JP5242048B2 - LED backlight system and initialization method thereof - Google Patents

Description

  The present invention relates to an LED backlight system that feedback-controls the color and brightness of an LED backlight and an initialization method thereof.

Conventionally, it is known that a plurality of red (R), green (G), and blue (B) LED elements are arranged to constitute an LED backlight serving as a light source of a liquid crystal panel.
However, the LED backlight has a problem that color (chromaticity) and brightness (luminance) change due to deterioration with time and heat generation. In addition, there is a problem that the variation in characteristics between LED elements constituting the LED backlight is large.

  That is, even when the same current is passed through the LED element, the amount of light emission changes due to deterioration with time and heat generation, so that the luminance changes. Further, if the ratio of the change in the amount of light emission regarding the LED elements of each color of red (R), green (G) and blue (B) is different, the mixing ratio of red (R), green (G) and blue (B) is different. For example, the chromaticity changes to bluish white or the like.

  Therefore, in order to correct changes in chromaticity and luminance due to deterioration with time and heat generation, the chromaticity and luminance of the LED backlight are feedback-controlled (hereinafter referred to as “LED backlight color feedback”) ( For example, see Patent Document 1).

Hereinafter, color feedback of the LED backlight will be described with reference to FIG.
FIG. 2 is a block diagram showing a general LED backlight system and an LED backlight initialization system (described later).
In FIG. 2, this LED backlight system is connected to an LED backlight 20 configured by arranging a plurality of LED elements 1, a color sensor 3 attached to the LED backlight 20, and the LED backlight 20. LED drivers 4 </ b> A to 4 </ b> C that drive the LED element 1, a controller 50 that includes the comparison calculation unit 7 and controls the LED drivers 4 </ b> A to 4 </ b> C, and a storage element 60 (storage means) connected to the controller 50. .

The LED backlight 20 is configured by arranging a plurality of red (R), green (G) and blue (B) LED elements 1. Further, the color sensor 3 detects the chromaticity and luminance of the LED backlight 20 and outputs them to the controller 50 as a color sensor output. The LED drivers 4A to 4C drive the red (R), green (G), and blue (B) LED elements 1 respectively.
Here, the color sensor 3 is a passive element and has little change in characteristics due to deterioration with time and heat generation. The storage element 60 is a non-volatile memory such as an EEPROM.

Further, the controller 50 compares the color sensor output from the color sensor 3 with the target value (initial setting value) of the color sensor 3 stored in advance in the storage element 60 by the comparison calculation unit 7.
Subsequently, the controller 50 drives the LED elements 1 of red (R), green (G), and blue (B) for the LED drivers 4 </ b> A to 4 </ b> C based on the comparison result in the comparison calculation unit 7. PWM signals to be output are respectively output, and the chromaticity and luminance of the LED backlight 20 are feedback-controlled.

Next, consider the variables of this LED backlight system. The variables of the LED backlight system can include the light emission amount of the LED backlight 20, the color sensor output from the color sensor 3, and the PWM signal from the controller 50.
At this time, the light emission amount can be expressed as the PWM signal multiplied by the coefficient α, and the color sensor output can be expressed as the light emission amount multiplied by the coefficient β.

  Here, even when the controller 50 outputs a constant PWM signal to the LED drivers 4A to 4C, the amount of light emitted from the LED backlight 20 varies due to variations in characteristics between the LED elements 1. In addition, since there is a variation in characteristics between the color sensors 3 (about ± 30%), a variation in the light emission amount of the LED backlight 20 cannot be detected by the color sensor 3.

Therefore, it is necessary to set (initialize) the target value of the color sensor 3 for each LED backlight system.
Therefore, conventionally, the LED backlight 20 to which the color sensor 3 is attached is imaged by using a camera, and the PWM signal output from the controller 50 to the LED drivers 4A to 4C is changed based on the imaging result, thereby the LED backlight. 20 chromaticity and brightness are adjusted.
When the chromaticity and brightness of the LED backlight 20 reach desired values, the color sensor output at that time is stored in the storage element 6 as the target value of the color sensor 3.

Next, initialization of the LED backlight system will be described.
When the LED backlight 20 is initialized, the PC 50 is connected to the controller 50 in FIG. 2, and the camera 9 is connected to the PC 8 to configure an initialization system for the LED backlight 20.

The camera 9 images the LED backlight 20 to which the color sensor 3 is attached and outputs an imaging signal to the PC 8.
The PC 8 processes the imaging signal from the camera 9 and outputs an operation command for changing the PWM signal to the controller 50 based on the processing result.

Next, the operation of the initialization system having the above configuration will be described.
First, the LED backlight 20 emits light with an appropriate PWM signal from the controller 50.
Next, the emitted LED backlight 20 is imaged by the camera 9, and the imaging signal is input to the PC 8.

Subsequently, the PC 8 processes the imaging signal and outputs an operation command for changing the PWM signal to the controller 50 so that the chromaticity and luminance of the LED backlight 20 become desired values based on the processing result. To do.
Hereinafter, when the imaging by the camera 9 and the change of the PWM signal according to the operation command from the PC 8 are repeated, when the chromaticity and luminance of the LED backlight 20 reach desired values, the controller 50 detects the color sensor at that time. The output is stored in the storage element 6 as the target value of the color sensor 3.

JP 2006-119268 A

  In the conventional LED backlight initialization system, it is necessary to set the target value of the color sensor using a camera for each LED backlight system, and there is a problem that the number of processes increases and the cost increases.

  An object of the present invention is to solve the above-described problems, and an object of the present invention is to provide an LED backlight system and an initialization method thereof that can simplify the process and realize cost reduction. It is to provide.

An LED backlight system according to the present invention includes an LED backlight configured by arranging a plurality of red, green, and blue LED elements that are pre-sorted and uniformed in color and brightness, and an LED backlight A color sensor for detecting each of color and brightness; an LED driver connected to the LED backlight for driving the LED element; a controller for controlling the LED driver; and storage means connected to the controller. When the LED backlight is first turned on, the LED backlight emits light with a predetermined PWM signal , and the detection value of the color sensor when the LED backlight emits light is stored in the storage means as the target value of the color sensor. When the backlight is turned on for the first time, the external control Initializing signal is inputted to the over la or in response to the on state of the setting pins provided in the controller, the controller, and outputs an initialization signal in the LED driver.

  According to the LED backlight system and the initialization method thereof according to the present invention, attention is paid to the fact that the current LED element can reduce the variation between the LED elements by selecting the chromaticity and the luminance. Since the step of setting the target value of the color sensor using can be omitted, the step can be simplified and the cost can be reduced.

Embodiment 1 FIG.
Hereinafter, the first embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram showing an LED backlight system according to Embodiment 1 of the present invention.
In FIG. 1, an LED backlight 2 is configured by arranging a plurality of red (R), green (G), and blue (B) LED elements 1 each of which is preliminarily selected and uniformed in chromaticity and luminance. Has been. The controller 5 receives an initialization signal from the outside when the LED backlight 2 is first turned on.
Other configurations are the same as those in FIG.

Next, the operation of the LED backlight system having the above configuration will be described.
First, when the LED backlight 2 is first turned on, an initialization signal is input from the outside to the controller 5, and the LED backlight 2 emits light under a predetermined condition (predetermined PWM signal) that is arbitrarily set.
At this time, the LED backlight 2 is composed of the LED elements 1 in which chromaticity and luminance are preliminarily selected and uniformed, and thus emits light with desired chromaticity and luminance.

Next, the chromaticity and luminance of the LED backlight 2 are detected by the color sensor 3 and output to the controller 5 as a color sensor output.
Subsequently, the controller 5 automatically stores the color sensor output at this time as the target value of the color sensor 3 in the storage element 6.

According to the LED backlight system and the initialization method thereof according to Embodiment 1 of the present invention, the LED backlight 2 is configured by using the LED element 1 in which the chromaticity and the luminance are preliminarily selected and uniformed, and the LED backlight By storing the color sensor output from the color sensor 3 when the light 2 emits light under a predetermined condition in the storage element 6 as the target value of the color sensor 3, the target value of the color sensor 3 is obtained using the camera. The step of setting can be omitted.
Therefore, by incorporating the initialization process of the LED backlight system into the display check process of the LED backlight 2, for example, the process can be simplified and the cost can be reduced.

In the first embodiment, the initialization signal is input to the controller 5 when the LED backlight 2 is first turned on. However, the present invention is not limited to this. The controller 5 may output an initialization signal to the LED driver when the power is turned on with a setting pin (not shown) provided in the controller 5 being on (high).
Also in this case, the same effect as in the first embodiment can be obtained.

It is a block diagram which shows the LED backlight system which concerns on Embodiment 1 of this invention. It is a block diagram which shows the general LED backlight system and the initialization system of LED backlight.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 LED element, 2 LED backlight, 3 Color sensor, 4A-4C LED driver, 5 Controller, 6 Memory element (memory | storage means), 7 Comparison calculating part.

Claims (3)

An LED backlight in which a plurality of red, green, and blue LED elements whose colors and brightness are preselected and uniformed are arranged,
A color sensor for detecting the color and brightness of the LED backlight,
An LED driver connected to the LED backlight and driving the LED element;
A controller for controlling the LED driver;
Storage means connected to the controller,
The controller causes the LED backlight to emit light with a predetermined PWM signal when the LED backlight is first turned on, and the detection value of the color sensor when the LED backlight is emitted to the target of the color sensor Stored as a value in the storage means ,
In response to an initialization signal input to the controller from the outside at the first power-on of the LED backlight or an ON state of a setting pin provided in the controller, the controller sends an initialization signal to the LED driver. LED backlight system, characterized in that An LED backlight comprising a plurality of red, green, and blue LED elements that are pre-sorted and uniformed in color and brightness; and
A color sensor for detecting the color and brightness of the LED backlight,
An LED driver connected to the LED backlight and driving the LED element;
A controller for controlling the LED driver;
A method of initializing an LED backlight system comprising storage means connected to the controller,
Causing the LED backlight to emit light with a predetermined PWM signal when the LED backlight is first turned on;
Detecting the color and brightness of the LED backlight when emitting the LED backlight,
See containing and storing the detected value of the color sensor in the storage means as a target value of the color sensor,
In response to an initialization signal input to the controller from the outside at the first power-on of the LED backlight or an ON state of a setting pin provided in the controller, the controller sends an initialization signal to the LED driver. Is output, and the LED backlight system is initialized. The LED backlight system initialization method according to claim 2, wherein the LED backlight system is incorporated in a display check process of the LED backlight.

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