGA and SVGA and high resolution only modes, is mounted on the monitor. If so, the range of the horizontal frequency of each mode is about 30 ~ 75KHz.

That is, when the mode is changed in the multi-mode monitor, there are parts that need to be changed in the internal circuits of the monitor. For example, image size and position change, horizontal and vertical synchronization and deflection optimization, and various deflection correction circuits. Readjustment should be done.

Referring to the horizontal deflection circuit of Figure 1 briefly described the operation of the deflection circuit of the monitor.

A horizontal drive signal (H.drive) having a horizontal synchronization frequency (H.sync) output from the video card turns on the horizontal drive transistor (TR1), and the base of the horizontal output transistor (TR2) through the horizontal drive transistor (HDT). Supply current to the terminal.

When the horizontal output transistor TR2 is turned on by receiving sufficient base current, the B ⁺ power current of the flyback transformer FBT flows to the horizontal output transistor TR2 through the horizontal deflection coil HD.Y.

In this way, while the horizontal output transistor TR2 is turned on, it corresponds to the second half of the effective scanning period of the horizontal sawtooth wave. Then, when the horizontal output transistor TR2 is rapidly turned off according to the horizontal drive signal H. driver, the horizontal deflection coil is turned off. The current accumulated in (HD.Y) charges the retrace capacitor (RE.C).

When the retrace capacitor RE.C is fully charged, it is discharged back to the horizontal deflection coil HD.Y and thus current is accumulated in the horizontal deflection coil HD.Y. In this way, the period between the charging and discharging of the retrace capacitor RE.C determines the retrace period.

When energy is accumulated in the horizontal deflection coil HD.Y and the deflection coil voltage reaches a degree of applying a forward bias to the damper diode DD, the damper diode DD is conducted and flows through the deflection coil HD.Y. The current drops to zero. At this time, the current flowing through the damper diode D.D corresponds to the first half of the effective scanning period of the horizontal sawtooth wave.

As such, when the current becomes zero, the horizontal output transistor TR2 is turned on again by the horizontal drive signal H. driver, and the sawtooth current flows through the horizontal deflection coil HD.Y while repeating the above process. Horizontal deflection is made and horizontal scanning is performed.

However, in the conventional horizontal deflection circuit, as the horizontal frequency of each mode increases, the on-time of the horizontal drive transistor TR1 becomes long, and accordingly, the voltage induced from the secondary side of the horizontal drive transformer HDT becomes large and horizontal. The base current of the output transistor TR2 becomes large. On the contrary, when the horizontal frequency decreases, the on-time of the horizontal driving transistor TR1 is shortened. Accordingly, the voltage induced in the secondary side of the horizontal driving transistor HDT decreases, so that the base current of the horizontal output transistor TR2 decreases. Becomes smaller. Therefore, since the base current of the horizontal output transistor TR2 changes rapidly according to the horizontal frequency, there is a problem that the horizontal deflection circuit becomes unstable.

Accordingly, the present invention has been made in order to solve the above problems, by increasing or decreasing the driving voltage supplied to the horizontal drive transformer according to the horizontal frequency to maintain a constant drive condition of the horizontal output transistor regardless of the horizontal frequency It is an object of the present invention to provide a driving voltage compensation circuit of a horizontal driving transformer in a mode image display device.

The circuit according to the present invention for achieving the above object,

In a multi-mode image display device having a horizontal drive transformer for supplying a driving voltage to the horizontal output transistor by generating induced electromotive force by the on / off time of the horizontal drive transistor,

A microcomputer for outputting a high or low level control signal according to a horizontal frequency;

And a switching unit configured to switch on / off by the control signal to selectively supply the first driving voltage and the second driving voltage to the horizontal driving transformer.

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

2 is a circuit diagram illustrating a driving voltage compensation circuit of a horizontal driving transformer in a multi-mode image display device according to the present invention.

As shown in FIG. 2, the circuit according to the present invention receives the driving voltage Vcc and generates horizontal induced transistors by the on / off time of the horizontal driving transistor TR1 to supply the horizontal output transistor TR2. A multi-mode image display device equipped with a drive transformer (HDT), comprising: a microcomputer (10) for outputting a high or low level control signal according to a horizontal frequency; The switching unit 20 is switched on / off by the control signal, and further includes a switching unit 20 for selectively supplying the first driving voltage Vcc1 and the second driving voltage Vcc2 to the horizontal driving transformer HDT. .

The switching unit 20 may include a first transistor Q11 that is switched on / off by receiving a control signal from the microcomputer 10; The switching is turned on / off in conjunction with the switching on / off operation of the first transistor Q11 to supply the second driving voltage Vcc2 to the horizontal driving transformer HDT together with the first driving voltage Vcc1. And a second transistor Q12 for supplying only the second driving voltage Vcc2 to the horizontal driving transformer HDT.

The first transistor Q11 is implemented as an NPN transistor, and the second transistor Q12 is implemented as a P-channel field effect transistor.

Next, the operation and effects of the circuit according to the present invention configured as described above will be described in detail.

The microcomputer 10 outputs a high level control signal when a low frequency horizontal frequency is input from the video card, and outputs a low level control signal when a high frequency horizontal frequency is input.

Accordingly, when the low frequency horizontal frequency is input and the microcomputer 10 outputs a high level control signal, the high level control signal is transmitted to the base terminal of the first NPN transistor Q11 through the resistor R11. Is applied to the first transistor Q11 to switch on. As the first transistor Q11 is switched on, a low level signal is applied to the gate terminal of the second P-channel field effect transistor Q12, so that the second transistor Q12 is switched on, and the second transistor Q12 is turned on. Is switched on, and the second driving voltage Vcc2 is supplied to the horizontal driving transformer HDT together with the first driving voltage Vcc1.

On the contrary, when the high frequency horizontal frequency is input and the microcomputer 10 outputs a low level control signal, the low level control signal is transmitted to the base terminal of the first NPN transistor Q11 through the resistor R11. Is applied to switch the first transistor Q11 off. As the first transistor Q11 is switched off, a high level signal is applied to the gate terminal of the second P-channel field effect transistor Q12, so that the second transistor Q12 is switched off, and the second transistor Q12 is turned off. Is switched off, only the second driving voltage Vcc2 is supplied to the horizontal drive transformer HDT.

That is, when the low frequency horizontal frequency is input, the second driving voltage Vcc2 is supplied to the horizontal driving transformer HDT together with the first driving voltage Vcc1. When the high frequency horizontal frequency is input, the second driving voltage ( By supplying only Vcc2), when the low frequency horizontal frequency is inputted, the total drive voltage supplied to the horizontal drive transformer (HDT) is increased. When the high frequency horizontal frequency is inputted, the total drive voltage supplied to the horizontal drive transformer (HDT) is supplied. Decreases.

As described above, the present invention increases or decreases the driving voltage supplied to the horizontal driving transformer (HDT) according to the horizontal frequency to maintain the output voltage of the horizontal driving transformer (HDT) constant, regardless of the horizontal frequency for each mode. Since the base current flowing through the horizontal output transistor TR2 is constantly supplied to maintain a constant drive condition, it is effective in improving the reliability of the horizontal output transistor TR2 and the life of the entire set.

Claims (2)

In a multi-mode image display device having a horizontal drive transformer for supplying a driving voltage to the horizontal output transistor by generating induced electromotive force by the on / off time of the horizontal drive transistor, A microcomputer for outputting a high or low level control signal according to a horizontal frequency; Switching on / off by the control signal, the switching unit for selectively supplying the first driving voltage and the second driving voltage to the horizontal drive transformer further comprises a horizontal drive transformer in the multi-mode image display device Drive voltage compensation circuit. The method of claim 1, wherein the switching unit, A first transistor switched on / off by receiving a control signal from the microcomputer; The switching is turned on / off in conjunction with the switching on / off operation of the first transistor to supply a second driving voltage to the horizontal driving transformer together with the first driving voltage, and to supply the second driving voltage to the horizontal driving transformer. A drive voltage compensation circuit of a horizontal drive transformer in a multi-mode image display device, comprising a second transistor for supplying only a drive voltage.

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