JP5636158B2 - Image display device - Google Patents

Description

  The present invention relates to an image display device.

  2. Description of the Related Art Conventionally, an image display device including an organic EL (Electroluminescence) element using current emission is known. In this image display apparatus, due to the temperature characteristics of the thin film transistor (TFT) and the organic EL element used therein, the light emission luminance changes when the temperature of the organic EL panel changes. Further, the light emission luminance is changed by causing the organic EL element to emit light for a long time.

  In order to solve this problem, a technique has been proposed in which a change in luminance of an organic EL display device is compensated by adjusting an amount of current supplied to a light emitting element according to a detection result of light emission luminance (for example, Patent Document 1). ). In addition, a current flowing through the anode electrode is detected in response to a predetermined adjustment luminance signal applied to the electrode of the pixel circuit, and the detection result (detected current value) is compared with a predetermined reference current value. A technique for adjusting the light emission luminance has also been proposed (for example, Patent Document 2).

JP 2004-29714 A JP 2005-78017 A

  By the way, in order to realize an easy-to-see screen that does not cause fatigue of the eyes of the user, it is preferable that the light emission luminance of the image display device is adjusted in accordance with the brightness of the ambient light.

  However, in Patent Documents 1 and 2 described above, a technique for maintaining the light emission luminance constant according to a change in the situation is described. However, the point that the light emission luminance is positively changed according to a change in the environment is completely different. Not touched. And such a request | requirement is not restricted only with respect to an organic electroluminescent panel, but is common in an image display apparatus generally.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an image display device capable of reducing power consumption while realizing a screen that is easy for the user to see according to changes in the environment.

  In order to solve the above problems, an image display device according to a first aspect of the present invention includes a first pixel circuit that emits light of a first color and a second pixel circuit that emits light of a second color. A display unit is provided. The image display device includes a detection unit that detects illuminance around the display unit. Furthermore, the illuminance around the display unit detected by the detection unit is less than or equal to a first reference illuminance, and the image display device is configured to set the luminance of the first pixel circuit that emits the first color light, A controller that reduces the luminance of the second pixel circuit that emits light of the second color at a rate different from that of the second pixel circuit;

  An image display device according to a second aspect of the present invention includes a first pixel circuit that emits light of a first color, a second pixel circuit that emits light of a second color, and a third pixel that emits light of a third color. And a display portion having a circuit. The image display device converts a first input gradation value corresponding to the first pixel circuit into a first output gradation value, and converts a second input gradation value corresponding to the second pixel circuit to a second value. A conversion unit that converts an output gradation value into a third output gradation value corresponding to the third pixel circuit; and a detection unit that detects illuminance around the display unit. I have. Further, the image display device is configured such that when the illuminance around the display unit detected by the detection unit is equal to or lower than the first reference illuminance and higher than the second reference illuminance, the second and third input floors. The conversion unit is controlled so that a tone value is smaller than the first input tone value, and the first output tone value is relatively larger than the second and third output tone values. And a control unit for reducing the light emission luminance of the display unit.

  An image display device according to a third aspect of the present invention is the image display device according to the second aspect of the present invention, wherein the control unit detects an illuminance around the display unit detected by the detection unit. When the illumination intensity is less than or equal to the second reference illuminance, the first output gradation value is controlled to be relatively smaller than the second output gradation value.

  An image display device according to a fourth aspect of the present invention is the image display device according to the third aspect of the present invention, wherein the control unit detects an illuminance around the display unit detected by the detection unit. When the third reference illuminance is lower than the second reference illuminance, the first output tone value is controlled to be relatively smaller than the second and third output tone values.

  An image display device according to a fifth aspect of the present invention is the image display device according to any one of the second to fourth aspects of the present invention, and emits light to the first to third pixel circuits. A power supply unit that supplies a necessary voltage is provided. In the image display device, the control unit is supplied from the power supply unit to the first to third pixel circuits according to a decrease in illuminance around the display unit detected by the detection unit. And controlling the voltage to reduce the light emission luminance of the display unit.

  An image display device according to a sixth aspect of the present invention is the image display device according to any one of the second to fifth aspects of the present invention, wherein the second and third colors are blue and green. Including.

  An image display device according to a seventh aspect of the present invention is the image display device according to any one of the second to sixth aspects of the present invention, wherein the control unit adjusts a γ table, and the display Control is made to reduce the light emission luminance of the part.

  An image display device according to an eighth aspect of the present invention is the image display device according to any one of the second to seventh aspects of the present invention, wherein the display section includes a substrate and a semiconductor on the substrate. And the detection portion is formed by stacking a semiconductor on the substrate.

  An image display device according to a ninth aspect of the present invention is the image display device according to any one of the second to seventh aspects of the present invention, wherein the display section includes the first to third pixel circuits. A transparent layer provided on the front side from which light is emitted, and the detection unit is provided in the vicinity of an end of the transparent layer.

  The present invention reduces the light emission luminance of the display unit in accordance with the decrease in the illuminance around the display unit to reduce power consumption, and the illuminance around the display unit is less than or equal to the first reference illuminance and When the illuminance is higher than 2 reference illuminance, it is possible to change the chromaticity of the display unit and realize an easy-to-view screen for the user in accordance with the environmental change.

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

<Functional configuration of image display device>
FIG. 1 is a block diagram showing a functional configuration of an image display apparatus 1 according to an embodiment of the present invention.

  The image display device 1 mainly includes an organic EL display 2, an X driver 3, an overall control unit 4, a storage unit 5, a power supply circuit 6, and an optical sensor 7. Here, the image signal is composed of signals relating to the three primary colors of red, green, and blue, and the organic EL display 2 has a light emitting element that emits red light, a light emitting element that emits green light, and blue light. It is assumed that the light emitting device emits light.

  The organic EL display 2 has a substantially rectangular outline, and has a self-luminous light emitting element that emits light by passing a current through the organic material. The organic EL display 2 includes a large number of pixel circuits 21R each emitting red light as a first color (for example, light having a wavelength included in a range of about 610 to 750 nm), and green light as a second color ( For example, a large number of pixel circuits 21G each emitting light having a wavelength included in the range of about 500 to 560 nm, and blue light (for example, light having a wavelength included in the range of about 435 to 480 nm) as the third color. A large number of pixel circuits 21 </ b> B that respectively emit are arranged.

  Specifically, a large number of pixel circuits 21R, 21G, and 21B are arranged in a matrix, for example. Each pixel circuit 21R, 21G, and 21B includes a light emitting element (here, an organic EL element). In the present embodiment, the organic EL display 2 corresponds to the “display unit” of the present invention, the pixel circuit 21R corresponds to the “first pixel circuit” of the present invention, and the pixel circuit 21G corresponds to the “second pixel” of the present invention. The pixel circuit 21B corresponds to a “third pixel circuit” of the present invention.

The organic EL display 2 has a plurality of image signal lines and a plurality of scanning signal lines. Each image signal line has an output image signal corresponding to the emission luminance (specifically, an output image signal S _OUTR indicating a red output gradation value (output gradation value), a green output gradation value) Output image signal S _OUTG or output image signal S _OUTB indicating a blue output gradation value) is supplied to each of the pixel circuits 21R, 21G, and 21B. Each scanning signal line is provided so as to be substantially orthogonal to the plurality of image signal lines, and supplies scanning signals to the pixel circuits 21R, 21G, and 21B. This scanning signal is a signal that controls the timing of supplying the output image signals S _OUTR , S _OUTG , S _OUTB to the pixel circuits 21R, 21G, 21B via the image signal lines.

The X driver 3 is electrically connected to a plurality of image signal lines, and controls the timing of supplying each output image signal S _OUTR , S _OUTG , S _OUTB input from the overall control unit 4 to each image signal line. Circuit. For example, the X driver 3 is arranged along one side (for example, a short side or a long side) of the organic EL display 2. Although not shown in FIG. 1, the timing for supplying the scanning signal to the scanning signal line along the other side (for example, the long side or the short side) substantially orthogonal to one side of the organic EL panel 3 is controlled. A circuit (Y driver) is arranged.

  The overall control unit 4 is a part that performs overall control of the operation of the image display device 1 and includes a CPU, a ROM, a RAM, and the like. For example, programs and various data are stored in the ROM, and various controls and functions in the overall control unit 4 are realized by the CPU reading and executing the programs in the ROM. Specifically, the overall control unit 4 implements functional configurations such as a luminance control unit 41 as a control unit and a γ conversion unit 42 as a conversion unit.

  The luminance control unit 41 reduces the light emission luminance in the organic EL display 2 according to the decrease in the illuminance around the organic EL display 2 detected by the optical sensor 7 as the detection unit. The illuminance around the organic EL display 2 here refers to the illuminance depending on the light (environment light) of the environment where the organic EL display 2 is placed, regardless of the light emission of the organic EL display 2. Yes. Therefore, hereinafter, the illuminance around the organic EL display 2 is also referred to as “environment-induced illuminance”. The control for decreasing the light emission luminance in response to the decrease in the environment-induced illuminance will be described later.

  Further, the luminance control unit 41 controls the γ conversion in the γ conversion unit 42 according to the environment-induced illuminance detected by the optical sensor 7. The control of γ conversion according to the environment-induced illuminance will be further described later. In the present embodiment, the luminance control unit 41 corresponds to the “control unit” of the present invention.

The γ conversion unit 42 includes an input image signal (specifically, an input image signal (red input image signal) S _INR indicating a red input tone value, an input image signal (green input image indicating a green input tone value). Signal) S _ING or an input image signal (blue input image signal) S _INB ) indicating a blue input gradation value is received and so-called γ conversion is performed.

Specifically, an input image signal S _INR indicating a red input gradation value (red input gradation value) corresponding to the pixel circuit 21R, and a green input gradation value (green input gradation value) corresponding to the pixel circuit 21G. the input image signal S _ING indicating the value), and the input image signal S _INB showing blue input tone values corresponding to the pixel circuit 21B (blue input tone value), a red output floor corresponding to the pixel circuits 21R An output image signal (red output image signal) S _OUTR indicating a tone value (red output tone value) and an output image signal (green output tone value) indicating a green output tone value (green output tone value) corresponding to the pixel circuit 21G Output image signal) S _OUTG and an input image signal (blue output image signal) S _OUTB indicating a blue output gradation value (blue output gradation value) corresponding to the pixel circuit 21B.

More specifically, for example, 6-bit red, green, and blue input image signals S _INR , S _ING , S _INB (here, images with red, green, and blue input gradation values of 0/63 to 63/63) Signal) is a 10-bit red, green, and blue output image signal S _OUTR , S _OUTG , S _OUTB (here, image signals with red, green, and blue output gradation values of 0 / 1023-1023 / 1023) Is converted to For example, the γ converter 42 converts the input tone value of each color into an output tone value that is approximately raised to the power of 2.2. The output image signals S _OUTR , S _OUTG and S _OUTB are input to the X driver 3.

  Regarding the conversion process (γ conversion process) in the γ conversion unit 42, a table (γ table) in which input gradation values before conversion and output gradation values after conversion are associated with each color is stored in the storage unit 5 in advance. The γ conversion process is performed by referring to the γ table as a conversion rule. Note that the γ conversion processing in the γ conversion unit 42 may be performed by calculation one by one. However, the conversion rule (here, the γ table) of the γ conversion process in the γ conversion unit 42 is appropriately changed according to the environment-induced illuminance detected by the optical sensor 7. In the present embodiment, the γ conversion unit 42 corresponds to the “conversion unit” of the present invention.

  The storage unit 5 is configured using a non-volatile memory or the like, and stores various information such as a γ table. The γ table is prepared for each environment-induced illuminance in a plurality of stages (for example, 6 or 12 or more stages) corresponding to a plurality of illuminance ranges (illuminance ranges), and stored in the storage unit 5.

  The power supply circuit 6 emits electric power supplied from a power supply (for example, a battery) to a large number of pixel circuits 21R, 21G, and 21B constituting the organic EL display 2 in accordance with a signal from the luminance control unit 41. A necessary voltage (light-emitting power supply voltage) and a voltage required for driving the X driver 3 (X driver driving voltage) are supplied. That is, power is supplied to the organic EL elements of the pixel circuits 21R, 21G, and 21B by the power supply circuit 6. In the present embodiment, the power supply circuit 6 corresponds to the “power supply unit” of the present invention.

  The power supply circuit 6 includes a transformer, and in response to a control signal corresponding to the environment-induced illuminance from the brightness control unit 41, each pixel circuit of the organic EL display 2 by a transformer (for example, a DC-DC converter). The electric power supplied to 21R, 21G, and 21B is changed. That is, the power supply voltage for light emission applied between both electrodes of the light emitting elements included in the pixel circuits 21R, 21G, and 21B is changed.

  For example, in the case where a moving image (for example, a moving image that displays 60 frames per second) is visually output in the image display device 1, the power supply voltage for light emission is changed every predetermined number (for example, 60) of frames. . The light emission power supply voltage is changed between the light emission period for one frame and the light emission period for the next frame. The current consumption in the organic EL display 2 is changed by changing the power supply voltage for light emission.

  The optical sensor 7 includes an illuminometer that measures the illuminance (environment-induced illuminance) around the organic EL display 2. In the present embodiment, the optical sensor 7 corresponds to the “detection unit” of the present invention. A signal indicating the measurement result of environment-induced illuminance in the optical sensor 7 is output to the luminance control unit 41.

  FIG. 2 is a schematic diagram illustrating an example of an attachment position of the optical sensor 7 in the image display device 1. Here, for example, it is assumed that the organic EL display 2 is configured with the element layer 202 interposed between the lower glass substrate 201 and the upper glass substrate 203.

  The lower glass substrate 201 is a base member on which the element layer 202 is laminated.

  The element layer 202 includes a large number of pixel circuits 21R, 21G, and 21B formed in a matrix. As for the element layer 202, a semiconductor layer made of silicon or the like is stacked on the glass substrate 201 on the lower surface, and P-type and N-type semiconductor layers are appropriately disposed to provide a transistor 212, and an organic EL Elements are formed to form pixel circuits 21R, 21G, and 21B. The optical sensor 7 is formed by appropriately stacking P-type and N-type semiconductor layers on the surface of the element layer 202 on the upper glass substrate 203 side. The photosensor 7 may be a general photodiode or a thin film transistor (TFT) in which no gate is formed.

  The upper glass substrate 203 is made of transparent glass, and is provided on the upper surface of the element layer 202 in order to protect the element layer 202. That is, the element layer 202 is sandwiched between the lower glass substrate 201 and the upper glass substrate 203. Then, light emitted from a large number of pixel circuits 21R, 21G, and 21B arranged in the element layer 202 passes through the upper glass substrate 203 and is emitted to the outside as indicated by the hatched arrows in FIG. The

Further, the optical sensor 7 receives the environmental light E _P incident from the outside and transmitted through the upper glass substrate 203, thereby measuring the environment-induced illuminance. As described above, when the optical sensor 7 is provided in the element layer 202, it is possible to measure the luminance of light emitted from the pixel circuits 21R, 21G, and 21B in a period in which light is emitted from the pixel circuits 21R, 21G, and 21B. In a period in which no light is emitted from each of the pixel circuits 21R, 21G, and 21B, it is possible to measure environment-induced illuminance.

  Specifically, when moving image display is performed, when a large number of pixel circuits 21R, 21G, and 21B are repeatedly turned on and off, and measurement is performed continuously in time with the optical sensor 7, the strength of the detected value is increased. Periodic fluctuations are obtained. The minimum value of the detected value corresponds to the illuminance caused by the environment, and the maximum value of the detected value corresponds to the light emission luminance.

  Here, the various configurations of the overall control unit 4 are functionally realized by executing a program by the CPU, but the configuration is not limited thereto. For example, all or part of the configuration of the overall control unit 4 may be realized by a hardware configuration such as a dedicated electronic circuit.

  Hereinafter, a change in the power supply voltage for light emission according to the environment-induced illuminance, a change in γ conversion processing according to the environment-induced illuminance, and the relationship between the environment-induced illuminance and the light emission luminance of the organic EL display 2 will be described in order.

<Change of power supply voltage for light emission according to environmental illuminance>
FIG. 3 is a schematic view illustrating the relationship between the environment-induced illuminance and the light-emitting power supply voltage when the light-emitting power supply voltage is changed according to the environment-induced illuminance under the control of the luminance control unit 41. In FIG. 3, the horizontal axis represents the common logarithm of environment-induced illuminance (that is, log ₁₀ (environment-induced illuminance)), and the vertical axis represents the power supply voltage for light emission. The relationship between the illuminance caused by the environment and the power supply voltage for light emission is indicated by a thick line Cv _DD .

As shown in FIG. 3, when the environment-induced illuminance is higher than a predetermined 0th reference illuminance (for example, 1000 lux) C0, the power supply voltage for light emission is set to a substantially constant value near the maximum value _VMAX .

  When the environment-induced illuminance is equal to or lower than the predetermined 0th reference illuminance C0 and higher than the predetermined first reference illuminance C1 (for example, 100 lux), the power supply voltage for light emission is monotonously according to the decrease in the environment-induced illuminance. Reduced. Furthermore, when the environment-induced illuminance is equal to or lower than the predetermined first reference illuminance C1 and higher than the predetermined second reference illuminance C2 (for example, 10 lux), the light-emitting power supply voltage is also reduced according to the decrease in the environment-induced illuminance. Monotonically reduced.

  By controlling the power supply voltage for light emission, when the environment-induced illuminance is equal to or lower than the predetermined 0th reference illuminance C0 and higher than the predetermined second reference illuminance C2, the organic EL is set according to the decrease in the environment-induced illuminance. By reducing the light emission luminance of the display 2, the light emission luminance is set to a value corresponding to the environment-induced illuminance. Therefore, when the amount of light around the image display device 1 is small, the light emission luminance is reduced, screen glare is prevented, and power consumption is reduced.

When the environment-induced illuminance is less than or equal to the predetermined second reference illuminance C2, the light-emitting power supply voltage is set to a substantially constant value near the minimum value V _MIN regardless of changes in the environment-induced illuminance. By such control of the power supply voltage for light emission, even when the surroundings of the image display device 1 become extremely dark, the light emission luminance that allows the user to visually recognize the image is ensured.

<Change of γ conversion processing according to environmental illuminance>
In normal γ conversion processing, when the red, green, and blue input image signals S _INR , S _ING , and S _INB indicate the same input gradation value, for example, the size of the TFT is adjusted for each color. As a result, red, green, and blue output image signals S _OUTR , S _OUTG , and S _OUTB that indicate output gradation values obtained by multiplying each input gradation value by a power of 2.2 are obtained. That is, the ratio related to the red, green, and blue input gradation values and the ratio related to the red, green, and blue output gradation values are designed to be kept substantially constant before and after the γ conversion process. Yes.

  On the other hand, in the γ conversion processing according to the present embodiment, the ratios related to the red, green, and blue tone values before and after the γ conversion processing are appropriately changed according to the change in the environment-induced illuminance. Specifically, the ratio relating to the red, green, and blue input gradation values is different from the ratio relating to the red, green, and blue output gradation values before and after the γ conversion processing. Hereinafter, the content of changing the ratio of the gradation values of red, green, and blue before and after the γ conversion process according to the environment-induced illuminance will be described.

FIG. 4 shows the red, green, and blue output image signals S _OUTR , S _OUTG , S _OUTB when the red, green, and blue input image signals S _INR , S _ING , S _INB exhibit the same input gradation value. FIG. 6 is a schematic diagram illustrating the relationship between the ratio of output gradation values indicated by and the environment-induced illuminance. In FIG. 4, the horizontal axis represents the common logarithm of environment-induced illuminance (that is, log ₁₀ (environment-induced illuminance)), and the vertical axis represents the ratio of red, green, and blue output tone values.

Here, the red, green, and blue output image signals S _OUTR , S _OUTG , S _OUTB corresponding to the red, green, and blue input image signals S _INR , S _ING , S _INB indicating the same gradation value are shown. The maximum output gradation value (maximum output gradation value) among the green, blue, and blue output gradation values is set to 1, which is a reference value. The relationship between the environment-induced illuminance and the ratio of the red output gradation value (specifically, the value obtained by dividing the red output gradation value by the maximum output gradation value) is indicated by a thick line Cf _R , The relationship between the ratio of the green output gradation value (specifically, the value obtained by dividing the green output gradation value by the maximum output gradation value) is indicated by a thick one-dot chain line Cf _G , and the environment-induced illuminance and the blue output gradation The relationship with the value ratio (specifically, the value obtained by dividing the blue output gradation value by the maximum output gradation value) is indicated by a thick broken line Cf _B.

  As shown in FIG. 4, when the environment-induced illuminance is higher than the predetermined 0th reference illuminance C0, the ratios of the red, green, and blue output gradation values are all 1 regardless of the decrease in the environment-induced illuminance. It is set to be a substantially constant value in the vicinity. In addition, even when the environment-induced illuminance is less than or equal to the predetermined 0th reference illuminance C0 and higher than the predetermined first reference illuminance C1, the red, green, and blue output gradation values are reduced regardless of the decrease in the environment-induced illuminance. Both ratios are set to be substantially constant values near 1. That is, when the environment-induced illuminance is higher than the predetermined first reference illuminance C1, the red, green, and blue input gradation values having the same value are red with substantially the same value (specifically, the same), The γ conversion processing in the γ conversion unit 42 is performed according to a conversion rule (here, a γ table) that provides green and blue output gradation values.

  When the environment-induced illuminance is equal to or lower than the predetermined first reference illuminance C1 and higher than the predetermined second reference illuminance C2, the ratio of the red output gradation value is 1 (that is, the maximum output) regardless of the decrease in the environment-induced illuminance. The ratio of the green and blue output gradation values is set to be relatively lower than the ratio of the red output gradation values while being maintained constant. That is, for the same value of red, green, and blue input tone values, the conversion rule (here, the red output tone value is relatively larger than the green and blue output tone values) The γ conversion processing in the γ conversion unit 42 is performed according to the γ table. If the red output tone value is relatively larger than the green and blue output tone values, the red output tone value may be slightly reduced. Here, when the environment-induced illuminance is equal to or lower than the first reference illuminance C1, control is performed so that the luminance related to the pixel circuit 21R decreases at a ratio different from the luminance related to the pixel circuit 21G or the pixel circuit 21B.

  Here, when the luminance of the object to be visually recognized is lowered to some extent, the human eye is less likely to feel red. For this reason, by adjusting the chromaticity so that an image displayed on the organic EL display 2 is a reddish image in which red is emphasized relatively more than green and blue by the γ conversion process. The user feels as if the so-called white balance relating to the original image is kept constant.

  When the environment-induced illuminance is equal to or lower than the predetermined second reference illuminance C2 and higher than the predetermined third reference illuminance C3 (for example, 6 lux), the ratio of the green output gradation value regardless of the decrease in the environment-induced illuminance Is kept constant at 1 (that is, the maximum output gradation value), while the ratio of the blue output gradation value is maintained near a predetermined value (for example, 0.7) lower than the green output gradation value, and It is set so that the ratio of the red output gradation value is monotonously decreased in accordance with the decrease in environment-induced illuminance. That is, a conversion rule (in this case, the γ table) in which the red output tone value is relatively smaller than the green output tone value for the same value of red, green, and blue input tone values. ), The γ conversion processing in the γ conversion unit 42 is performed.

  When the environment-induced illuminance is equal to or lower than the predetermined third reference illuminance C3 and higher than the predetermined fourth reference illuminance C4 (for example, 2 lux), the ratio of the green output gradation value regardless of the decrease in the environment-induced illuminance Is kept constant at 1 (that is, the maximum output gradation value), while the ratio of the blue output gradation value is maintained near a predetermined value (for example, 0.7) lower than the green output gradation value, and The ratio of the red output gradation value is set so as to decrease monotonously in a range of values lower than the ratio of the blue output gradation value in accordance with a decrease in the environment-induced illuminance. In other words, for the same value of red, green, and blue input tone values, the conversion rule (here, the red output tone value is smaller than the green and blue output tone values) The γ conversion processing in the γ conversion unit 42 is performed according to the γ table.

  Further, when the environment-induced illuminance is equal to or lower than the predetermined fourth reference illuminance C4, the ratio of the green output gradation value is kept constant at 1 (that is, the maximum output gradation value) regardless of the decrease in the environment-induced illuminance. However, the ratio of the blue output gradation value is maintained near a predetermined value (for example, 0.7) lower than the green output gradation value, and the ratio of the red output gradation value is extremely low (here, 0) is set to be maintained in the vicinity. That is, the image displayed on the organic EL display 2 is a blue-green monochromatic display image.

  Here, the human eye cannot recognize the color of the object when the luminance of the object to be visually recognized becomes considerably low. Therefore, in the present embodiment, control is performed so as to emit light having a color intermediate between two colors (green and blue) (light in a wavelength range centered on 500 nm) having a human eye sensitivity higher than that of red even at extremely low luminance. Is done. By such control, power consumption can be reduced.

<Relationship between environmental illuminance and emission brightness>
FIG. 5 is a schematic view illustrating the relationship between the environment-induced illuminance and the light emission luminance of the organic EL display 2 obtained as a result of the change of the power supply voltage for light emission and the γ conversion process according to the environment-induced illuminance described above.

In FIG. 5, the horizontal axis represents the common logarithm of environment-induced illuminance (that is, log ₁₀ (environment-induced illuminance)), and the vertical axis represents emission luminance. In FIG. 5, when the red, green, and blue input image signals S _INR , S _ING , and S _INB indicate the same input gradation value, the environment-induced illuminance and the emission luminance of the red pixel circuit 21R are The relationship is indicated by a thick line Ce _R , the relationship between the environment-induced illuminance and the light emission luminance related to the green pixel circuit 21G is indicated by a thick one-dot chain line Ce _G , and the environment-related illuminance and the light emission luminance related to the blue pixel circuit 21B are The relationship is indicated by a thick broken line Ce _B.

As shown in Figure 5, when the environment due illuminance is higher than a predetermined zeroth reference illumination C0 is the pixel circuits 21R, 21G, emission luminance according to the 21B becomes substantially constant value in the vicinity of the maximum value Y _MAX.

  When the environment-induced illuminance is less than or equal to the predetermined 0th reference illuminance, the light emission luminance related to the pixel circuits 21R, 21G, and 21B tends to decrease as the environment-induced illuminance decreases.

  Specifically, when the environment-induced illuminance is equal to or lower than the predetermined 0th reference illuminance C0 and higher than the predetermined first reference illuminance C1, the pixel circuits 21R, 21G, and 21B are activated according to the decrease in the environment-induced illuminance. Each of the emission luminances decreases monotonously.

  When the environment-induced illuminance is equal to or lower than the predetermined first reference illuminance C1 and higher than the predetermined second reference illuminance C2, the light emission luminances related to the pixel circuits 21G and 21B are relative to the light emission luminance related to the pixel circuit 21R. Lower. That is, in the range of the environment-induced illuminance, the amount of decrease in the light emission luminance related to the pixel circuits 21G and 21B with respect to the decrease in the environment-induced illuminance is larger than the amount of decrease in light emission luminance related to the pixel circuit 21R with respect to the decrease in the environment-induced illuminance. growing.

When the environment-induced illuminance is equal to or lower than the predetermined second reference illuminance C2 and higher than the predetermined third reference illuminance C3, the light emission luminance of the pixel circuit 21G is the highest among the light emission luminances related to the pixel circuits 21R, 21G, and 21B. The light emission luminance of the pixel circuit 21R is an intermediate value, and the light emission luminance of the pixel circuit 21B is the lowest value. The light emission luminances of the pixel circuits 21G and 21B are maintained at substantially constant values in the vicinity of the minimum values Y _MING and Y _MINB , whereas the light emission luminance related to the pixel circuit 21R decreases the environment-induced illuminance. In response, it decreases monotonously.

When the environment-induced illuminance is equal to or lower than the predetermined third reference illuminance C3 and higher than the predetermined fourth reference illuminance C4, the light emission luminance of the pixel circuit 21G is the highest among the light emission luminances related to the pixel circuits 21R, 21G, and 21B. The light emission luminance of the pixel circuit 21B is an intermediate value, and the light emission luminance of the pixel circuit 21R is the lowest value. The light emission luminances of the pixel circuits 21G and 21B are maintained at substantially constant values in the vicinity of the minimum values Y _MING and Y _MINB , whereas the light emission luminance related to the pixel circuit 21R decreases the environment-induced illuminance. In response, it decreases monotonously.

  That is, when the environment-induced illuminance is equal to or lower than the predetermined second reference illuminance C2 and higher than the predetermined fourth reference illuminance C4, the light emission luminance related to the pixel circuits 21G and 21B is almost equal to the decrease in the environment-induced illuminance. While the luminance does not decrease, the light emission luminance related to the pixel circuit 21R decreases monotonously.

When the environment-induced illuminance is less than or equal to the predetermined fourth reference illuminance C4, the light emission luminance of the pixel circuit 21G is maintained at a substantially constant value near the minimum value Y _MING regardless of the change in the environment-induced illuminance, and the pixel circuit 21B The light emission luminance is maintained at a substantially constant value near the minimum value Y _MINB , and the light emission luminance of the pixel circuit 21R is maintained at a substantially constant value near a very low predetermined value (here, 0). At this time, the emission luminance of the pixel circuit 21G is the highest value, the emission luminance of the pixel circuit 21B is an intermediate value, and the emission luminance of the pixel circuit 21R is the lowest value.

<Light emission control operation according to ambient light>
FIG. 6 is a flowchart showing an operation flow of light emission control according to ambient light in the image display apparatus 1 according to the present embodiment. This operation flow is realized by the control of the overall control unit 4. Then, for example, in response to the input image signal constituting the moving image being input to the overall control unit 4, this operation flow is started, and the process proceeds to step S1 in FIG.

  In step S <b> 1, environment-induced illuminance is measured by the optical sensor 7. At this time, the overall control unit 4 obtains the value of environment-induced illuminance.

  In step S2, the luminance control unit 41 sets the light-emitting power supply voltage and the γ table according to the value of the environment-induced illuminance obtained in step S1.

  In step S3, the timer of the timer that the overall control unit 4 has as a function is started.

  In step S <b> 4, the overall control unit 4 determines whether or not a predetermined time (for example, 1 second) has elapsed since the timer was started. Here, if the predetermined time has not elapsed, the determination in step S4 is repeated, and if the predetermined time has elapsed, the process proceeds to step S5.

  In step S <b> 5, environment-induced illuminance is measured by the optical sensor 7.

  In step S6, the overall control unit 4 resets the timer and starts counting the timer again.

  In step S7, the luminance control unit 41 sets the light-emitting power supply voltage and the γ table according to the value of the environment-induced illuminance obtained in step S5. In addition, since the γ table is prepared for each of the multiple illuminance ranges, if the illuminance caused by the environment does not deviate from the illuminance range to which the illuminance caused by the environment measured last time belongs, Settings are maintained. Conversely, if the environment-induced illuminance is out of the illuminance range to which the previously measured environment-induced illuminance belongs, the γ table used in the γ conversion unit 42 is changed to a γ table corresponding to the current environment-induced illuminance.

  Then, when the process of step S7 is completed, the process returns to step S4. That is, while the input image signal constituting the moving image is continuously input to the overall control unit 4, the processes in steps S4 to S7 are repeated.

  Note that when the input of the input image signal constituting the moving image to the overall control unit 4 is terminated, the operation flow is forcibly terminated.

  As described above, in the image display device 1 according to the embodiment of the present invention, the light emission luminance of the organic EL display 2 decreases as the illuminance around the organic EL display 2 (here, environment-induced illuminance) decreases. Is done. In addition, when the illuminance around the organic EL display 2 (here, environment-induced illuminance) is equal to or lower than the first reference illuminance C1 and higher than the second reference illuminance C2, the organic EL display 2 is reddish. Is displayed. For this reason, a screen that is easy for the user to see according to changes in the environment is realized, and power consumption is also reduced.

  In addition, when the object to be visually recognized becomes very dark, the sensitivity of the human eye to red light decreases. For this reason, red light is relatively reduced as compared with light of other colors. As a result, a screen that is easy for the user to see according to the environmental change is realized, and the power consumption is further reduced.

  In addition, the light emission luminance of the organic EL display 2 is reduced by reducing the power supply voltage for light emission necessary for light emission supplied to the pixel circuits 21R, 21G, and 21B. For this reason, power consumption can be further reduced.

  Also, the red, green, and blue input image signals having the same value are converted into red, green, and blue output image signals having different values by the γ conversion process according to the environment-induced illuminance. For this reason, the so-called white balance of the image displayed on the organic EL display 2 can be adjusted without adding a special configuration.

  Further, as shown in FIG. 2, a configuration is adopted in which the photosensor 7 is formed when the pixel circuits 21R, 21G, and 21B are configured. For this reason, the optical sensor 7 that can easily detect the illuminance around the organic EL display 2 (here, the illuminance caused by the environment) can be easily formed.

<Modification>
The present invention is not limited to the above-described embodiments, and various changes and improvements can be made without departing from the scope of the present invention.

  For example, in the above-described embodiment, the light emission luminance of the organic EL display 2 is changed by changing the power supply voltage for light emission supplied from the power supply circuit 6 to the organic EL display 2. However, the present invention is not limited to this. For example, the light emission luminance may be changed by changing the power supply voltage supplied from the power supply circuit 6 to the X driver 3 according to the environment-induced illuminance. Further, the light emission luminance may be changed by changing the γ table. Further, the image display device 1 is provided with a palette control unit that adjusts a palette that is a source of the input tone value signal, and the input tone value is changed by adjusting the contents of the palette by the palette control unit. It may be a method. The palette control unit changes the magnitude of the input gradation value according to the environment-induced illuminance. Then, the output tone value is changed by changing the input tone value. The light emission luminance may be adjusted by changing the input gradation value by the palette control unit and changing the γ table.

  In the above embodiment, the white balance of the image is adjusted by changing the γ table. However, the present invention is not limited to this. For example, the white balance of the image is adjusted by converting at least one of the input gradation value and the output gradation value by a conversion process other than the γ conversion process according to the environment-induced illuminance. May be. Further, a pallet control unit that adjusts a pallet that is a source of the input tone value signal is provided in the image display device 1, and the input tone value is changed in accordance with the adjustment of the pallet contents by the pallet control unit. Thus, the white balance of the image may be adjusted. Here, the palette control unit changes the magnitude of the input gradation value according to the environment-induced illuminance. Then, according to the change of the input tone value, the output tone value is changed as a result, and the white balance of the image is adjusted. Note that the white balance of the image may be adjusted by both changing the input tone value by the palette control unit and changing the γ table.

  In the above embodiment, the optical sensor 7 is embedded in the element layer 202 together with the transistor 212 and the like. However, the present invention is not limited to this, and the optical sensor may be provided in various other positions. Hereinafter, two specific examples of the attachment positions of the optical sensors 7A and 7B will be described and described.

  FIG. 7 is a diagram for explaining the mounting position of the optical sensor 7A in the image display device 1A according to the first modification. Note that the configuration of the image display device 1A is changed to a photosensor 7A having a different mounting position compared to the image display device 1 according to the above-described embodiment, and the organic EL display 2 is configured by the change. It is changed to a different organic EL display 2A.

  As shown in FIG. 7, in the organic EL display 2 </ b> A, similarly to the organic EL display 2 according to the above embodiment, the organic EL in which light is emitted from a large number of pixel circuits 21 </ b> R, 21 </ b> G, 21 </ b> B included in the element layer 202. On the front side of the display 2A, an upper glass substrate 203 corresponding to a transparent layer is provided. The optical sensor 7A is provided in the vicinity of the end portion of the top glass substrate 203.

The optical sensor 7A measures the environment-induced illuminance by receiving the environmental light E _P incident from the outside and transmitted through the upper glass substrate 203 in a period in which no light is emitted from the pixel circuits 21R, 21G, and 21B. . Further, in a period in which light is emitted from each of the pixel circuits 21R, 21G, and 21B, the optical sensor 7A measures the light _ET that is emitted from each of the pixel circuits 21R, 21G, and 21B and travels in the lateral direction on the upper glass substrate 203. Thus, it is possible to measure the light emission luminance related to the pixel circuits 21R, 21G, and 21B.

  In such a configuration, there is no need to provide a special optical sensor outside the organic EL display 2A. Therefore, it is possible to easily form the optical sensor 7A that can easily detect the illuminance around the organic EL display 2A (here, the illuminance caused by the environment).

  FIG. 8 is a diagram for explaining the mounting position of the optical sensor 7B in the image display device 1B according to the second modification. Note that the configuration of the image display device 1B is different from the image display device 1 according to the above-described embodiment in that the optical sensor 7 is changed to the optical sensor 7B having a different mounting position, and the organic EL display 2 is configured by the change. It has been changed to a different organic EL display 2B.

As shown in FIG. 8, in the organic EL display 2 </ b> B, the optical sensor 7 </ b> B is provided in the vicinity of the front end portion of the top glass substrate 203. Then, the ambient light E _P is received by the optical sensor 7B to measure the environment-induced illuminance.

It should be noted that the organic EL display lights up sequentially from the upper horizontal line (pixel circuit line constituted by the pixel circuits 21R, 21G, and 21B) corresponding to the output image signal of each frame constituting the moving image, so-called progressive. In the case of the type, when a moving image is displayed on the organic EL display, one of the horizontal lines is in a light emitting state. Therefore, from the viewpoint of accurately measuring the illuminance caused by the environment without being influenced by the light emitted from the organic EL display, the ambient light E _P is received as shown in FIG. 8, but is emitted from the organic EL display. It is preferable that an optical sensor is installed so as not to receive received light.

  In the above embodiment, the organic EL display 2 includes the pixel circuit 21R that emits red light, the pixel circuit 21G that emits green light, and the pixel circuit 21B that emits blue light. Not limited to this. The second and third colors can be considered to be colors related to the wavelength bands around the wavelength bands of green and blue light. It should be noted that the relationship between the green output tone value with respect to the environment-induced illuminance in the γ table of the above embodiment and the relationship between the blue output tone value with respect to the environment-induced illuminance may be interchanged. The green output gradation value and the blue output gradation value may show the same tendency.

  In the above embodiment, as shown in FIG. 3, the power supply voltage for light emission is continuously changed in accordance with the change in the illuminance caused by the environment. However, the present invention is not limited to this. For example, the illuminance is divided into a plurality of (for example, 12) value ranges (illuminance ranges), and a table in which the power supply voltage for light emission is associated with each illuminance range is stored in the storage unit 5 or the like. A configuration may be employed in which a power supply voltage for light emission associated with an illuminance range to which environment-induced illuminance actually measured by the optical sensor 7 belongs is employed.

  In the above embodiment, the image display device 1 including the organic EL display 2 has been described as an example, but the present invention is not limited to this. The idea of the present invention can be applied to various image display devices such as a self-luminous display, a liquid crystal display, a plasma display, and a cathode ray tube that emit light by itself, including a light emitting diode composed of an inorganic material. It is.

  Note that a part of the configuration that constitutes the above embodiment and the above modification may be combined as appropriate within a consistent range.

It is a figure which shows the functional structure of the image display apparatus which concerns on one Embodiment of this invention. It is a schematic diagram which illustrates the attachment position of the optical sensor which concerns on one Embodiment of this invention. It is a schematic diagram which illustrates the relationship between environmental illuminance and the power supply voltage for light emission. It is a schematic diagram which illustrates the relationship between environment-induced illumination intensity and a γ table. It is a schematic diagram which illustrates the relationship between environmental illumination intensity and light emission luminance. It is a flowchart which shows the operation | movement flow of the light emission control according to environmental light. 10 is a schematic view illustrating an attachment position of an optical sensor according to Modification 1. FIG. 10 is a schematic view illustrating an attachment position of an optical sensor according to Modification 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,1A, 1B Image display apparatus 2,2A, 2B Organic EL display 3 X driver 4 Control part 5 Memory | storage part 6 Power supply circuit 7,7A, 7B Photosensor 21R, 21G, 21B Pixel circuit 41 Luminance control part 42 γ conversion part

Claims (9)

A display unit having a first pixel circuit that emits light of a first color and a second pixel circuit that emits light of a second color;
A detection unit for detecting illuminance around the display unit;
Illuminance around the display unit detected by the detection unit is less than or equal to the first reference illuminance, generates an output luminance and the second color light of the first pixel circuit for emitting the first color light The ratio of the output luminance of the second pixel circuit is lowered so as to be different from the ratio of the input image signal of the first pixel circuit and the input image signal of the second pixel circuit, and the illuminance is reduced to the first reference illuminance. In the above case, the ratio between the output luminance of the first pixel circuit and the output luminance of the second pixel circuit is set to the ratio between the input image signal of the first pixel circuit and the input image signal of the second pixel circuit. a control unit that maintain substantially constant,
An image display device comprising:
A display unit having a first pixel circuit that emits light of a first color, a second pixel circuit that emits light of a second color, and a third pixel circuit that emits light of a third color;
Converting a first input gradation value corresponding to the first pixel circuit to a first output gradation value, converting a second input gradation value corresponding to the second pixel circuit to a second output gradation value; A conversion unit that converts a third input gradation value corresponding to the third pixel circuit into a third output gradation value;
A detection unit for detecting illuminance around the display unit;
When the illuminance around the display unit detected by the detection unit is equal to or lower than the first reference illuminance and higher than the second reference illuminance, the second and third input gradation values are set to the first input floor. The display unit is controlled so that the first output gradation value is relatively larger than the second and third output gradation values, and the light emission luminance of the display unit is reduced. And the ratio of the first output tone value, the second output tone value, and the third output tone value is set to the first input tone value when the illuminance is not less than the first reference illuminance. value, said second input tone value, and the third that maintain the ratio and at a substantially constant input tone value control unit,
An image display device comprising:
The image display device according to claim 2,
The control unit is
When the illuminance around the display unit detected by the detection unit is less than or equal to the second reference illuminance, the first output gradation value is relatively smaller than the second output gradation value. An image display device that is controlled as described above.
The image display device according to claim 3,
The control unit is
When the illuminance around the display unit detected by the detection unit is equal to or lower than a third reference illuminance lower than the second reference illuminance, the first output floor is higher than the second and third output gradation values. An image display apparatus, wherein control is performed so that a tone value becomes relatively small.
An image display device according to any one of claims 2 to 4,
A power supply for supplying a voltage necessary for light emission to the first to third pixel circuits;
With
The control unit is
In accordance with a decrease in illuminance around the display unit detected by the detection unit, the voltage supplied from the power supply unit to the first to third pixel circuits is controlled, and the emission luminance of the display unit is controlled. An image display device that is controlled to be small.
An image display device according to any one of claims 2 to 5,
The second and third colors are
An image display device including blue and green.
The image display device according to any one of claims 2 to 6,
The control unit is
An image display device characterized by adjusting a γ table and controlling to reduce the light emission luminance of the display unit.
The image display device according to any one of claims 2 to 7,
The display unit is
A substrate and a transistor provided by stacking semiconductors on the substrate;
The detection unit is
An image display device, wherein a semiconductor is stacked on the substrate.
The image display device according to any one of claims 2 to 7,
The display unit is
A transparent layer provided on the front side from which light is emitted from the first to third pixel circuits;
The detection unit is
An image display device provided near an end of the transparent layer.

Images