KR100244775B1 - A circuit for compensating rgb signals in case of abl in a monitor - Google Patents

Abstract

The present invention relates to a video signal compensating circuit for automatic brightness limitation in a monitor in which the size of a video signal is increased when the brightness of the entire screen is lowered by the ABL and the size of the DC component is reduced so that the screen is clear even in ABL.

The circuit of the present invention includes a first resistor (R21) for adjusting the size of the video signal is connected or separated from the output terminal of the video preamplifier; A second resistor R28 connected to or separated from an output terminal of the video power amplifier to adjust the magnitude of the video signal DC component; Detecting means for detecting an operation of the ABL circuit; A video signal controller for separating the first resistor to increase the size of the video signal when the detecting means detects the ABL operation; And a DC component controller for connecting the second resistor to lower the magnitude of the DC signal when the detecting means detects the ABL operation.

Therefore, the video signal compensation circuit according to the present invention can display the screen clearly and at the same time lower the overall brightness by increasing the video signal and lowering the DC component at the time of ABL.

Description

A circuit for compensating RGB signals in case of ABL in a monitor}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic brightness control circuit (ABL: Automatic Brightness Control or ACL: Automatic Current Control) to prevent the screen from becoming too bright when the anode current is excessively increased in a monitor. The present invention relates to a video signal compensating circuit for automatic brightness limitation in a monitor in which a video signal is increased when the brightness of the screen is lowered and the DC component is lowered so that the screen is clear even at ABL.

In general, a cathode ray tube (CRT) focuses and accelerates hot electrons emitted from R, G, and B electron guns, and then collides with R, G, and B fluorescent surfaces through a point on a shadow mask to form pixels. Sawtooth current flows to form a two-dimensional screen.

In order to operate the cathode ray tube (CRT), a heater voltage of about 6.3V is applied to the heater, and a focus grid voltage, a screen grid voltage, etc. are required for focusing the emitted hot electrons. High pressure of 20 ~ 30KV is applied.

However, when the anode current increases in the cathode ray tube, the screen becomes brighter. Accordingly, the size of the screen is changed and the fluorescent surface of the CRT is easily aging due to excessive brightness, or the user's eyes are tired.

In order to solve this problem, most monitors are equipped with an automatic luminance limiting circuit (ABL or ACL). As shown in FIG. 1, a typical automatic luminance limiting circuit includes a DC-DC converter 100 and an FBT 110. And a horizontal output unit 120, a horizontal driver 130, a video preamplifier 140, and a video power amplifier 150, and detect a voltage dropped by an anode current flowing through the secondary winding of the FBT 110. To the collector of the PNP transistor Q1 and the collector of the PNP transistor Q1, a resistor R2, a base connected to the resistor R2, and a Vcc (12V) connected to the emitter through a resistor R3. The divided resistors R3 and R5 connected to each other, the NPN transistor Q2 having a base connected to the split resistors R3 and R5, and the collector output of the NPN transistor Q2 are connected to the contrast of the video preamplifier 140. Consist of split resistors (R6, R7, R8) for connection to the terminals.

A diode D1 and a capacitor C2 are connected to the resistor R3 in parallel, and a voltage of Vcc1 (80V) is connected to the anode current terminal through the resistor R1, and this connection point connects the capacitor C1. It is grounded through. Here, the resistor R1 has a high resistance value of about 120K ohms.

In general, an ABL circuit is a circuit for preventing a large anode current from flowing when the luminance is abnormally high, thereby overloading the high-voltage generating circuit and causing components to be destroyed. To this end, the change of the anode current is detected and fed back to the brightness control voltage or contrast control voltage to apply the ABL. That is, when the brightness increases and the anode current exceeds the threshold, the anode current is limited by lowering the contrast control voltage of the video preamplifier 140.

For example, when the anode current is increased and the voltage of the node A is lowered, the PNP transistor Q1 is further biased in the forward direction so that a large amount of collector current flows, thereby gradually increasing the base current of the NPN transistor Q2, thereby increasing the transistor ( Q2) is turned on. When the transistor Q2 is turned on, the current flowing through the resistor R6 increases, thereby limiting the brightness of the screen such that the voltage of the contrast terminal of the video preamplifier 140 is lowered.

That is, the video preamplifier 140 amplifies and outputs the R, G, and B video signals input through the sub-connector according to the magnitude of the signal input through the contrast terminal, and the higher gain of the contrast terminal increases the gain. Amplify the video signal to make it larger, and when the voltage of the contrast terminal decreases, amplify it to a lower gain to make the video signal smaller.

Therefore, in the ABL circuit, when the anode current increases, the base voltage of the PNP transistor Q1 is increased in the negative direction, which causes forward bias. Accordingly, the NPN transistor Q2 also has the forward bias, which increases the voltage of the contrast terminal. Lowering it limits the luminance.

However, even when the ABL operation is performed by the ABL circuit, there is a problem that the screen is not clear because the overall brightness of the screen is generally bright and the size of the video signal is small.

Accordingly, the present invention has been proposed to solve the above problems, and provides an automatic luminance limitation video signal compensation circuit capable of providing a clearer image by increasing the video signal and reducing the DC component at the time of ABL. There is a purpose.

In order to achieve the above object, the circuit of the present invention amplifies the RGB video signal by the video preamplifier with a variable amplification according to the contrast signal and then amplifies the video power amplifier with high gain to drive the cathode of the CRT, In a monitor equipped with an automatic luminance limiting circuit configured to control the contrast signal to control the brightness of the screen when the anode current flowing through it increases, it is connected to or separated from an output terminal of the video preamplifier to adjust the magnitude of the video signal. First resistance; A second resistor connected to or separated from an output terminal of the video power amplifier to adjust a magnitude of a video signal DC component; Detecting means for detecting an operation of the ABL circuit; A video signal controller for separating the first resistor to increase the size of the video signal when the detecting means detects the ABL operation; And a DC component controller for connecting the second resistor to lower the magnitude of the DC signal when the detecting means detects the ABL operation.

1 is a circuit diagram showing the configuration of a monitor equipped with an automatic luminance limiting circuit;

2 is a circuit diagram showing the configuration of a monitor equipped with a video signal compensating circuit for automatic luminance limitation in accordance with the present invention.

* Explanation of symbols for main parts of the drawings

100: DC-DC converter 110: high pressure generator (FBT)

120: horizontal output unit 130: horizontal drive unit

140: video preamplifier 150: video power amplifier

200: video signal compensation circuit

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

As shown in FIG. 2, the monitor equipped with the video signal compensation circuit according to the present invention includes a DC-DC converter 100, a high voltage generator (FBT) 100, a horizontal output unit 120, a horizontal driver 130, The video preamplifier 140, the video power amplifier 150, and the video signal compensation circuits 200R, 200G, and 200B are included. In addition, although not shown in FIG. 2, the ABL circuit as shown in FIG. 1 is employed in the monitor to which the present invention is applied, and thus the ABL operation is performed.

Split resistors R11 and R12 for connecting an output signal to the video power amplifier 150 are connected to the output terminal of the video preamplifier 140 shown in FIG. The resistor R21 is connected or disconnected in parallel to adjust the size of the video signal.

In addition, the split resistors R14 and R15 are connected to the output terminal of the video power amplifier 150 to adjust the magnitude of the DC voltage for driving the cathode of the CRT 170. ) Is connected to or separated from the resistor R28 in parallel to adjust the magnitude of the DC component.

In the video signal compensating circuit according to the present invention, when the zener diode DZ21 and the zener diode DZ21 are conducted, the video signal for reducing the size of the video signal by connecting the resistor R21 to the resistor R12 in parallel. The control unit and the Zener diode DZ21 are configured to connect the resistor R28 to the resistor R15 in parallel to control the magnitude of the DC signal when the zener diode DZ21 is turned on.

The video signal controller is turned on when the zener diode DZ21 is turned on, and is turned on when the first transistor Q21 is turned on to connect the resistor R21 to an output terminal of the video preamplifier 140. A third transistor Q23 that is turned on when the zener diode DZ21 is turned on, a fourth transistor Q24 that is turned off when the third transistor Q23 is turned on, and includes a second transistor Q22; When the fourth transistor Q24 is turned off, the resistor R28 is configured as a fifth transistor Q25 which separates the resistor R28 from the output terminal of the video power amplifier 150.

Next, the operation of the automatic luminance limiting circuit of the present invention configured as described above will be described.

When the anode current is normal (i.e. before ABL is applied), the voltage of node A is high, so the zener diode DZ21 is conducting, and when the anode current increases and the voltage of node A is lowered (i.e., ABL is applied) ) Zener diode DZ21 is turned off. Therefore, the operation of the present invention will be described by dividing it into a case where the zener diode DZ21 is turned on and when it is turned off.

1.Before ABL (When Zener Diode is On)

When the anode current flows normally, the voltage of the node A is relatively higher than the rated voltage of the zener diode DZ21 so that the zener diode DZ21 conducts. When the zener diode DZ21 is turned on, 'high' is applied to the base of the first transistor Q21 to turn on the first transistor Q21. As a result, the base of the second transistor Q22 is turned 'low' so that the zener diode DZ21 is turned on. The two transistors Q22 are also turned on.

Therefore, the output terminal of the video preamplifier 140 is connected to the resistor R12 and the resistor R21 in parallel to reduce the total resistance value, thereby reducing the video output of the video preamplifier 140.

On the other hand, when the voltage of the node A is relatively higher than the rated voltage of the zener diode DZ21, when the zener diode DZ21 conducts, the third transistor Q23 is turned on, and accordingly, the fourth transistor Q24 and the fourth transistor are turned on. 5 transistor Q25 is turned off.

Therefore, since the voltage divided by the resistor R15 drives the cathode of the output terminal of the video power amplifier 140, the video signal loaded on the relatively large DC voltage is output.

2.When ABL is caught (Zener diode is off)

When the anode current increases and the voltage of the node A becomes relatively lower than the rated voltage of the zener diode DZ21, the zener diode DZ21 is turned off. When the zener diode DZ21 is turned off, 'low' is applied to the base of the first transistor Q21, so that the first transistor Q21 is turned off. Transistor Q22 is also turned off.

Therefore, the resistor R21 connected to the collector of the second transistor Q22 is electrically separated from the ground, and the output terminal of the video preamplifier 140 is sized by the resistor R12, and the overall resistance value is relatively As it becomes larger, the video output of the video preamplifier 140 becomes larger.

On the other hand, when the voltage of the node A is relatively lower than the rated voltage of the zener diode DZ21, when the zener diode DZ21 is turned off, the third transistor Q23 is turned off, and thus the fourth transistor Q24 and the fourth transistor Q24 are turned off. The fourth transistor Q25 is turned on.

When the fifth transistor Q25 is turned on, the resistor R28 is connected to ground, and the output terminal of the video power amplifier 150 is divided by a resistor R15 and a resistor R28 connected in parallel with the resistor R15. Since this method is driven, a video signal loaded on a relatively small DC voltage is output.

In summary, the above description is shown in Table 1 below.

TABLE 1

Before the ABL is applied, as shown in Table 1, the output of the video preamplifier 140 is relatively low, and the output (direct current component) of the video power amplifier 150 is relatively high. The output of the preamplifier 140 is increased and the output (direct current component) of the video power amplifier 150 is made relatively low.

As described above, the video signal compensating circuit according to the present invention has an effect of displaying the screen clearly and simultaneously reducing the overall brightness by increasing the video signal and reducing the DC component at the time of ABL.

Claims (3)

After the video preamplifier is amplified with variable amplification according to the contrast signal, it is amplified with high gain in the video power amplifier to drive the cathode of the CRT, and when the anode current flowing through the FBT increases, the contrast signal is controlled. In the monitor equipped with an automatic luminance limit circuit for controlling the brightness of the screen, A first resistor (R21) connected to or separated from an output terminal of the video preamplifier to adjust a magnitude of a video signal; A second resistor (R28) connected to or separated from an output terminal of the video power amplifier to adjust a magnitude of a video signal DC component; Detection means for detecting the operation of said automatic luminance limiting circuit, comprising a zener diode (DZ21) which is conducting normally and is turned off during operation of the automatic luminance limiting circuit; A video signal controller for separating the first resistor to increase the size of the video signal when the detecting means detects the operation of the automatic luminance limiting circuit; And And a DC component controller for lowering the magnitude of the DC signal by connecting the second resistor when the detecting means detects the operation of the automatic luminance limiting circuit. The method of claim 1, wherein the video signal control unit A first transistor Q21 that is turned on when the zener diode DZ21 is conductive; And And a second transistor (Q22) for connecting the first resistor to an output terminal of the video preamplifier when the first transistor (Q21) is turned on. The method of claim 1, wherein the DC component control unit A first transistor Q23 that is turned on when the zener diode DZ21 is conductive; A second transistor Q24 that is turned off when the first transistor Q23 is turned on; And And a third transistor (Q25) which separates the second resistor from the output terminal of the video power amplifier when the second transistor (Q24) is turned off.