KR900008168Y1 - Image control circuit - Google Patents

Abstract

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Description

Image control circuit

1 is a conventional image control circuit diagram.

2 is an image control circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

TR1-TR5: Transistor R1-R16: Resistor

C1-C5: Capacitor D1-D4: Diode

G1: grid 1,1 ': blanking circuit

2,2 ': Automatic brightness control unit 3,3': Bright control unit

4,4 ': flyback transformer portion 5: CRT

51: anode

The present invention relates to an image control circuit capable of integrating blanking, automatic brightness control (ABL), and bright operation in a monitor, and in particular, enables automatic brightness control by directly changing the grid voltage of a CRT tube with a current flow. It relates to an image control circuit.

In the conventional image control circuit, as shown in FIG. 1, the blank signal input terminal WO is connected to the retrace elimination circuit section 1 composed of the resistors R1 (R2) and the transistor TR1, and the image is displayed. The amplifier stage XO, the contrast circuit YO and the image output terminal Zi are connected in common, and the connection point thereof is connected to the collector of the transistor TR1 of the blanking circuit section 1 via the diode D1, while the diode D2 is connected. Is connected to the transistor TR2 emitter of the automatic brightness control unit 2 composed of the transistor TR2, the resistors R3-R6, and the capacitor C1, and the resistance of the automatic brightness control unit 2 The connection point of R6) and capacitor C1 is grounded through resistors R7 and R8, and a flyback transformer section 4 composed of a flyback transformer T1, a diode D3, and a capacitor C2. Is connected to the anode 51 of the CRT 5, and the grid G1 of the CRT 5 has a variable resistor VR1 (VR2), a resistor R9 (R10) and a condenser. Consisted by connecting the variable side of the variable resistor (VR1), the Bright adjustment unit (3) consisting of (C3). Therefore, when power is applied to the power supply terminal Vcc (B ⁺ ), when the brightness becomes bright, a large amount of current flows to the anode 51 of the CRT 5, so that the current input to the flyback transformer unit 4 ( Ib) increases, and accordingly, the potential applied to the base of the transistor TR2 is lowered and the transistor TR2 is turned on, so that a part of the current flowing in the image output terminal Zi is passed through the diode D2 through the transistor TR2. In this case, a small current flows to the anode 51 of the CRT 5 in the reference level state where the brightness is dark, and the current Ib input to the flyback transformer unit 4 is reduced. As a result, the potential applied to the base of the transistor TR2 is increased and turned off so that there is no change in the image output so that the luminance change is not affected.

Alternatively, when the blank signal is input from the blank signal input terminal (WO), the transistor TR1 is turned on and the image output flows to the ground, so that the screen does not come out and the blank is erased. Therefore, it does not affect the video output. In addition, the negative voltage (-Vcc) is varied by varying the variable resistor VR1 and the variable resistor VR2 to control the brightness by varying the grid G1 voltage of the CRT 5.

However, such a conventional image control circuit has a complicated configuration, and since automatic luminance adjustment is operated in accordance with the change in the size of the image output, there is a problem that the operation progress is not performed quickly and accurately.

In view of the above, the present invention has been made so that the automatic brightness control can be made quickly and accurately by directly changing the grid (G1) voltage of the CRT 5 with the flow of current, which will be described in detail with reference to the accompanying drawings. As follows.

FIG. 2 is an image control circuit diagram of the present invention. As shown therein, a power supply terminal B ⁺ is connected to a base of a capacitor C5 and a transistor TR3 through a resistor R13, and the connection point thereof is connected to a resistor ( R11) and flyback transformer 4 'of flyback transformer T1, diode D4, ground capacitor C4, connected to anode 51 of CRT 5, and auto-brightness control unit 2'. And emitter of the transistor TR3, which is the output side of the auto-luminance control unit 2 ', through the resistor R12 and the variable resistor VR3 to the resistors R15, R16 and TR5. The transistor TR4 is connected to the collector of the transistor TR5 of the blanking circuit unit 1 'which is controlled by the blank signal input terminal WO, and is connected to the emitter of the transistor TR4 whose base is grounded. Connects the collector to the grid G1 of the CRT 5 and at the negative power terminal via the resistor R14. That connects to the (-Vcc) configured with the Bright adjustment part (3 '), it will be described the operation and effect of the present design thus constructed in detail as follows.

When power is applied to the power supply terminals Vcc and B ⁺ and the reference level is dark, the current Ib flowing through the flyback transformer 4 'is at least the base voltage of the transistor TR3. Since the voltage of Vcc) is clamped to the sum of the collector-base voltages, the luminance does not change, and the luminance changes only by the variable position of the variable resistor VR3.

On the other hand, in the state where the brightness is bright, the current Ib flowing in the flyback transformer section 4 'is increased so that the base voltage of the transistor TR3 is lower than the clamp voltage, thereby lowering the emitter of the transistor TR3. The voltage is output, and this low output voltage is applied to the grid G1 of the CRT 5 through the resistor R12, the variable resistor VR3, and the transistor TR4, so that the screen becomes dark and the brightness is automatically adjusted. Will be done.

In addition, when the blank signal is input to the retrace elimination circuit unit 1 ', the transistor TR5 is turned on so that the current through the variable resistor VR3 flows to the ground through the transistor TR5 in the transistor TR4. As a result, a negative power supply (-Vcc) is applied to the CRT 5 so that the screen does not come out, and the blanking is erased. If the blank signal is not input, the transistor TR5 is turned off so as not to affect the screen.

In addition, the brightness adjustment enables the brightness of the screen to be adjusted by varying the voltage applied to the grid G1 of the CRT 5 by varying the current flowing through the transistor TR4 with the variable resistor VR3.

As described in detail above, the present invention directly changes the grid G1 voltage of the CRT 5 by the flow of current, so that the brightness adjustment can be automatically and accurately controlled quickly.

Claims (1)

The power supply terminal B ⁺ is connected to the base of the capacitor C5 and the transistor TR3 through the resistor R13, and the anode of the CRT 5 through the resistor R11 and the flyback transformer 4 '. A return erase circuit portion 1 'and a base which are connected to 51 and under which the emitter of the transistor TR3 is controlled by the blank signal input terminal WO after the resistor R12 and the variable resistor VR3 are grounded. And a collector of the transistor TR4 connected to the grid G1 of the CRT 5 together with a negative power supply terminal (-Vcc) through the resistor R14. An image control circuit.