KR19980067995U - Monitor brightness adjustment circuit - Google Patents

Abstract

The present invention relates to a brightness control circuit of the monitor, the device of the present invention outputs a control signal to the ABL circuit for controlling the brightness of the entire screen according to the magnitude of the anode current flowing in the CRT screen, and the ABL circuit in the super bright mode In the brightness control circuit of the monitor equipped with a super bright circuit to increase the brightness of the entire screen, the super bright circuit is a microcomputer for outputting a high level super bright signal in the super bright mode, and a high level from the micom By providing an eleventh transistor turned on when the super bright signal is output, and a second transistor and a third transistor biased to reduce the emitter current when the eleventh transistor is turned on, The microcomputer will send a low level super bright signal in normal mode. Outputting a high level super bright signal in the super bright mode to realize a stable super bright mode, and at the same time, controlling the super bright signal in the super bright mode to limit the brightness of the screen to a certain degree. There is.

Description

Monitor brightness adjustment circuit

The present invention relates to an automatic brightness limiting 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 the monitor. The brightness control circuit of the monitor to brighten the brightness of the screen in the bright mode.

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, and vertical and horizontal deflection coils. 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, and about the anode is accelerated. A high pressure of 20-30 KV is applied.

As the anode current increases in the cathode ray tube, the screen becomes bright. Accordingly, the size of the screen is changed, and the fluorescent plate 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). A typical automatic luminance limiting circuit (ABL circuit) is a current change of the flyback transformer 51 as shown in FIG. When the detection is higher than the average luminance, the luminance of the screen is controlled by feeding back the potential of the lower node 'A' to the ABL terminal of the flyback transformer 51.

That is, when the potential of the node 'A' is lowered, the output voltage of the flyback transformer 51 supplied to the anode end of the CRT is reduced, thereby suppressing the anode current of the CRT and the contrast current flowing into the video preamplifier 53. The screen is dimmed by reducing (I _CON ).

The ABL circuit 52 controls the current I ₁ and the contrast current I _CON applied to the flyback transformer 51, so that the current I ₁ output to the flyback transformer 51 increases. In this case, the amount of current discharged from the capacitor C1 increases, so that the potential of the node 'A' is lowered.

When the potential of the node 'A' is lowered, the current I ₂ and the current I ₃ increase, but when the current I ₃ increases, the current between the base and emitter ends of the first transistor Q1 increases. In addition, since the current between the base and emitter ends of the second transistor Q2 decreases, the emitter current of the second transistor Q2 decreases, so that the emitter current is the contrast current I _CON . 53 is introduced into the contrast terminal.

As described above, when the current flowing into the flyback transformer 51 increases, the contrast decreases as the contrast current I _CON supplied to the contrast terminal of the video preamplifier 53 decreases, thereby darkening the screen as a whole. In this case, when the variable resistor VR is adjusted, the contrast current I _CON increases and decreases, thereby adjusting the brightness of the screen.

On the contrary, when the current I ₁ output to the flyback transformer 51 decreases, the above operation is reversed.

However, when the ABL circuit is uniformly applied to the normal mode and the low resolution mode, the brightness of the screen in the low resolution mode becomes darker overall. This is because the signal level is smaller than the video signal that is supported.

That is, the ABL circuit should include a super bright circuit for brightening the screen in the low resolution mode. The brightness control circuit of the monitor to which the conventional super bright circuit 50 is applied is shown in FIG. 2.

Here, the microcomputer 54 outputs a high level super bright signal in the normal mode and a low level super bright signal in the super bright mode.

When the monitor is in the normal mode, the microcomputer 54 outputs a high level super bright signal, which causes the third transistor Q3 to be turned on so that the collector stage and the emitter stage of the third transistor Q3 are short-circuited. .

At this time, as the current I ₂ increases, the potential of the node 'A' decreases, and the current I ₃ increases to increase the current between the base and emitter terminals of the first transistor Q1 and the second transistor. As the current between the base and emitter ends of Q2 decreases, the contrast current I _CON decreases, resulting in a lower contrast of the screen.

In addition, when the monitor is in the super bright mode, when the microcomputer 54 outputs the low level super bright signal, the third transistor Q3 is turned off, and thus the potential of the node 'A' becomes relatively high.

That is, the current I ₃ decreases to decrease the current between the base and emitter ends of the first transistor Q1, and the current between base and emitter ends of the second transistor Q2 increases to increase the contrast current I _CON . When the increased contrast current (I _CON ) flows into the contrast terminal of the video amplifier as described above, the overall screen becomes brighter as the contrast increases.

However, in the conventional super bright circuit, since the breakdown voltage of the third transistor, which is a switching element, is very small, a failure of the third transistor frequently occurs in a normal mode in which a high level is output from the microcomputer. There is a problem that can not be used.

Accordingly, an object of the present invention is to provide a brightness control circuit of a monitor to which a super bright circuit is applied, which is more stable and inexpensive.

The brightness control circuit of the monitor according to the present invention for achieving the above object, the ABL circuit for adjusting the brightness of the entire screen according to the magnitude of the anode current flowing on the CRT screen, and the control signal to the ABL circuit in the super bright mode In the brightness control circuit of the monitor equipped with a super bright circuit for outputting the brightness of the entire screen to increase,

The super bright circuit may include a microcomputer that outputs a high level super bright signal in a super bright mode,

An eleventh transistor turned on when a high level super bright signal is output from the microcomputer;

A twelfth transistor and a thirteenth transistor biased to reduce the emitter current when the eleventh transistor is turned on;

When the emitter current of the thirteenth transistor is decreased, the ABL circuit is driven to increase the luminance of the entire screen.

1 is a circuit diagram showing a general automatic brightness limit circuit;

2 is a circuit diagram showing a conventional brightness control circuit;

3 is a circuit diagram illustrating a brightness control circuit of the monitor according to the present invention.

* Names of symbols for main parts of the drawings

10: Super Bright Circuit 11: Micom

Q11, Q12, Q13: transistor

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

Figure 2 is a circuit diagram showing a brightness control circuit of the monitor according to the present invention, which is an ABL circuit for adjusting the brightness of the entire screen according to the magnitude of the anode current flowing in the CRT screen, and controlled by the ABL circuit in the super bright mode It is composed of a super bright circuit 10 for outputting a signal to increase the brightness of the entire screen.

Here, since the ABL circuit has the same configuration as the prior art and performs the same operation as the prior art, a detailed description of the configuration will be omitted.

The super bright circuit 10 may include a microcomputer 11 that outputs a high level super bright signal in a super bright mode, an eleventh transistor Q11 that is turned on when a high level signal is output from the microcomputer 11; In addition, when the eleventh transistor Q11 is turned on, the emitter current is biased to reduce the emitter current. The emitter terminal of the third transistor Q13 is a node. It is connected to 'A'.

Referring to the operation and effects of the present invention configured as described above are as follows.

First, the microcomputer 11 outputs a low level super bright signal when the monitor is in the normal mode, and outputs a high level super bright signal when the monitor is in the super bright mode.

That is, when the monitor is in the normal mode, the microcomputer 11 outputs a low-level super bright signal to the eleventh transistor Q11, thereby keeping the eleventh transistor Q11 in a turn off state.

When the eleventh transistor Q11 is turned off, the base current of the twelfth transistor Q12 increases and the base current of the thirteenth transistor Q13 increases, so that the emitter current of the thirteenth transistor Q13 increases. Done.

At this time, when the emitter current of the thirteenth transistor Q13 increases, the potential of the node 'A' decreases, and as the current I ₃ increases, the emitter current of the first transistor Q1 increases and the second As the emitter current of transistor Q2 decreases, the contrast of the screen decreases, so that the screen becomes dark overall.

On the other hand, when the monitor is in the super bright mode, the microcomputer 11 outputs a high level super bright signal and the eleventh transistor Q11 is turned on.

When the eleventh transistor Q11 is turned on, a part of the base current of the twelfth transistor Q12 flows between the collector terminal and the emitter terminal of the eleventh transistor Q11 so that the base current of the twelfth transistor Q12 decreases. As a result, emitter currents of the twelfth transistor Q12 and the thirteenth transistor Q13 are reduced.

At this time, when the emitter current of the thirteenth transistor Q13 decreases, the potential of the node 'A' becomes high. As a result, the base current and the emitter current of the first transistor Q1 decrease and the second transistor Q2. ), The base current and emitter current increase, increasing the contrast of the screen.

In this case, when the screen becomes too bright in the super bright mode, the microcomputer 11 may output the low level super bright signal to turn off the eleventh transistor Q11 to maintain the brightness of the screen to a certain degree.

As described above, the present invention enables a microcomputer to output a low level super bright signal in a normal mode and a high level super bright signal in a super bright mode to implement a stable super bright mode and at the same time In the bright mode, the brightness of the screen may be limited to a certain degree by adjusting the super bright signal.

Claims (1)

ABL circuit for controlling the brightness of the entire screen according to the magnitude of the anode current flowing in the CRT screen, and a super bright circuit for outputting a control signal to the ABL circuit in the super bright mode to increase the brightness of the entire screen In the brightness control circuit, The super bright circuit may include a microcomputer that outputs a high level super bright signal in a super bright mode, An eleventh transistor turned on when a high level super bright signal is output from the microcomputer; A second transistor and a third transistor biased to reduce emitter current when the eleventh transistor is turned on, And the ABL circuit is driven to increase the luminance of the entire screen when the emitter current of the third transistor is decreased.