KR20000008555U - LCD backlight brightness circuit - Google Patents

Abstract

The present invention relates to an LCD backlight brightness control circuit, the LCD backlight used in the prior art to perform a specific switching signal to perform only the on / off function, causing unnecessary battery waste due to excessive light source at night,

The present invention aims to limit the amount of unnecessary current flowing into the backlight, so that the user can set the time zone according to night and day, and when the backlight of the LCD is turned on / off, the current time is In this case, the brightness of the backlight is reduced so that the excessive light source is not emitted in the dark environment, thereby eliminating user's visual fatigue, prolonging the battery life and stabilizing the system by reducing power consumption. Make sure

Description

LCD backlight brightness circuit

The present invention relates to an LCD backlight brightness control circuit, and more specifically, to reduce the power consumption of the backlight (Backlight) installed on the side of the LCD panel by changing the brightness at a predetermined time, the battery due to unnecessary brightness The present invention relates to an LCD backlight brightness control circuit which increases the efficiency of a system by extending the battery life of an LCD-equipped device so that power is not wasted.

In general, the display of the device uses a lot of the LCD because the power consumption is very low in the display method by the liquid crystal. In addition, since the liquid crystal device is a non-light emitting body, the disadvantage of having to turn on a separate backlight (or a pilot lamp, etc.) at night is highlighted.

Then, the device is installed with the backlight, for example, with respect to the lamp driving of the mobile phone or pager, with reference to the illustrated drawings in detail as follows.

First attached to Figure 1 is a conventional LED backlight driving circuit using a mobile phone as an example, a plurality of backlights 71 are installed on both sides or the rear (depending on the device) of the LCD panel 70 made of a predetermined pattern of liquid crystal elements have.

These backlights 71 are connected in parallel, one side is connected to the power supply terminal and the other side is connected to the switching unit 72, and then again the switching unit 72 applies a separate power source for driving a small number of elements It is configured to receive a control signal from the controller 73 so as to be patterned to receive the signal, and to perform a predetermined switching control by a specific signal.

The controller 73 supplies a negative pulse as a control signal depending on whether the key panel 74 is operated.

On the other hand, the switching unit 72 is provided with a transistor TR10 for allowing the emitter side to earth through the resistor R20 after one terminal of the backlight 71 and the collector side are connected, and the transistor TR10 is provided. The resistor R10 is connected to the base side of the. The other end of the resistor R10 is connected to the collector side of the transistor TR20, the emitter side of the transistor TR20 is connected to the driving power source Vcc, and the base side is earthed through the capacitor C10. Thereafter, the capacitor C10 and the base side are connected to the control unit 73 via a resistor R30.

The operation of the circuit based on such a configuration will now be described.

First, when a user presses a key to make a call through the key panel 74, the key signal generated therefrom is applied to the control unit 73 to prepare for transmission through a transmission unit (not shown), and the control unit 73 The negative pulse is supplied to the switching unit 72 for a predetermined time.

Accordingly, the switching signal of the switching unit 72 turns on the backlight 71 so that the call data currently input by the user can be easily identified. The operation of the switching unit 72 will be described. As follows.

When a negative pulse is supplied from the controller 73 for a predetermined time, the low-level signal discharges the charge charge of the capacitor C10 through the resistor R30. As a result, the base side of the PNP transistor TR20 is kept at a low level, and the driving power supply Vcc is supplied to the collector side via the emitter side of the transistor TR20.

Therefore, the power supplied to the collector side is applied to the base side of the NPN transistor TR10 through the resistor R10, so that the transistor TR10 remains turned on. Then, the lamp power Vcc supplied to the plurality of parallel-connected backlights 71 is turned on through the turned-on transistor TR10 and the protection resistor R20, and the backlight 71 is turned on.

Then, when the user inputs data through the key panel, it is easy to identify the data displayed by the LCD due to the lighting of the backlight, but it is necessary to differentiate in bright and dark places. That is, in a dark place, the lighting state of the backlight is too bright to be a waste of power, it is difficult to implement a stable system, and the problem that does not provide the ease of use as much power consumption.

The present invention was devised to solve such a problem, and by adjusting the power consumption of the backlight from the time data already set according to the day and night, the brightness of the light transmitted through the LCD panel is weakened when the device is used at night. The purpose of the present invention is to provide an LCD backlight brightness control circuit capable of not only wasting unnecessary light sources, but also preventing excessive power from the system, thereby achieving stable circuits.

The present invention for achieving the above object is a clock supply unit for supplying a pulse of a fixed period, a memory unit for storing the time data formed from the output pulse of the clock supply unit, the brightness control signal according to the storage time of the memory unit A control unit for outputting a; and a switching unit for changing the amount of current flowing into the backlight by the output signal of the control unit.

1 is a view showing a conventional LCD backlight on / off circuit,

2 is a circuit diagram according to the present invention.

<Explanation of symbols for main parts of drawing>

1: LCD 2: Backlight

3: first switching part 4: second switching part

5 control unit 6 memory unit

7: Key Panel 8: Clock Supply Unit

R1-R3: Resistor TR1: NPN transistor

TR2, TR3: PNP type transistor C: capacitor

Then described in detail based on the accompanying drawings illustrating the configuration of the present invention made as described above.

2 is a circuit diagram illustrating the present invention, and a plurality of backlights 2 are provided on both sides or rear surfaces (depending on the device) of an LCD panel 1 formed of a liquid crystal element having a predetermined pattern.

These backlights 2 are connected in parallel, one side of which is connected to the power supply terminal and the other side of which is connected to the first switching unit 3, and then again the first switching unit 3 is a separate for driving a small number of elements At the same time, the control signal is transmitted from the control unit 5 and the second switching unit 4 so that a predetermined switching control is performed by a specific signal.

When a predetermined pulse signal is received from the clock supply unit 8 connected to the input port of one side of the control unit 5, and predetermined time data is formed therefrom, it is stored through the memory unit 6. The control signal of the control part 5 is output by the data and the key signal of the key panel 7.

On the other hand, the first switching unit 3 is provided with a transistor TR1 for allowing the emitter side to earth through the resistor R1 after one terminal of the backlight 2 and the collector side are connected, and the transistor ( The resistor R2 is connected to the base of TR1. The other end of the resistor R2 is connected to the collector side of the transistor TR2, the emitter side of the transistor TR2 is connected to the driving power supply Vcc, and the base side is earthed through a capacitor C. Thereafter, the capacitor C and the base side are connected to one port of the control unit 5 via a resistor R3.

In addition, the second switching unit 4 allows the resistor R4 to be connected between the resistor R2 and the transistor TR1, and the other end of the resistor R4 is connected to the collector side of the PNP transistor TR3. At the same time, the emitter side of the transistor TR3 is connected to the collector side of the transistor TR2, and then the base side of the transistor TR3 is connected to one control port of the control unit 5.

Then explaining the operation of the present invention made of such a configuration as follows.

First, the user sets a time zone corresponding to day and night through the key panel 7, and this setting signal is applied through an input port of the controller 5 to store time data in the memory unit 6. . Since the control unit 5 is already receiving the current time by the clock pulse which has been continuously supplied through the clock supply unit 8, the control unit 5 compares the previously set time data with the present time.

At this time, when the user presses a key of the key panel 7 to make a call, the controller 5 outputs a control signal from the comparison between the current time and the already set time data. That is, it is determined whether the time when the key is pressed is night, and the control signal is applied to the second switching unit 4, and at the same time, the control is performed by the first switching unit 3 regardless of the time zone according to the key input. Apply a signal.

For example, if the time when the key is pressed on the key panel 7 is a night set by the user, the control signal of the controller 5 outputs a low level signal for a predetermined time to the first switching unit 3, and the second switching unit (4) outputs a high level signal.

Then, the low level flowing into the first switching unit 3 discharges the charge charge of the capacitor C connected to the base side of the transistor TR2 through the resistor R3, and finally, the PNP transistor TR2. The base side is turned on to a low level. Therefore, the power supplied to the emitter side of the transistor TR2 is transmitted to the collector side, and is supplied in parallel to the emitter side of the resistor R2 and the transistor TR3.

However, since the high level signal is applied to the base side of the transistor TR3, the power applied through the collector side of the transistor TR2 is supplied to the base side of the transistor TR1 via the resistor R2 only. Therefore, the NPN transistor TR1 is turned on, and the backlight 2 forms a current pattern through the resistor R1 through the transistor TR1.

As a result, the amount of current applied to the backlight 2 is determined from the resistance of the resistor R2 and switched to a state where the brightness is decreased for a predetermined time.

On the other hand, when the user applies the key signal to the control unit 5 through the key panel 7, if the current time corresponds to the day of the already set time data, the low level signal to the first switching unit 3 described above. Is outputted, and the second switching unit 4 also applies a low level signal for a predetermined time.

As a result, the transistor TR2 and the transistor TR3 are turned on, and the power applied through the transistor TR2 is supplied to the resistor R2 and the resistor R4 through the transistor TR3. Therefore, the power is supplied in parallel to the resistor R2 and the resistor R4 so that a current proportional to the synthesized resistance is introduced into the base side of the transistor TR1.

Here, the synthesized resistance value Z may be represented by (R2 · R4) / (R2 + R4), which is further divided by R2 / (R2 / R4 + 1) to be smaller than the resistance value of the resistor R2. . That is, the base-side applied current of the transistor TR1 is increased through the resistor R4, and the amount of current flowing into the backlight 2 is increased, and the brightness thereof is increased.

On the other hand, if the system is turned off from the above-described key panel 7 or if a predetermined time has elapsed from the key input signal, the control signal of the controller 5 is sent to the first switching unit 3 and the second switching unit 4. By outputting a high level signal, the transistors TR2 and TR3 are turned off to cut off the power supply to the backlight 2.

As described above, the present invention connects a second switching unit capable of changing a backlight supply current in an LCD backlight driving circuit, and adds a clock supply unit for supplying predetermined time data and a memory unit for storing data. By controlling the system according to the incoming signal at the same time, the brightness of the backlight can be changed according to the day and night when using the device, thereby avoiding unnecessary power waste caused by excessive light source at night In addition, the stability of the system due to the stabilization of power is improved.

Claims (2)

In the LCD backlight driving circuit having a backlight (2) mounted on the LCD (1) and a first switching unit (3) for driving the same When predetermined time data according to the night and day standards are set, the memory unit 6 for storing the time data, the clock supply unit 8 for counting the present time, and the current time detected from the clock supply unit 8 are already present. The controller 5 outputs a control signal for attenuating the brightness of the backlight 2 when it is determined to be night based on the set time data, and receives the output signal of the controller 5 to change the brightness of the backlight 2. LCD backlight brightness control circuit, characterized in that consisting of a second switching unit (4) connected to the first switching unit (3) to enable. The resistor of claim 1, wherein the second switching unit 4 is connected in parallel to reduce the amount of current flowing into the brightness adjusting resistor R2 of the first switching unit 3 according to the switching signal of the controller 5. And a transistor (TR3) provided between the resistor (R4) and the resistor (R2) to switch according to the parallel connection from the control signal of the control unit (5). Brightness control circuit.