JPWO2006088118A1 - Display control device and display device - Google Patents

Abstract

  A red light sensor 222D, a green light sensor 232D, and a blue light sensor 242D are arranged on the LCD panel 200 of the display device 100. The processing unit 170 of the display device 100 causes the LCD correction control unit 173 to detect the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D based on the state of the external light, and the red light sensor 222D in the LCD panel 200. The display state of the image at the position corresponding to the green light sensor 232D and the blue light sensor 242D is corrected.

Description

  The present invention relates to a display control device and a display device for adjusting a display state of an image on a display means.

  Conventionally, there is known a display control device that performs so-called dimmer control that adjusts the brightness of the display device according to light from the outside (hereinafter, referred to as external light) (see, for example, Patent Document 1).

  In the device described in Patent Document 1, a reading cycle of a digital value obtained by converting the output of an optical sensor for detecting external light is set in a memory in advance depending on the environment in which it is used. In this way, the read cycle is adjusted and changed according to the use environment, thereby adjusting the adjustment speed of the brightness of the backlight with respect to the external light.

Japanese Unexamined Patent Publication No. 2001-142446 (page 4, left column-page 4, right column)

  However, in the above-described configuration, the display state of the entire display area may be adjusted to be substantially the same by adjusting the brightness of the backlight. Therefore, for example, when strong external light is emitted to only a part of the display area, the display state of only the area irradiated with the external light is appropriately adjusted, and the display state of the area not irradiated with the external light is changed. As an example, there is a problem that it may not be properly adjusted.

  An object of the present invention is to provide a display control device and a display device capable of appropriately adjusting the display state of an image on a display means.

  The display control device of the present invention is a display control device that adjusts the display state of an image on the display means, and is arranged at a predetermined position in the display area of the display means to control the state of incident external light. It is characterized by comprising: a light state detecting means for detecting; and a display state adjusting means for adjusting the display state of the image at the predetermined position based on the state of the light from the outside.

  A display device of the present invention is characterized by including display means for displaying an image and the display control device of the present invention described above.

It is a block diagram which shows schematic structure of the display apparatus which concerns on one embodiment of this invention. It is a schematic diagram which shows the schematic structure of the LCD panel in the said one Embodiment. FIG. 3 is a schematic diagram showing a schematic configuration of a red subpixel, a green subpixel, and a blue subpixel in the one embodiment. 7 is a flowchart showing a video display process in the embodiment. 6 is a graph showing a red sensor value in each pixel when red external light T is incident on the one embodiment. 6 is a graph showing a green sensor value in each pixel when red external light T is incident on the one embodiment. 6 is a graph showing a blue sensor value in each pixel when red external light T is incident on the one embodiment. 6 is a flowchart showing an LCD correction process in the one embodiment. It is a block diagram which shows schematic structure of the display apparatus which concerns on other embodiment of this invention.

Explanation of symbols

100,300 display device 110 display unit 170 which is a display unit 170 processing unit which constitutes a display control device 171 sensor average value calculation unit 172 which also functions as a display state adjustment unit 172 backlight correction control unit 173 as a display state adjustment unit 173 image form LCD correction control means as display state adjusting means which also functions as recognition means 180 Backlight as irradiation means 200 LCD panel as display area 210 Pixels that are pixels 220 Red subpixel 222C as first liquid crystal element Red transmission means Color filter 222D as a display control device and a red light sensor 223 as a first light intensity detecting means constituting a light state detecting means 223 a liquid crystal 230 a green subpixel 232C as a second liquid crystal element 232C a color filter 232D as a green transmitting means Green light sensor as second light intensity detecting means constituting display control device and light state detecting means 240 Blue sub-pixel 242C as third liquid crystal element 242C Color filter 242D as blue transmitting means Display control device and light state detecting means Light sensor as third light intensity detecting means constituting the

  An embodiment according to the present invention will be described below with reference to the drawings. In the present embodiment, a display device including the display control device of the present invention will be described as an example of a configuration that is mounted on a moving body such as a vehicle and that displays map information, store information, television images, or the like. The display device is not limited to the configuration mounted on the vehicle, but may be any configuration for displaying various information, such as a configuration arranged in a home or a factory. FIG. 1 is a block diagram showing a schematic configuration of a display device. FIG. 2 is a schematic diagram showing a schematic configuration of the LCD panel. FIG. 3 is a schematic diagram showing a schematic configuration of a red subpixel, a green subpixel, and a blue subpixel.

[Configuration of display device]
In FIG. 1, 100 is a display device. The display device 100 appropriately displays a video based on a video signal output from a video signal output device (not shown). In addition, the display device 100 appropriately corrects the display state of the image based on, for example, the light of a streetlight incident from the outside of the display device 100, the headlight of another vehicle (hereinafter referred to as external light), or the like. The display device 100 includes a display unit 110 which is a display unit, a video signal processing unit 120, a gamma correction unit 130, a correction processing unit 140, an A/D (Analog/Digital) conversion unit 150, and a memory 160. And a processing unit 170, and the like.

  The display unit 110 is connected to the correction processing unit 140 and the A/D conversion unit 150, and appropriately displays a video based on the video signal from the video signal output device. The display unit 110 includes a backlight 180 as an irradiation unit, an LCD (Liquid Crystal Display) unit 190, and the like.

  The backlight 180 is formed in a substantially rectangular plate shape, and appropriately irradiates a predetermined light from the back surface of the LCD unit 190 toward the LCD unit 190 under the control of the correction processing unit 140. Specifically, the backlight 180 acquires from the correction processing unit 140 an irradiation light setting signal indicating that red, green, and blue light having predetermined light amounts are emitted according to the external light. Then, the light corresponding to the irradiation light setting signal is emitted toward the LCD unit 190. The surface of the backlight 180 on the side where the light is output is referred to as the surface of the backlight 180 for description.

  The LCD unit 190 appropriately displays an image using the light of the backlight 180 under the control of the correction processing unit 140. The LCD unit 190 includes an LCD panel 200 as a display area, a signal line driving circuit 250, a scanning line driving circuit 260, and the like.

  As shown in FIG. 2, the LCD panel 200 is formed in a substantially rectangular plate shape in which the horizontal direction is longer than the vertical direction, and is arranged on the front surface side of the backlight 180. The LCD panel 200 includes pixels 210 that are N in the horizontal direction and M in the vertical direction (N and M are natural numbers), and are (N×M) pixels arranged side by side. ing. Here, the pixel 210 existing at the Pth in the horizontal direction and the Qth in the vertical direction with the upper left end in FIG. 2 of the LCD panel 200 as a base point will be appropriately referred to as a (P, Q) pixel 210 and described. Under the control of the correction processing unit 140, the pixel 210 adjusts the transmission state of the light emitted from the backlight 180 and outputs the light in a predetermined color. The pixel 210 includes a red sub-pixel 220 as a first liquid crystal element, a green sub-pixel 230 as a second liquid crystal element, and a blue sub-pixel as a third liquid crystal element, which are arranged side by side in the lateral direction. Sub-pixels 240, and so on. In the following, since the red subpixel 220, the green subpixel 230, and the blue subpixel 240 have substantially the same structure, only the red subpixel 220 will be described in detail, and the green subpixel 230 and the blue subpixel 230 will be described. The description of the sub-pixel 240 is simplified.

  The red sub-pixel 220 appropriately outputs the light from the backlight 180 in red with a predetermined intensity. As shown in FIG. 3, the red subpixel 220 includes a first substrate unit 221, a second substrate unit 222, a liquid crystal 223, and the like.

  The first substrate portion 221 is adjacent to the surface of the backlight 180. The first substrate portion 221 has a first glass substrate 221A having substantially the same shape as the substantially rectangular shape of the LCD panel 200. A surface of the first glass substrate 221A on the backlight 180 side (hereinafter, referred to as one side) has, for example, a first glass substrate 221A having a substantially same shape as that of the first glass substrate 221A and polarizing the light in a predetermined direction. Polarizing plates 221B are stacked. Further, a counter electrode 221C is provided on the other surface of the first glass substrate 221A. Further, on the other side of the counter electrode 221C, for example, a first alignment film 221D, which has substantially the same shape as the first glass substrate 221A and which arranges the molecules of the liquid crystal 223 in a certain direction, is laminated.

  The second substrate portion 222 is arranged on the other side of the first substrate portion 221. The second substrate portion 222 has a second glass substrate 222A having substantially the same shape as the first glass substrate 221A. On the other surface of the second glass substrate 222A, for example, a second glass substrate 222A having the substantially same shape as the second glass substrate 222A and polarizing the light in a direction substantially orthogonal to the polarization direction of the first polarizing plate 221B. Polarizing plates 222B are laminated. Further, a color filter 222C as a red color red transmitting means is laminated on one surface of the second glass substrate 222A. Further, on one surface of the color filter 222C, a red light sensor 222D as a first light intensity detecting unit, a TFT (Thin Film Transistor) 222E, and a pixel electrode 222F are arranged side by side in one direction. Has been done.

  The red light sensor 222D is connected to the A/D conversion unit 150, as shown in FIG. Further, as shown in FIG. 3, the red light sensor 222D includes a light receiving surface 222D1 provided on the color filter 222C side and receiving external light incident through the color filter 222C, and a surface opposite to the light receiving surface 222D1. And a mask 222D2 which is provided in the above and shields the light incident from the backlight 180. Then, the red light sensor 222D detects the intensity of the light that has been received by the light receiving surface 222D1 and has passed through the color filter 222C, that is, the intensity of red light included in the external light, and converts the detected intensity into the red sensor value Or. , As analog signals to the A/D converter 150. The source of the TFT 222E is connected to the signal line driving circuit 250, the drain is connected to the pixel electrode 222F, and the gate is connected to the scanning line driving circuit 260. When the gate signal is input from the scanning line driving circuit 260, the TFT 222E causes the signal line driving circuit 250 to apply a predetermined voltage to the pixel electrode 222F and the counter electrode 221C. In addition, a second alignment film 222G is arranged on one side of the mask 222D2, the TFT 222E, and the pixel electrode 222F so that the molecules of the liquid crystal 223 are aligned in a fixed direction substantially orthogonal to the direction in which the first alignment film 221D is aligned. There is.

  The liquid crystal 223 is provided between the first alignment film 221D and the second alignment film 222G. The molecules of the liquid crystal 223 are twisted by about 90° by the first alignment film 221D and the second alignment film 222G, that is, the backlight 180, in a state where no voltage is applied to the pixel electrode 222F and the counter electrode 221C. It is arranged so that the light of is not transmitted. When a predetermined voltage is applied to the pixel electrode 222F and the counter electrode 221C, the molecules of the liquid crystal 223 are arranged in a direction along the electric field, that is, the light of the backlight 180, according to the predetermined voltage. Changes to a transparent state. As a result, the red sub-pixel 220 appropriately transmits the light of the backlight 180 in a state according to the voltage by the liquid crystal 223 and outputs it as red light having a predetermined intensity via the color filter 222C.

  The green sub-pixel 230 appropriately outputs the light from the backlight 180 in green with a predetermined intensity. The green subpixel 230 includes a first substrate unit 221, a second substrate unit 232, a liquid crystal 223, and the like. On the second glass substrate 222A of the second substrate section 232, a color filter 232C as a green-colored green transmitting unit is laminated. Further, the color filter 232C is provided with a green light sensor 232D as a second light intensity detecting means, a TFT 232E, and a pixel electrode 232F. The green light sensor 232D has a light receiving surface 232D1 and a mask 232D2, detects the intensity of green light contained in the external light received by the light receiving surface 232D1, converts this intensity into a green sensor value Og, and outputs it. Further, the green sub-pixel 230 outputs the light of the backlight 180 as green light of a predetermined intensity via the color filter 232C according to the voltage applied to the pixel electrode 232F and the counter electrode 221C.

  The blue sub-pixel 240 appropriately outputs the light from the backlight 180 in blue with a predetermined intensity. The blue sub-pixel 240 includes the first substrate unit 221, the second substrate unit 242, the liquid crystal 223, and the like. On the second glass substrate 222A of the second substrate portion 242, a color filter 242C as a blue transmitting unit for blue is laminated. Further, the color filter 242C is provided with a blue light sensor 242D as a third light intensity detecting unit, a TFT 242E, and a pixel electrode 242F. The blue light sensor 242D has a light receiving surface 242D1 and a mask 242D2, detects the intensity of blue light contained in the external light received by the light receiving surface 242D1, converts this intensity into a blue sensor value Ob, and outputs it. Furthermore, the blue sub-pixel 240 outputs the light of the backlight 180 as blue light of a predetermined intensity via the color filter 242C according to the voltage applied to the pixel electrode 242F and the counter electrode 221C.

  Then, the pixel 210 outputs light of a color obtained by combining red, green, and blue lights of predetermined intensities output from the red subpixel 220, the green subpixel 230, and the blue subpixel 240. The red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D constitute the light state detecting means of the present invention.

  The signal line drive circuit 250 is connected to the sources of the TFTs 222E, 232E, 242E as described above. Then, the signal line drive circuit 250 applies a predetermined voltage to the pixel electrodes 222F, 232F, 242F and the counter electrode 221C via the predetermined TFTs 222E, 232E, 242E. Specifically, the signal line driving circuit 250 includes red, green, and blue intensities corrected by the predetermined red sub-pixel 220, green sub-pixel 230, and blue sub-pixel 240 from the correction processing unit 140 according to external light. A color correction signal for outputting light is acquired. Further, a first specifying signal for specifying these red subpixel 220, green subpixel 230, and blue subpixel 240 is acquired. Then, a voltage corresponding to a red correction value Hr of the color correction signal, which will be described later, is applied to the pixel electrode 222F and the counter electrode 221C of the red sub-pixel 220 corresponding to the first specific signal via the TFT 222E. Further, the signal line drive circuit 250 applies a voltage corresponding to a green correction value Hg and a blue correction value Hb, which will be described later, of the color correction signal to the pixel electrodes 232F and 242F and the counter electrode 221C of the green subpixel 230 and the blue subpixel 240. Apply.

  The scanning line drive circuit 260 is connected to the gates of the TFTs 222E, 232E, 242E as described above. Then, the scanning line drive circuit 260 acquires from the correction processing unit 140 a second specific signal for specifying the red subpixel 220, the green subpixel 230, and the blue subpixel 240, and uses this as the second specific signal. A gate signal is appropriately output to the TFTs 222E, 232E, 242E of the corresponding red subpixel 220, green subpixel 230, and blue subpixel 240.

  The video signal processing unit 120 is connected to the gamma correction unit 130. Further, a video information output device (not shown) is detachably connected to the video signal processing unit 120. The video signal processing unit 120 acquires a video signal for displaying a video on the display unit 110 from the video information output device. Then, for example, the image quality adjustment processing for adjusting the video signal is appropriately performed in accordance with the brightness, contrast, color saturation, and the like preset by the user. The video signal processing unit 120 outputs the video signal to each pixel 210 by setting a red set value Sr1 corresponding to a red intensity setting, a green set value Sg1 corresponding to a green intensity setting, and a blue intensity setting. The color setting signal relating to the blue setting value Sb1 corresponding to is appropriately output to the gamma correction unit 130.

  The gamma correction unit 130 is connected to the correction processing unit 140 and the processing unit 170. The gamma correction unit 130 acquires a color setting signal from the video signal processing unit 120 and appropriately performs so-called gamma correction processing on the red setting value Sr1, the green setting value Sg1, and the blue setting value Sb1. Then, the gamma correction unit 130 sets the red set value Sr1, the green set value Sg1, and the blue set value Sb1 that have been subjected to the gamma correction process as a red adjustment value Sr2, a green adjustment value Sg2, and a blue adjustment value Sb2, respectively. The color adjustment signals regarding these are output to the correction processing unit 140 and the processing unit 170.

  The correction processing unit 140 is connected to the processing unit 170, and under the control of the processing unit 170 appropriately corrects the display state of the image on the display unit 110. The correction processing unit 140 includes a backlight drive unit 141, a level correction unit 142, and the like.

  The backlight drive unit 141 causes the backlight 180 to appropriately emit predetermined light. Specifically, the backlight driving unit 141 includes a red backlight light amount (hereinafter, referred to as a red BL light amount, which corresponds to red, green, and blue light amounts of light emitted from the processing unit 170 by the backlight 180 according to external light. Light amount signals regarding Lr, green backlight light amount (hereinafter, referred to as green BL light amount) Lg, and blue backlight light amount (hereinafter, referred to as blue BL light amount) Lb are appropriately acquired. Then, an irradiation light setting signal for setting the red, green, and blue light amounts of the light emitted by the backlight 180 to the red BL light amount Lr, the green BL light amount Lg, and the blue BL light amount Lb of the light amount signal is generated, Output to the backlight 180.

  The level correction unit 142 appropriately corrects the contrast and color tone of the image displayed on the LCD panel 200. Specifically, the level correction unit 142 acquires the color adjustment signal from the gamma correction unit 130. Further, from the processing unit 170, the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2 are appropriately corrected according to the external light, the red correction value Hr, the green correction value Hg, and the blue correction value Hr corresponding to red, green, and blue. A correction request signal for the correction to the correction value Hb is acquired. Then, the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2 are corrected to the red correction value Hr, the green correction value Hg, and the blue correction value Hb, and the red sub-pixel 220 and the green sub-value are corrected together with the color correction signals related thereto. A first specifying signal for specifying the pixel 230 and the blue sub-pixel 240 is output to the signal line driving circuit 250. In addition, a second identification signal for identifying the red subpixel 220, the green subpixel 230, and the blue subpixel 240 corresponding to the color correction signal is output to the scanning line drive circuit 260.

  The A/D conversion unit 150 is connected to the processing unit 170. The A/D conversion unit 150 acquires analog signals from the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D, and calculates the red sensor value Or, the green sensor value Og, and the blue sensor value Ob of these analog signals. The digital signal is converted and output to the processing unit 170.

  The memory 160 is connected to the processing unit 170. The memory 160 readablely stores various information necessary for video display processing. Further, the memory 160 stores various programs developed on an OS (Operating System) that controls the operation of the entire display device 100.

  The processing unit 170 includes various input/output ports (not shown) such as a gamma correction port to which the gamma correction unit 130 is connected, a BL drive port to which the backlight drive unit 141 is connected, and a level correction port to which the level correction unit 142 is connected. It has an A/D port to which the A/D converter 150 is connected, a memory port to which the memory 160 is connected, and the like. Then, the processing unit 170, as various programs, as shown in FIG. 1, a sensor average value calculation unit 171 that also functions as a display state adjustment unit, and a backlight correction control unit (hereinafter, BL correction) as the display state adjustment unit. (Referred to as control means) 172, LCD correction control means 173 as display state adjusting means that also functions as image form recognition means, and the like. The processing unit 170, the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D constitute a display control device of the present invention. Here, the display control device of the present invention may be configured not to include at least one of the sensor average value calculation means 171 and the BL correction control means 172.

  The sensor average value calculation means 171 calculates the average value of each of the red sensor value Or, the green sensor value Og, and the blue sensor value Ob per predetermined time as the red sensor average value Ar, the green sensor average value Ag, and the blue sensor average value Ab. Is calculated as appropriate. Specifically, the sensor average value calculation unit 171 acquires the red sensor value Or, the green sensor value Og, and the blue sensor value Ob output as digital signals from the A/D conversion unit 150 and stores them in the memory 160. .. Then, for example, the red sensor values Or corresponding to all the pixels 210 output from the A/D conversion unit 150 at a predetermined time are acquired from the memory 160, and the red sensor average value Ar of these red sensor values Or is calculated. Similarly, the green sensor average value Ag and the blue sensor average value Ab are calculated based on the green sensor value Og and the blue sensor value Ob corresponding to all the pixels 210.

  The BL correction control unit 172 controls to appropriately set the color of the light emitted by the backlight 180 according to the external light. Specifically, the BL correction control means 172 multiplies the red sensor average value Ar by the proportional constant Jr, and calculates the value obtained by adding the minimum light amount Kr of the red light output from the backlight 180 as the red BL light amount Lr. .. Further, a value obtained by multiplying the green sensor average value Ag and the blue sensor average value Ab by the proportional constants Jg and Jb and adding the minimum light amounts Kg and Kb of the green and blue of the backlight 180 is the green BL light amount Lg and the blue BL light amount Lb. Calculate as. Then, a light amount signal regarding the red BL light amount Lr, the green BL light amount Lg, and the blue BL light amount Lb is generated and output to the backlight drive unit 141.

  The LCD correction control unit 173 controls the operations of the red sub-pixel 220, the green sub-pixel 230, and the blue sub-pixel 240 of each pixel 210 to adjust the contrast and color tone of the image displayed on the LCD panel 200 according to the external light. Control to set. Specifically, the LCD correction control unit 173 acquires a color adjustment signal from the gamma correction unit 130 and stores the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2 in the memory 160. Then, the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2 are set as the red correction value Hr, the green correction value Hg, and the blue correction value Hb. Further, the red sensor value Or corresponding to the red sub-pixel 220 of the predetermined pixel 210 is acquired from the memory 160, and the value obtained by dividing the red sensor value Or by the red sensor average value Ar is calculated as the red relative value Dr. Further, the green relative value Dg and the blue relative value Db of the green subpixel 230 and the blue subpixel 240 corresponding to the red subpixel 220 are calculated in the same manner as the red relative value Dr. Then, when it is recognized that all of the red relative value Dr, the green relative value Dg, and the blue relative value Db are within the allowable range, for example, 0.9 to 1.1, the pixel 210 is out of contrast or color tone. It is judged that there is almost no change due to light and there is no need for correction. Note that the allowable range is not limited to the above range, and may be other ranges such as 0.7 to 1.3 and 0.8 to 1.4 as appropriate. Then, a correction request signal regarding the set red correction value Hr, green correction value Hg, and blue correction value Hb is output to the level correction unit 142.

  Further, when the LCD correction control means 173 recognizes that at least one of the red relative value Dr, the green relative value Dg, and the blue relative value Db is not within the allowable range, the contrast of the pixel 210 and the external light of the color tone. It is judged that the change due to is necessary to be largely corrected. Further, based on the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2, the brightness X before correction (hereinafter referred to as pixel brightness X) according to the external light in this pixel 210 is calculated. The pixel brightness X is less than a preset value, that is, the light output state based on the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2 of the pixel 210, that is, the light emission state is set in advance. When it is recognized that the pixel 210 is darker than the above, it is determined that the contrast of the display image is reduced due to the reflection of the external light in the pixel 210, and the contrast correction process is performed. Specifically, when the LCD correction control unit 173 recognizes that the red relative value Dr is larger than 1.1 which is the upper limit value, the value obtained by multiplying the red adjustment value Sr2 by the proportional constant Cr and the red relative value Dr is used. Calculate Then, this value is reset as the red correction value Hr. That is, when recognizing that the intensity of red light of the external light incident on the pixel 210 is 10% or more higher than the average intensity of the red light incident on all the pixels 210, the red light emission intensity of the pixel 210 is increased. Process to increase the contrast. When recognizing that the green relative value Dg and the blue relative value Db are larger than the upper limit values, the green adjustment value Sg2 and the blue adjustment value Sb2 are multiplied by the proportional constants Cg and Cb and the green relative value Dg and the blue relative value Db. The values are reset as the green correction value Hg and the blue correction value Hb.

  Further, when the LCD correction control unit 173 recognizes that the pixel brightness X is equal to or higher than the set value, that is, the light emitting state of the pixel 210 is brighter than the preset state, the color tone changes due to the reflection of external light in the pixel 210. Is determined to be large, color tone correction processing is performed. Specifically, when the LCD correction control unit 173 recognizes that the red relative value Dr is larger than the upper limit value, the red correction value Hr is a value obtained by multiplying the red adjustment value Sr2 by the proportional constant Ir and the red relative value Dr. Reset as. That is, when it is recognized that the intensity of red light incident on this pixel 210 is 10% or more higher than the average intensity of red light incident on all pixels 210, the red light emission intensity of this pixel 210 is reduced to adjust the color tone. To process. When recognizing that the green relative value Dg and the blue relative value Db are larger than the upper limit value, the green adjustment value Sg2 and the blue adjustment value Sb2 are multiplied by the proportional constants Ig and Ib and the green relative value Dg and the blue relative value Db. The values are reset as the green correction value Hg and the blue correction value Hb. Then, the LCD correction control unit 173 outputs to the level correction unit 142 a correction request signal regarding the red correction value Hr, the green correction value Hg, and the blue correction value Hb set by the contrast and color tone correction processing.

[Operation of display device]
Next, as an operation of the display device 100, a video display process will be described with reference to the drawings. Here, a display process of an image when red external light T (hereinafter, referred to as red external light T) as shown in FIG. 2 is incident on the LCD panel 200 will be described as an example. FIG. 4 is a flowchart showing a video display process. FIG. 5A is a graph showing a red sensor value in each pixel when red external light T is incident, and FIG. 5B is a graph showing a green sensor value in each pixel when red external light T is incident. Yes, FIG. 5C is a graph showing a blue sensor value in each pixel when red external light T is incident. FIG. 6 is a flowchart showing the LCD correction process.

  First, in the display device 100, when the video signal processing unit 120 acquires a video signal of a predetermined video output from the video signal output device, the red light sensor 222D of all the pixels 210 is incident on the LCD panel 200. The intensity of red light contained in the light is detected. Further, the green light sensor 232D and the blue light sensor 242D of all the pixels 210 detect the intensities of the green light and the blue light included in the outside light. Then, in the processing unit 170, the sensor average value calculating unit 171 as shown in FIG. 4, the red sensor value Or corresponding to the intensity of light detected by the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D, respectively. , Green sensor value Og and blue sensor value Ob are recognized (step S101).

  Here, since the sensor average value calculating unit 171 receives the red external light T as shown in FIG. 2 on the LCD panel 200, the red external light T is incident as shown in FIG. 5A, for example ( The red sensor value Or of the pixel 210 such as (1,1), (1,2), (1,3), (2,1) does not enter the red external light T (1,4), (1,N). ), etc., is recognized as being extremely larger than the red sensor value Or of the pixel 210. Further, for example, as shown in FIGS. 5B and 5C, it is recognized that the green sensor value Og and the blue sensor value Ob of all the pixels 210 are substantially the same.

  After that, the sensor average value calculation means 171 calculates the red sensor average value Ar, the green sensor average value Ag, and the blue sensor average value Ab (step S102). In the processing unit 170, the BL correction control unit 172 determines the red BL light amount Lb, the green BL light amount Lg, and the blue BL light amount Lb based on the red sensor average value Ar, the green sensor average value Ag, and the blue sensor average value Ab. The calculation is performed (step S103). Then, the display device 100 irradiates the backlight 180 with the light whose red, green, and blue light amounts are set to the red BL light amount Lb, the green BL light amount Lg, and the blue BL light amount Lb toward the LCD panel 200 (step. S104). After that, the processing unit 170 performs the LCD correction processing (step S105) and ends the video display processing.

  On the other hand, in the LCD correction process, as shown in FIG. 6, the processing unit 170 causes the LCD correction control unit 173 to set the variable Q to 1 (step S201) and the variable P to 1 (step S202). ). Further, the gamma correction unit 130 performs gamma correction processing or the like to set the red setting value Sr1, the green setting value Sg1, the blue setting value Sb1 of each pixel 210 based on the video signal to the red adjustment value Sr2, the green adjustment value Sg2, Set as blue adjustment value Sb2. Then, the LCD correction control unit 173 sets the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2 of the (P, Q) pixel 210 as the red correction value Hr, the green correction value Hg, and the blue correction value Hb. Yes (step S203). Then, it is determined whether or not all of the red relative value Dr, the green relative value Dg, and the blue relative value Db of (P, Q) are within the allowable range (step S204).

  When it is determined in step S204 that all are within the allowable range, the level correction unit 142 sets the red, green, and blue pixels 210 of (P, Q) to the red correction value Hr and the green correction value Hg, respectively. The color corresponding to the blue correction value Hb is emitted (step S205). Here, when the process of step S205 is performed after the process of step S204, the red correction value Hr, the green correction value Hg, and the blue correction value Hb are set to the red adjustment value Sr2, the green adjustment value Sg2, and the blue adjustment value Sb2. The emitted light, that is, the color of which the intensity of each color is not corrected, is emitted. Then, the LCD correction control means 173 adds 1 to the variable P (step S206), and determines whether or not the variable P is N or less (step S207). If it is determined in step S207 that the number is N or less, the process returns to step S203. On the other hand, if it is determined in step S207 that it is not N or less, 1 is added to the variable Q (step S208), and it is determined whether this variable Q is M or less (step S209). If it is determined in step S209 that the value is M or less, the process returns to step S202. On the other hand, if it is determined in step S209 that it is not equal to or less than M, the LCD correction process ends. Further, in step S204, when the LCD correction control unit 173 determines that at least one of the red relative value Dr, the green relative value Dg, and the blue relative value Db is not within the allowable range, the (P, Q) It is determined whether the pixel brightness X of the pixel 210 is less than a set value (step S210).

  If it is determined in step S210 that the red relative value Dr is less than the set value, it is determined whether the red relative value Dr is greater than the upper limit value (step S211). When it is determined in step S211 that the value is larger than the upper limit value, the red correction value Hr is set based on the proportional constant Cr (step S212), and it is determined whether the green relative value Dg is larger than the upper limit value. (Step S213). On the other hand, if it is determined in step S211 that it is not larger than the upper limit value, the process of step S213 is performed. When it is determined in step S213 that it is larger than the upper limit value, the green correction value Hg is set based on the proportional constant Cg (step S214), and it is determined whether the blue relative value Db is larger than the upper limit value (step S214). S215). On the other hand, if it is determined in step S213 that it is not larger than the upper limit value, the process of step S215 is performed. When it is determined in step S215 that the value is larger than the upper limit value, the blue correction value Hb is set based on the proportional constant Cb (step S216), and the process of step S205 is performed. On the other hand, if it is determined in step S215 that it is not larger than the upper limit value, the process of step S205 is performed.

  Here, as shown in FIGS. 5A, 5B, and 5C, since the red sensor value Or of the pixel 210 on which the red external light T is incident is larger than the upper limit value, the pixel brightness X of the pixel 210 whose pixel brightness X is less than the set value is Among them, the red correction value Hr of the pixel 210 on which the red external light T is incident is corrected to a value larger than the red adjustment value Sr2 based on the proportional constant Cr. Further, since the red sensor value Or of the pixel 210 to which the red external light T is not incident is smaller than the upper limit value, the red correction value Hr of the pixel 210 to which the red external light T is not incident among the pixels 210 whose pixel brightness X is less than the set value. Is not corrected. Further, since the green sensor value Og and the blue sensor value Ob of all the pixels 210 whose pixel brightness X is less than the set value are smaller than the upper limit value, the green correction value Hg and the blue correction value Hb of the pixel 210 are not corrected. Then, among the pixels 210 having the pixel brightness X less than the set value, the pixel 210 to which the red external light T is incident is caused to emit light in a color corrected so that only the intensity of red is increased. Further, among the pixels 210 whose pixel brightness X is less than the set value, the pixels 210 to which the red external light T is not incident are caused to emit light in the colors of which the intensities of the respective colors are not corrected.

  When it is determined in step S210 that the pixel brightness X is equal to or greater than the set value, it is determined whether the red relative value Dr is larger than the upper limit value (step S217). When it is determined in step S217 that it is larger than the upper limit value, the red correction value Hr is set based on the proportionality constant Ir (step S218), and it is determined whether the green relative value Dg is larger than the upper limit value (step S218). S219). On the other hand, if it is determined in step S217 that it is not larger than the upper limit value, the process of step S219 is performed. If it is determined in step S219 that it is larger than the upper limit value, the green correction value Hg is set based on the proportional constant Ig (step S220), and it is determined whether the blue relative value Db is larger than the upper limit value (step S220). S221). On the other hand, if it is determined in step S219 that it is not larger than the upper limit value, the process of step S221 is performed. When it is determined in step S211 that the value is larger than the upper limit value, the blue correction value Hb is set based on the proportional constant Ib (step S222), and the process of step S205 is performed. On the other hand, if it is determined in step S221 that it is not larger than the upper limit value, the process of step S205 is performed.

  Here, the red correction value Hr of the pixel 210 to which the red external light T is incident among the pixels 210 whose pixel brightness X is equal to or higher than the set value is corrected to a value smaller than the red adjustment value Sr2 based on the proportionality constant Ir. Further, the red correction value Hr of the pixel 210 to which the red external light T is not incident among the pixels 210 having the pixel brightness X equal to or higher than the set value is not corrected. Further, the green correction value Hg and the blue correction value Hb of all the pixels 210 whose pixel brightness X is the set value or more are not corrected. Then, among the pixels 210 having the pixel brightness X equal to or higher than the set value, the pixels 210 to which the red external light T is incident are caused to emit light in a color corrected so that only the intensity of red is reduced. Further, among the pixels 210 having the pixel brightness X equal to or higher than the set value, the pixels 210 to which the red external light T is not incident are caused to emit light in the colors whose intensities of the respective colors are not corrected.

[Operation and effect of display device]
As described above, in the above-described embodiment, the red light sensor 222D, the green light sensor 232D, and the blue light sensor, which detect the state of external light such as the headlight of another vehicle, are displayed on the LCD panel 200 of the display device 100. And 242D. Then, the processing unit 170 of the display device 100 causes the LCD correction control unit 173 to detect the red light sensor of the LCD panel 200 based on the state of the external light detected by the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D. The display state of the image at the positions corresponding to 222D, the green light sensor 232D, and the blue light sensor 242D is corrected. For this reason, in the display device 100, when the red external light T as shown in FIG. 2 is incident on the LCD panel 200, the red light sensor 222D, the green light sensor 232D, and the blue light sensor 232D at the positions where the red external light T is incident. Based on the detection state of the red outside light T in the optical sensor 242D, the display state of the image only at the position where the red outside light T is incident can be corrected. Further, since the display device 100 directly detects the state of the external light incident on the LCD panel 200 by the red light sensor 222D or the like arranged on the LCD panel 200, for example, the LCD panel around the LCD panel 200 or the like. The state of outside light can be detected more appropriately as compared with the configuration in which the state of the outside light incident on the LCD panel 200 is detected by the sensor arranged at a position separated from 200. Therefore, the display device 100 can appropriately adjust the display state of the image.

  Further, the LCD correction control unit 173 calculates the pixel brightness X before correction according to the external light in each pixel 210. Then, the LCD correction control unit 173 displays the image based on the external light detection states of the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D, and the pixel brightness X, that is, the light emission state of the pixel 210 before correction. Correct the display status. Therefore, the display device 100 can correct the display state of the image according to the light emission state of the pixel 210 before correction according to the external light, that is, the brightness of the image before correction according to the external light. Therefore, the display device 100 can more appropriately adjust the display state of the image.

  Further, when the LCD correction control unit 173 recognizes that the pixel brightness X is less than the set value, that is, that the light emitting state of the pixel 210 is darker than the preset state, the contrast is reflected by the outside light in the pixel 210. Will be dropped. Then, a contrast correction process is performed to increase the light emission intensity of the color corresponding to the color of the external light in the pixel 210. For example, when the red external light T is incident on the pixel 210 corresponding to the dark portion of the image, the contrast correction process for increasing the red emission intensity of the pixel 210 is performed. For this reason, in the display device 100, even when external light is incident on a dark portion of an image, that is, even when external light is incident in a state where the contrast of the image is reduced, the contrast of the dark portion is not deteriorated. You can correct the image to the state. Therefore, the display device 100 can adjust the display state of the image more appropriately.

  When the LCD correction control unit 173 recognizes that the pixel brightness X is equal to or larger than the set value, that is, the light emitting state of the pixel 210 is brighter than the preset state, the color tone is reflected by the external light reflected by the pixel 210. Is determined to change significantly. Then, a color tone correction process is performed to reduce the emission intensity of the color corresponding to the color of the external light in the pixel 210. For example, when the red external light T is incident on the pixel 210 corresponding to the bright part of the image, the color tone correction process is performed to reduce the red light emission intensity of the pixel 210. For this reason, the display device 100 changes the color tone of the bright portion of the image even when the external light is incident on the bright portion of the image, that is, even when the external light is incident in a state where the change of the color tone of the image is large. You can correct the image in a suppressed state. Therefore, the display device 100 can adjust the display state of the image more appropriately.

  Further, the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D are arranged at a plurality of different positions on the LCD panel 200, respectively. Therefore, the display device 100 can correct the light emitting states at all the positions in this region according to the external light even when the external light is incident on the region including the plurality of positions. Further, even when external light of different colors is incident on a plurality of spaced positions, the light emitting states at the plurality of positions can be corrected according to the external light. Therefore, the display device 100 can adjust the display state of the image more appropriately.

  Further, a red light sensor 222D, a green light sensor 232D, and a blue light sensor 242D are arranged in the pixel 210. Therefore, the display device 100 can more finely adjust the display state of the image by correcting the light emission state for each pixel 210.

  Further, a red light sensor 222D, a green light sensor 232D, and a blue light sensor 242D are respectively arranged in the red subpixel 220, the green subpixel 230, and the blue subpixel 240 whose light emission state can be corrected by the liquid crystal 223. That is, the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D are arranged on the LCD panel 200. Therefore, it is possible to provide the LCD panel 200 capable of appropriately adjusting the display state of the image.

  Then, the LCD panel 200 transmits the light from the backlight 180 through the red subpixel 220, the green subpixel 230, and the blue subpixel 240, and outputs the light as red, green, and blue light. Further, the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D detect the red, green, and blue intensities of the external light incident on the red subpixel 220, the green subpixel 230, and the blue subpixel 240, respectively. Then, the LCD correction control unit 173 outputs the red color from the red subpixel 220, the green subpixel 230, and the blue subpixel 240 based on the intensities of the respective colors detected by the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D. Set the intensity of green, blue. Therefore, the display device 100 can appropriately adjust the display state of the color image. Further, it is possible to provide a so-called transmissive LCD panel 200 capable of appropriately adjusting the display state of a color image.

  Further, the BL correction control unit 172 corrects the state of the light emitted by the backlight 180 based on the state of the external light detected by the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D. Therefore, the display device 100 can finely correct the light emission state of the pixel 210 by correcting the light transmission state of the liquid crystal 223 and the light state of the light emitted by the backlight 180. Therefore, the display device 100 can further finely adjust the display state of the image.

  Then, the sensor average value calculation means 171 uses the red sensor value Or, the green sensor value Ob, and the red sensor average value Ar of the red sensor 222D, the green sensor 232D, and the blue sensor 242D respectively detected by the red sensor 222D, the green sensor 242D, and the blue sensor Ob. The average value Ag and the blue sensor average value Ab are calculated. Further, the LCD correction control means 173 divides the red sensor value Or, the green sensor value Ob, and the blue sensor value Ob corresponding to the predetermined pixel 210 by the red sensor average value Ar, the green sensor average value Ag, and the blue sensor average value Ab. The calculated red relative value Dr, green relative value Dg, and blue relative value Db are calculated. Then, when the LCD correction control means 173 recognizes that the red relative value Dr, the green relative value Dg, and the blue relative value Db are within the allowable range, that is, the color of the external light incident on the predetermined pixel 210 and the LCD panel. When it is recognized that the average color of the external light incident on the light 200 is substantially the same, the light transmission state in the liquid crystal 223 of the pixel 210 is not corrected. On the other hand, if the BL correction control unit 172 recognizes that the color of the external light incident on the predetermined pixel 210 and the average color of the external light incident on the LCD panel 200 are substantially the same, the backlight 180 is turned on. Correct the condition of the applied light. Therefore, in the display device 100, the color of the external light incident on the predetermined pixel 210 is substantially the same as the average color of the external light incident on the LCD panel 200, and the light emission state of the predetermined pixel 210 is changed to other values. If the pixel 210 can be corrected in the same manner, the light emission state of each pixel 210 can be similarly corrected by correcting the state of the light emitted by the backlight 180. Therefore, the display device 100 can more easily correct the light emission state of the entire screen as compared with the configuration in which the light transmission state of the liquid crystal 223 of each pixel 210 is corrected.

[Modification of Embodiment]
It should be noted that the present invention is not limited to the above-described embodiment, and also includes the modifications described below within the range in which the object of the present invention can be achieved.

  That is, the display device 100 that outputs the color setting signal processed by the video signal processing unit 120 to the gamma correction unit 130 and outputs the color adjustment signal corrected by the gamma correction unit 130 to the level correction unit 142 will be described. However, as shown in FIG. 7, the display device 300 may output the color setting signal processed by the video signal processing unit 120 to the correction processing unit 140 and the processing unit 170. In the case of such a configuration, the level correction unit 142 in the correction processing unit 140 acquires the color setting signal from the video signal processing unit 120, and according to the correction request signal from the processing unit 170, the red setting value Sr1 and the green setting value. Sg1 and blue setting value Sb1 are corrected to red correction value Hr, green correction value Hg, and blue correction value Hb corresponding to red, green, and blue, which are appropriately corrected according to the external light, and the color correction signals related to these are corrected to gamma. Output to the correction unit 130. Then, the gamma correction unit 130 performs gamma correction processing on the color correction signal and outputs it to the signal line driving circuit 250 together with the first specific signal, and outputs the second specific signal for the color correction signal to the scanning line driving circuit. It will be output to 260.

  Further, the display state of the image may not be corrected based on the light emission state of the pixel 210 before correction according to the external light. For example, when a predetermined pixel 210 is irradiated with red external light T, the control is performed to increase or decrease the red light emission intensity of the pixel 210 regardless of the light emission state of the pixel 210 before correction. May be In the case of such a configuration, if it is determined in step S204 that at least one of the red relative value Dr, the green relative value Dg, and the blue relative value Db is not within the allowable range, the processing or steps of steps S211 to S216 are performed. The processing from S217 to S222 is performed. Therefore, the processing load in the LCD correction processing can be reduced. Further, it is not necessary to provide the LCD correction control unit 173 with a function for calculating the pixel brightness X, and the configuration of the LCD correction control unit 173 can be simplified.

  Then, when the external light is incident on the dark portion of the image, the contrast correction processing on the dark portion may not be performed. In the case of such a configuration, when it is determined in step S210 that the pixel brightness X of the (P, Q) pixel 210 is less than the set value, the process of step S205 is performed. Therefore, the processing load in the LCD correction processing can be reduced. Further, since it is not necessary to provide the LCD correction control unit 173 with a function for performing the contrast correction processing, the configuration of the LCD correction control unit 173 can be simplified.

  Further, when the external light is incident on the bright portion of the image, the color tone correction process in the bright portion may not be performed. In the case of such a configuration, if it is determined in step S210 that the pixel brightness X of the (P, Q) pixel 210 is equal to or greater than the set value, the process of step S205 is performed. Therefore, the processing load in the LCD correction processing can be reduced. Further, since it is not necessary to provide the LCD correction control unit 173 with a function for performing the color tone correction process, the configuration of the LCD correction control unit 173 can be simplified.

  Then, for example, when increasing the red emission intensity of the pixel 210, the green and blue emission intensities are reduced and the red emission intensity is relatively increased without increasing the absolute value of the red emission intensity. May be Further, for example, when the emission intensity of green of the pixel 210 is reduced, the emission intensity of red and blue is increased and the emission intensity of green is relatively reduced without decreasing the absolute value of the emission intensity of green. May be Even with such a configuration, the display device 100 allows the predetermined part of the image to be captured even if external light is incident on the predetermined part in a state where the contrast is lowered or the color tone is greatly changed. The contrast and color tone correction processing can be performed in the same manner as in the above-described embodiment, and the image display state can be appropriately adjusted.

  Further, for example, the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D may be arranged only at predetermined positions on the LCD panel 200. Even with such a configuration, it is possible to correct the display state of the image at a predetermined position where the red light sensor 222D and the like are arranged according to external light. Therefore, the display device 100 can appropriately adjust the image display state as compared with the conventional configuration in which the image display state is adjusted only by adjusting the brightness of the backlight.

  The red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D may be configured as below without being arranged between the liquid crystal 223 and the color filters 222C, 232C, 242C. That is, the red, green, and blue colors are provided on the front surface side of the LCD panel 200 with respect to the color filters 222C, 232C, and 242C, for example, between the front surface of the LCD panel 200 and the second glass substrate 222A and the second polarizing plate 222B. A sensor for detecting the light intensity may be provided. Further, one sensor for detecting the intensities of red, green, and blue may be arranged on the surface side of the red sub-pixel 220 in the pixel 210 with respect to, for example, the color filter 222C. Even with such a configuration, the display device 100 can detect the color of the external light incident on each pixel 210 by the sensor, and can appropriately adjust the display state of the image according to the detected color of the external light. .. Further, if the pixel 210 has a configuration in which one sensor for detecting the intensities of red, green, and blue is provided, the number of sensors provided in the pixel 210 can be reduced as compared with the configuration of the above embodiment, and the pixel 210 can be reduced. The configuration can be simplified.

  Further, the pixel 210 may be configured to have only one or two of the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D. Even with such a configuration, the display device 100 can appropriately adjust the display state of the image according to the color included in the external light that can be detected by the sensor provided in the pixel 210. Further, the number of sensors provided in the pixel 210 can be reduced as compared with the configuration of the above embodiment, and the configuration of the pixel 210 can be simplified.

  In the above-described embodiments, the backlight 180 capable of adjusting the color of light is used for description, but the present invention is not limited to this, and the backlight in which the color of light such as a cold cathode tube or a white LED cannot be adjusted. May be used. In this case, the respective sensor average values Ar, Ag, Ab of the respective sensor values Or, Og, Ob obtained by the red light sensor, the green light sensor, and the blue light sensor indicate the respective lightness of red, green, and blue. A value indicating the brightness of external light can be obtained by performing an operation of multiplying and adding a predetermined coefficient, and the brightness of light is adjusted according to the value.

  Further, in the above-described embodiment, the configuration in which the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D are arranged on the side where external light is incident through the color filter 222C has been described. The filter may be arranged on the surface side, that is, on the side on which outside light is incident without passing through the color filter 222C. With this configuration, only the brightness of the external light is detected regardless of the color of the external light. In this case, only the contrast is corrected by uniformly correcting the red adjustment value Sr, the green adjustment value Sg, and the blue adjustment value Sb. Further, the brightness of the light of the backlight 180 may be controlled according to this correction.

  Then, the state of the light emitted by the backlight 180 may not be corrected based on the state of the external light. In the case of such a configuration, when the process of step S102 is performed, the process of step S105 is performed. Therefore, the processing load in the video display processing can be reduced. Further, it is not necessary to provide the BL correction control unit 172 in the processing unit 170, and the configuration of the processing unit 170 can be simplified.

  Further, even if the color of the external light incident on the predetermined pixel 210 is substantially the same as the average color of the external light incident on the LCD panel 200, the light transmission state of the liquid crystal 223 of the pixel 210 is corrected. It may be configured to. In the case of such a configuration, when the process of step S203 is performed, the process of step S210 is performed. Therefore, the processing load in the LCD correction processing can be reduced. Further, it is not necessary to provide a function for comparing the red relative value Dr with the upper limit value and the lower limit value. Therefore, the configuration of the LCD correction control unit 173 can be simplified.

  The present invention is not limited to the display device 100 including the transmissive LCD panel 200, and may be applied to the following display devices, for example. That is, a so-called reflective or semi-transmissive LCD panel that reflects incident light to output an image, an organic EL (Electro Luminescence) panel, a PDP (Plasma Display Panel), a CRT (Cathode-Ray Tube), an FED ( The present invention may be applied to a display device including a field emission display), an electrophoretic display panel, and the like, and further to a display device that displays an image by light emitting means such as a plurality of light emitting diodes. The present invention may be applied not only to a color display device but also to a monochrome display device. Further, the invention is not limited to the in-vehicle display device, but may be applied to a portable display device, a display device installed in a home or a factory, or a display device installed outdoors in a stadium or the like. Further, it may be applied to a display unit that displays various information such as a reproduction state and a recording state in a video/music recording/reproducing apparatus.

  Although each function described above is constructed as a program, it may be configured by hardware such as a circuit board or an element such as one IC (Integrated Circuit), and can be used in any form. It should be noted that by adopting a configuration in which it is read from a program or a separate recording medium, handling is easy and the use can be easily expanded.

  In addition, the specific structure and procedure for carrying out the present invention can be appropriately changed to other structures and the like within a range in which the object of the present invention can be achieved.

[Effect of Embodiment]
As described above, in the above embodiment, the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D are arranged on the LCD panel 200 of the display device 100. Then, the processing unit 170 of the display device 100 causes the LCD correction control unit 173 to detect the red light sensor in the LCD panel 200 based on the state of the external light detected by the red light sensor 222D, the green light sensor 232D, and the blue light sensor 242D. The display state of the image at the positions corresponding to 222D, the green light sensor 232D, and the blue light sensor 242D is corrected. For this reason, in the display device 100, when red external light T as shown in FIG. Based on the detection state of the red outside light T in the optical sensor 242D, the display state of the image only at the position where the red outside light T is incident can be corrected. Further, since the display device 100 directly detects the state of external light incident on the LCD panel 200 by the red light sensor 222D or the like arranged on the LCD panel 200, for example, the LCD panel around the LCD panel 200 or the like. The state of the external light can be detected more appropriately as compared with the structure in which the state of the external light incident on the LCD panel 200 is detected by the sensor arranged at a position separated from 200. Therefore, the display device 100 can appropriately adjust the display state of the image.

  INDUSTRIAL APPLICABILITY The present invention can be used for a display control device and a display device for adjusting the display state of an image on the display means.

[0002]
Based on the display state adjusting means for adjusting the display state of the image at the predetermined position,
Image form recognition means for recognizing the intensity setting of the image signal of the image displayed at the predetermined position, and the display state adjusting means is for setting the intensity of the image signal at the predetermined position and from the outside. The display state of the image at the predetermined position is adjusted based on the state of the light.
[0008]
The display device of the present invention includes a display unit for displaying an image, the display control device of the present invention described above,
Is provided.
[Brief description of drawings]
[0009]
FIG. 1 is a block diagram showing a schematic configuration of a display device according to an embodiment of the present invention.
FIG. 2 is a schematic diagram showing a schematic configuration of an LCD panel in the one embodiment.
FIG. 3 is a schematic diagram showing a schematic configuration of a red subpixel, a green subpixel and a blue subpixel in the one embodiment.
FIG. 4 is a flowchart showing a video display process in the embodiment.
FIG. 5A is a graph showing a red sensor value in each pixel when red external light T is incident on the one embodiment.
FIG. 5B is a graph showing a green sensor value in each pixel when red external light T is incident on the one embodiment.
FIG. 5C is a graph showing a blue sensor value in each pixel when red external light T is incident on the one embodiment.
FIG. 6 is a flowchart showing LCD correction processing in the one embodiment.
FIG. 7 is a block diagram showing a schematic configuration of a display device according to another embodiment of the present invention.
[Explanation of symbols]
[0010]
100, 300 display device 110 display unit 170 which is a display unit 170 processing unit 171 which constitutes a display control device 171 sensor average value calculation unit 172 which also functions as a display state adjustment unit 172 backlight correction control unit 173 as a display state adjustment unit 173 image form LCD correction control means as display state adjusting means that also functions as recognizing means 180 Backlight as irradiating means

Claims (12)

A display control device for adjusting a display state of an image on a display means,
A light state detection unit that is disposed at a predetermined position in the display area of the display unit and that detects the state of incident light from the outside,
Display state adjusting means for adjusting the display state of the image at the predetermined position based on the state of light from the outside,
A display control device comprising: The display control device according to claim 1, wherein
An image form recognition means for recognizing at least one of lightness, hue and saturation in the display form of the image displayed at the predetermined position,
The display state adjusting means adjusts the display state of the image at the predetermined position based on the state of at least one of the predetermined position and the light from the outside. apparatus. The display control device according to claim 2, wherein
The light state detection means detects the color of light from the outside as the light state,
The image form recognition means recognizes the brightness of the image,
When the display state adjusting unit recognizes that the brightness of the image at the predetermined position is lower than the predetermined brightness, the display state adjusting unit adjusts the intensity of the color corresponding to the color of the light from the outside in the image to be strong. A display control device characterized by: The display control device according to claim 2, wherein
The light state detection means detects the color of light from the outside as the light state,
The image form recognition means recognizes the brightness of the image,
When the display state adjusting means recognizes that the brightness of the image at the predetermined position is higher than the predetermined brightness, the display state adjusting means adjusts the intensity of the color corresponding to the color of the light from the outside in the image to be weakened. A display control device characterized by: The display control device according to any one of claims 1 to 4,
The display control device, wherein the light state detection means is arranged at a plurality of predetermined positions different from each other in the display area. The display control device according to any one of claims 1 to 5,
The display area includes a plurality of pixels for outputting light of a predetermined color,
The light state detection means is disposed in the pixel at the predetermined position,
The display control device, wherein the display state adjusting means adjusts the display state of the image by adjusting the output state of the light of the predetermined color in the pixel at the predetermined position. The display control device according to claim 6,
The pixel includes a liquid crystal element that adjusts at least one of a transmission state and a reflection state of incident light to output the light of the predetermined color,
The optical state detecting means is disposed in the liquid crystal element at the predetermined position,
The display control device, wherein the display state adjusting unit adjusts an output state of light of a predetermined color in the pixel by adjusting at least one of the states of the liquid crystal element at the predetermined position. The display control device according to claim 7,
The display means includes an irradiation means for irradiating light to the outside through the pixel,
The pixel has a first liquid crystal element that transmits light emitted from the irradiation unit and outputs the light as red light, and a second liquid crystal element that transmits the light emitted and outputs the light as green light. An element and a third liquid crystal element that transmits the emitted light and outputs it as blue light,
The light state detection means detects the color of light from the outside as the light state,
The display state adjusting means adjusts the transmission state of the irradiated light in the liquid crystal element based on the color of the light from the outside at the predetermined position to output the light of the predetermined color in the pixel. A display control device characterized by adjusting the state. The display control device according to claim 8,
The first liquid crystal element includes a liquid crystal that adjusts a transmission state of the irradiated light, and a red transmissive unit that is disposed on the outer side of the liquid crystal and that transmits red light.
The second liquid crystal element includes the liquid crystal and a green transmissive unit that is disposed on the outer side of the liquid crystal and transmits green light.
The third liquid crystal element includes the liquid crystal, and a blue transmission unit that is disposed on the outside of the liquid crystal and transmits blue light.
The optical state detecting means is disposed between the liquid crystal and the red transmitting means, and is a first light intensity detecting means for detecting the intensity of the red light from the outside that passes through the red transmitting means, and the liquid crystal. And a second light intensity detecting means which is arranged between the green transmitting means and which detects the intensity of the green light from the outside which transmits the green transmitting means, and the second light intensity detecting means which is disposed between the liquid crystal and the blue transmitting means. A third light intensity detecting means provided to detect the intensity of the blue light from the outside that is transmitted through the blue transmitting means,
The display state adjusting means, based on the color of the light from the outside specified based on the intensity of the red light at the predetermined position, the intensity of the green light, the intensity of the blue light, the liquid crystal A display control device, which adjusts a transmission state of the emitted light. The display control device according to claim 8 or 9,
The display state adjusting means adjusts the irradiation state of the light to be emitted by the irradiating means based on the color of the light from the outside detected by the light state detecting means, thereby adjusting the irradiation state of the light of the predetermined color in the pixel. A display control device characterized by adjusting the output state. The display control device according to claim 10,
The light state detection means is provided in each of the plurality of pixels that are different from each other,
When the display state adjusting means recognizes that the average color of the light from the outside detected by the plurality of light state detecting means and the color of the light from the outside at the predetermined position are substantially the same, The display control device is characterized in that the transmission state of the irradiated light in the liquid crystal element is not adjusted. Display means for displaying an image,
A display control device according to any one of claims 1 to 11,
A display device comprising:

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