JP2008242354A - Display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device capable of preventing image quality from disturbances due to external light in a portable apparatus assumed to be used outdoors and capable of achieving fine color tones. <P>SOLUTION: A self-light-emitting display device is provided with R (red), G (green) and B (blue) light intensity sensors for detecting light intensity of environmental light and a color temperature during white display is controlled so that the color tone of reflected light from the surface of a display panel 8 is canceled, on the basis of information detected by respective light intensity sensors. Consequently, even when reflected light of external light exists, an image can be displayed by a color tone that should be displayed by right. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a display device having a light intensity sensor.

  In recent years, mobile devices having a small flat panel display such as a mobile phone and a music player are becoming popular. Such portable devices are sometimes used in places with very large environmental illuminance, such as under direct sunlight in midsummer, and it is required to display images with high brightness on the mounted flat panel display. On the other hand, such high-intensity display is not necessary for indoor use. For this reason, Patent Document 1 discloses a display device that adjusts the brightness of a display in accordance with ambient environmental illuminance from the viewpoint of low power consumption and the like.

JP-A-5-241512

  In a portable device assumed to be used outdoors, an antireflection film may be provided on the outermost surface in order to prevent interference with image quality due to external light. Such an antireflection film is often designed to suppress reflection of light in the vicinity of a wavelength of 550 nm corresponding to green, which has the highest human visibility, and light of other wavelengths may not be able to prevent reflection. .

  Therefore, the blue or purple component of the reflected light may be superimposed on the display image, and display quality may be deteriorated.

  In addition, outside light changes not only in illuminance but also in color. For example, sunlight near noon has a color called daylight color or daytime white, but it becomes reddish in the evening. When the white color displayed on the display is observed in such a place, human vision is affected by the color temperature of ambient light.

  Therefore, even if the display performs the same white display, it may be felt as a white display with an unnatural color due to a difference in ambient light conditions.

  The present invention has been made in view of such problems, and an object thereof is to provide a display device capable of realizing a good color.

As a means for solving the problems of the background art, a display device according to the invention described in claim 1 includes:
In a self-luminous display device,
It is provided with at least one light intensity sensor for detecting the light intensity of ambient light, and a plurality of color signals are independently controlled based on information detected by the light intensity sensor. .

  The display device according to the present invention can realize a good color.

  The wavelength characteristics related to the reflection of external light on the surface of the display device are determined by the material and surface treatment of the surface of the display device. Therefore, if the spectral characteristic of external light can be detected in some form, the spectral characteristic of reflected light can be calculated.

  The present invention has been made based on this finding.

  Hereinafter, the best mode for carrying out the present invention will be described.

<First Embodiment>
The display device of this embodiment is a display device formed on a substrate using a self-luminous organic EL element as a display element.

  As shown in FIG. 1, this display device includes light intensity sensors for each color of R (red), G (green), and B (blue) that detect the light intensity of ambient light, and the light intensity sensor detects the light intensity sensor. The plurality of color signals are independently controlled based on the information.

  More specifically, the R light intensity sensor 1 outputs a signal having a level corresponding to the light intensity of the red component of the ambient light. This signal is converted into a red signal Rin4 by the A / D converter 7 and output to the LUT 9. The Similarly, in the G light intensity sensor 2 and the B light intensity sensor 3, the green signal Gin5 and the blue signal Bin6 are output to the LUT 9, respectively.

  Information output to the LUT 9 is processed by the LUT 9 as follows.

  The color signals of the above RGB colors indicate the intensity of each color component, and are converted into the XYZ color system defined in the CIE 1931 color system by the following <Equation 1>.

  In addition, each coefficient from a11 to a33 in <Equation 1> may be set appropriately according to the spectral characteristics of the R light intensity sensor 1, the G light intensity sensor 2, and the B light intensity sensor 3.

  Next, using the obtained XYZ values, chromaticity coordinates xyz are obtained by <Equation 2>.

  Further, r is the surface reflectance of the display panel 8, and the value of XYZ in <Equation 1> is used, and the value of the reflected light X'Y'Z 'of ambient light on the surface of the display panel 8 is obtained from <Equation 3>. Ask.

Conversion functions f _r (K), f _g (K), and f _b (K), which are conversion coefficients of the RGB video signal, are set so as to cancel the interference caused by the surface reflection.

The conversion functions f _r (K), f _g (K), and f _b (K) set in the LUT 9 are output to a power supply device that supplies power to the display panel 8, and the RGB video signals input to the display panel 8 Rvideo, Gvideo, and Bvideo are modulated.

In other words, Rvideo, Gvideo, and Bvideo, which are RGB video signals, are converted into R′video and G′video by <Equation 4> using conversion functions f _r (K), f _g (K), and f _b (K), respectively. , B'video.

The conversion functions f _r (K), f _g (K), and f _b (K) are set so as to cancel the interference caused by the surface reflection as described above. That is, the color temperature at the time of white display is controlled so as to cancel the color tone of the reflected light on the surface of the display panel 8 calculated by the light intensity detected by the light intensity sensors 1 to 3 of each color. Therefore, even when there is reflected light due to external light, it is possible to display with a color that should originally be displayed.

<Second Embodiment>
The display device according to the present embodiment is a back-emitting type display device including a backlight 10 incorporating a plurality of color light sources (not shown).

  As shown in FIG. 2, the display device includes light intensity sensors for each of the RGB colors that detect the light intensity of the ambient light. Based on the information detected by the light intensity sensor, the display device includes a plurality of light source colors. The light intensity is modulated independently.

  Specifically, the display panel 8 and the backlight 10 of the display device are stacked, and RGB video signals Rvideo, Gvideo, and Bvideo are input to the display panel 8 and corresponding images are displayed.

  The backlight 10 includes light sources corresponding to RGB colors therein, and the color temperature of the backlight 10 can be changed by changing the intensity of each light source.

For example, when an LED light source is used, the intensity of each light source can be changed by current modulation. In view of this, the display device according to the present embodiment applies the conversion functions f _r (K), f _g (K), and f _b (K) set in the LUT 9 to the backlight 10 as in the first embodiment. Output to the power supply that supplies power. Then, the current amounts of the power supply currents 11, 12, and 13 corresponding to the RGB light sources of the backlight 10 are modulated according to the color temperature of the ambient light, and the color temperature of the backlight 10 is adjusted.

  Thereby, the light emitted from the light source in the backlight 10 is modulated by the display panel 8 and can be displayed in a color to be originally displayed.

<Third Embodiment>
In the first and second embodiments described above, the display device provided with the light intensity sensors independent of each color of RGB to cope with various environmental lights has been described. However, if the environment of use can be assumed to some extent, for example, it is mainly used during the daytime outdoors, and the wavelength characteristics of the ambient light can be assumed, it depends on the assumed ambient light as shown in FIG. The structure may be simplified by using only one light intensity sensor having wavelength characteristics. That is, it is sufficient to provide at least one light intensity sensor.

<Fourth Embodiment>
The first to third embodiments include the light intensity sensor and the A / D converter for calculating the reflected light due to the external light. The color temperature of the external light is calculated using this configuration as it is. be able to. That is, the color tone of the environmental light is calculated based on the light intensity of each color of the environmental light detected by the light intensity sensor, and the color temperature at the time of white display is controlled according to the calculated color tone of the environmental light.

  Specifically, the relationship between the xyz value obtained by the above <Equation 2> and the color temperature is 1: 1 as illustrated in “Color Engineering” (Noboru Ohta: 1993, University of Tokyo Press). Therefore, the color temperature K of the ambient light is calculated by the light intensity sensor.

Next, Rvideo, Gvideo, and Bvideo, which are RGB video signals, are converted using the conversion functions f _r (K), f _g (K), and f _b (K) derived from the color temperature K of the ambient light to < Conversion into R'video, G'video, and B'video, respectively, is made using Equation 3>. The conversion functions f _r (K), f _g (K), and f _b (K) detect the color temperature K ′ of white display on the surface of the display panel 8 when Rvideo, Gvideo, and Bvideo have the maximum values. It is set to be higher than the color temperature K of ambient light by about 2500K to 3500K. Human vision changes how white display is perceived depending on the color temperature of ambient light, but when the white display is observed at a color temperature 2500 to 3500K higher than the color temperature of ambient light, it feels good white display Because there are many. In order to suppress power consumption in the room, conversion functions f _r (K), f _g (K), and f _b (K) that suppress display luminance in a low illuminance environment may be set.

Next, the values of the conversion coefficients f _r (K), f _g (K), f _b (K) are calculated for all possible combinations of RGB color signals 4, 5, 6 of the ambient light, and the LUT 9 Is stored in a memory (not shown). This is to simplify the actual circuit by calculating in advance before shipping. Alternatively, a plurality of combinations of calculation values corresponding to the RGB values of a specific ambient light may be prepared, and other combinations may be generated by interpolation using a calculator provided in the LUT 9.

  It is more preferable that an antireflection film is provided on the surface of the display device of the first to fourth embodiments.

It is a block diagram of a self-luminous type display device in the case of including light intensity sensors for each of RGB colors. It is a block diagram of a back emission type display device provided with light intensity sensors for each of RGB colors. It is a block diagram of a display apparatus at the time of providing one light intensity sensor.

Explanation of symbols

1 R light intensity sensor 2 G light intensity sensor 3 B light intensity sensor 4 Red signal Rin
5 Green signal Gin
6 Blue signal Bin
7 A / D converter 8 Display panel 9 LUT (Look Up Table)
10 Backlight 11 R Power supply current 12 G Power supply current 13 B Power supply current

Claims (7)

In a self-luminous display device,
It is provided with at least one light intensity sensor for detecting the light intensity of ambient light, and a plurality of color signals are independently controlled based on information detected by the light intensity sensor. , Display device. In a back-emitting display device with a backlight incorporating light sources of multiple colors,
At least one light intensity sensor for detecting the light intensity of ambient light is provided, and the light intensity of the light sources of a plurality of colors is independently modulated based on information detected by the light intensity sensor. A display device.   The color temperature at the time of white display is controlled so as to cancel the color tone of the reflected light on the surface of the display device, which is calculated based on the light intensity of the ambient light detected by the light intensity sensor. The display device according to claim 1 or 2.   The color tone of the ambient light is calculated based on the light intensity of each color of the ambient light detected by the light intensity sensor, and the color temperature at the time of white display is controlled according to the calculated color tone of the ambient light. The display device according to claim 1 or 2.   5. The display device according to claim 1, wherein the color temperature at the time of white display is controlled at a color temperature higher by about 2500 to 3500 K than the detected color temperature of the ambient light. .   The display device according to claim 1, wherein an organic EL element is used as a display element.   The display device according to any one of claims 1 to 6, further comprising an antireflection film on a surface of the display device.

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