KR20000009203U - Monitor back raster adjustment circuit - Google Patents

Abstract

The present invention relates to a back raster adjusting circuit which is configured to prevent the color coordinates from shifting when the back raster is adjusted using the R, G, and B bias circuits.

The apparatus of the present invention comprises: a microcomputer 16 for providing R, G, and B bias control signals to adjust color coordinates during back raster adjustment, and one brightness control signal to adjust overall brightness; An R bias circuit 14a for adjusting the R bias; A G bias circuit 14b for adjusting the G bias; A B bias circuit 14c for adjusting the B bias; A first DC control variable resistor 22a which adjusts a gain of the R bias circuit in accordance with the brightness bias control signal to the R bias control signal of the microcomputer; A second DC control variable resistor 22b for adjusting the gain of the G bias circuit in accordance with the bright bias control signal to the G bias control signal of the microcomputer; And a third DC control variable resistor 22c that adjusts the gain of the B bias circuit in accordance with the B bias control signal of the microcomputer according to the brightness control signal.

Therefore, according to the present invention, when adjusting the back raster during the manufacturing process of the monitor, the brightness is controlled by processing the R, G, B bias for adjusting the color coordinate and the brightness for adjusting the overall brightness by using the DC control variable resistor. Color coordinates can be prevented from shifting at the time.

Description

BACK RASTER ADJUST CIRCUIT OF A MONITOR

The present invention relates to a circuit for adjusting the back raster in a monitor. In particular, the back raster adjustment is performed to prevent the color coordinates from being distorted when the back raster is adjusted using the R, G, and B DC bias circuits. It is about a circuit.

In general, a monitor is divided into a video system for processing an image signal, a deflection system for vertical and horizontal deflection, and a power system, and a video system requires a careful adjustment in relation to image quality. Therefore, in the manufacturing process of the monitor, the image-related part is adjusted at the factory.

For example, when adjusting the color coordinates in the monitor production line, adjustments are made in the absence of the R, G, and B signals (this is called 'BACK-RASTER' adjustment) and adjustments in the state where the R, G and B signals are input. It is done differently. Normally, in the absence of R, G, B signals (i.e. back raster adjustment), the color coordinate adjustment is determined by the magnitude of the cathode voltage for G1 by the R, G, B bias, and the overall brightness adjustment is the G1 voltage. Or by brightness control to vary the cathode voltage to the same magnitude. In the presence of the RGB signal, the color coordinate adjustment is made by the R, G, B gain (GAIN) adjustment, and the overall brightness is made by the contrast control.

FIG. 1 is a circuit diagram illustrating a general video system in a monitor, which includes a video preamplifier 10, a video power amplifier 12, R, G, and B bias circuits 14a, 14b, and 14c, a microcomputer 16, and a key input unit. It consists of 18. In FIG. 1, the video preamplifier 10 amplifies R, G, and B signals input from a video card (not shown) of a computer through a deserving according to a contrast adjustment signal, and the video power amplifier 12 is a video preamplifier. The output of the amplifier 10 is amplified with a fixed gain to drive the cathode of the CRT. At the output of the video preamplifier 10, the R signal is input to the video power amplifier 12 through the split resistors R1 and R2, and the G signal is the video power amplifier 12 through the split resistors R3 and R4. The signal B is input to the video power amplifier 12 through the split resistors R5 and R6.

In addition, the R output of the video power amplifier 12 drives the R cathode of the CRT through a resistor (R7), a capacitor (C1), and a resistor (R10) connected in series with each other, and the G output is connected with a resistor (R8) connected in series with each other. The G cathode of the CRT is driven through a capacitor (C2) and a resistor (R11), and the B output drives the B cathode of the CRT through a resistor (R9), a capacitor (C3), and a resistor (R12) connected in series with each other. . At this time, a DC bias voltage input from the bias circuits 14a, 14b, and 14c is applied to the output terminal of the video power amplifier 12 to drive the cathode of the CRT with a large voltage.

The R, G, and B bias circuits are configured in the same manner. The R bias circuit 14a includes two transistors Q1 and Q2, resistors R13, R14 and R15, a capacitor C4, and a diode D1. Adjust the R bias voltage according to the control signal (R.bias) of the microcomputer. The contrast of the video preamplifier is adjusted according to the contrast signal output from the microcomputer, and the brightness is adjusted by the voltage applied to the G1 grid.

As described above in this configuration, when the R, G, B signal is present and the R, G, B signal is absent (that is, the back raster), the color brightness and the overall brightness are adjusted. Since the ratio of the R, G, and B bias does not change, the color coordinate does not change.However, when the G1 voltage is changed by the brightness control, the R, G, B bias ratio changes according to the variation of the G1 voltage. There is a problem. In other words, if the color coordinate is adjusted to R, G, B bias in the back raster adjustment, and then the overall brightness is adjusted to brightness, the ratio between the cathode voltages is changed as the magnitude of the G1 voltage changes. .

Therefore, the present invention has been made to solve the above problems, and when the back raster is adjusted, it provides a back raster adjustment circuit of the monitor, which implements color coordinate adjustment and overall brightness adjustment using a DC control variable resistor. There is a purpose.

In order to achieve the above object, the present invention eliminates the R, G and B signals input to the video preamplifier and adjusts the R, G and B bias voltages and brightness voltages while observing the CRT screen. A monitor test apparatus capable of performing an adjustment, wherein each of the R, G, and B bias control signals is provided to adjust the color coordinates during the back raster adjustment, and one brightness control signal is provided to adjust the overall brightness. Micom; An R bias circuit for adjusting the R bias; A G bias circuit for adjusting the G bias; A B bias circuit for adjusting the B bias; A first DC control variable resistor configured to adjust a gain of the R bias circuit in accordance with a brightness control signal to an R bias control signal of a microcomputer; A second DC control variable resistor for adjusting a gain of the G bias circuit according to a brightness control signal in response to a G bias control signal of a microcomputer; And a third DC control variable resistor for adjusting the gain of the B bias circuit according to the B bias control signal of the microcomputer according to the brightness control signal.

1 is a circuit diagram showing a general video system in a monitor,

2 is a circuit diagram illustrating a video system to which a back raster adjusting circuit according to the present invention is applied.

* Explanation of symbols for main parts of the drawings

10: Video Preamplifier 12: Video Power Amplifier

14a, 14b, 14c: bias circuit

16: Micom 18: Key in

22a, 22b, 22c: DC control variable resistor

2 is a circuit diagram illustrating a video system to which a back raster adjusting circuit according to the present invention is applied.

Referring to FIG. 2, the video power amplifier 12 receives the R, G, and B signals, amplifies them with high gain, and outputs the R, G, and B cathodes, respectively, and the bias voltages of the R, G, and B cathodes are The R, G, and B bias circuits 14a, 14b, and 14c are provided. The R bias circuit 14a includes a PNP transistor Q2 whose base is connected to the collectors of the NPN transistor Q1 and the NPN transistor Q1, and the collector side of the NPN transistor Q1 and the emitter side of the PNP transistor Q2. It consists of a resistor, capacitor and diode connected to it. The voltage of the G1 grid is controlled by a variable resistor for sub brightness control, and the bias voltage of each cathode is adjusted to each bias control signal (R.bias, G.bias, B.bias) and brightness. It is variable according to a control signal. At this time, each control signal is provided from the microcomputer 16, as shown in FIG. That is, the microcomputer 16 provides R, G, and B bias control signals R.bias, G.bias, and B.bias, respectively, to adjust the color coordinates during the back raster adjustment, and to adjust the overall brightness. One brightness control signal is provided, and the first DC control variable resistor 22a is connected to the R bias control signal R.bias and the brightness control signal of the microcomputer 16 according to the R bias circuit 14a. Adjust the gain. The second DC control variable resistor 22b adjusts the gain of the G bias circuit 14b according to the brightness control signal in response to the G bias control signal G.bias of the microcomputer 16, and the third DC control variable. The resistor 22c adjusts the gain of the B bias circuit 14c according to the brightness control signal in response to the B bias control signal B.bias of the microcomputer 16.

Next, the back raster adjustment process in the circuit of the present invention configured as described above is as follows.

As described above, in the monitor video system test process in the factory where the monitor is manufactured, the color coordinate adjustment in the absence of the R, G, B signal (i.e. back raster adjustment) is performed by R, G, B bias. Determined by the magnitude of the cathode voltage for, respectively, the overall brightness adjustment is made by a brightness control that changes either the G1 voltage or the cathode voltage to the same magnitude. In the presence of the RGB signal, the color coordinate adjustment is made by the R, G, B gain (GAIN) adjustment, and the overall brightness is made by the contrast control.

When adjusting the color coordinates of the back raster, the R bias control signal, the G bias control signal, and the B bias control signal are input to one terminal of each of the DC control variable resistors 22a, 22b, 22c, and this input is input to each bias circuit 14a. , 14b, 14c). Therefore, change the R, G, B bias voltage individually and adjust the color coordinate.

On the other hand, in the case of adjusting the overall brightness of the back raster according to the present invention, after adjusting the sub-brightness of the G1 grid to be fixed constantly, according to the brightness control signal output from the microcomputer 16, the first DC control variable resistor Reference numeral 22a, the second DC control variable resistor 22b, and the third DC control variable resistor 22c are collectively adjusted.

In this way, the color coordinates are prevented from being distorted by adjusting the bias voltage collectively without changing the G1 grid voltage at the time of the back raster adjustment.

As described above, according to the present invention, when adjusting the back raster in the manufacturing process of the monitor, R, G, B bias for adjusting color coordinates and brightness for adjusting the overall brightness are adjusted by using a DC control variable resistor. The treatment has an effect of preventing the color coordinates from shifting during brightness adjustment.

Claims (1)

In the monitor test apparatus that can perform the back raster adjustment by removing the R, G, B signal input to the video preamp, and adjusting the R, G, B bias voltage and brightness voltage while observing the CRT screen. , A microcomputer 16 for providing R, G and B bias control signals to adjust color coordinates at the time of the back raster adjustment, and to provide one brightness control signal to adjust the overall brightness; An R bias circuit 14a for adjusting the R bias; A G bias circuit 14b for adjusting the G bias; A B bias circuit 14c for adjusting the B bias; A first DC control variable resistor (22a) for adjusting a gain of the R bias circuit according to a brightness control signal in response to a R bias control signal of a microcomputer; A second DC control variable resistor 22b that adjusts a gain of the G bias circuit according to a brightness control signal in response to a G bias control signal of a microcomputer; And And a third DC control variable resistor (22c) for adjusting the gain of the B bias circuit in accordance with the B bias control signal of the microcomputer according to the brightness control signal.