JP2019144314A - Display device and control method of the same - Google Patents

Abstract

To provide such technology capable of suppressing image quality degradation of a display image as well as suppressing temperature elevation of a display panel.SOLUTION: A display device of the present invention has: light-emitting means; display means for displaying an image by transmitting the light emitted by the light-emitting means based on a display image data; acquiring means for acquiring temperature information relating to the temperature of the display means; reducing means for reducing the emission luminance of the emitting means from a set luminance based on the temperature information; and increasing means for increasing a gradation value of a target image data to generate the display image data when the emission luminance of the light-emitting means is reduced from the set luminance.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a display device and a control method thereof.

  Improvement of the fidelity of a display image (an image displayed on a display surface) is desired for a display device. Specifically, it is desired to increase the brightness ratio (contrast ratio; brightness / darkness ratio) between the bright and dark areas of the display image and to improve the accuracy of the change in gradation (gradation) from the bright area to the dark area of the display image. Yes. As a technique for increasing the number of gradations of a display image, there is a technique for individually driving each of two stacked liquid crystal panels. A display device provided with the two liquid crystal panels is called a “dual liquid crystal display device” or the like.

  However, in the conventional dual liquid crystal display device, when the light emitted from the backlight unit is transmitted through two liquid crystal panels, the light emission luminance of the backlight unit is one liquid crystal panel. Higher emission luminance (about twice). Therefore, in the conventional dual liquid crystal display device, the power consumption and the heat generation amount of the backlight unit are larger than in the case where there is one liquid crystal panel, and the temperature of each liquid crystal panel is likely to increase.

  Conventional techniques relating to display devices are disclosed in, for example, Patent Documents 1 and 2. In the technique disclosed in Patent Document 1, display luminance (luminance on the display surface; luminance of the display image) is uniformly reduced over the entire display surface as the temperature of the display device increases. In the technique disclosed in Patent Document 2, the gradation value of image data is increased in accordance with a user operation, and the light emission luminance of the backlight unit is reduced.

JP 2012-198540 A JP 2010-14987 A

  However, in the technique disclosed in Patent Document 1, since the display brightness is uniformly reduced over the entire display surface, the display brightness with very low fidelity (reproducibility) is obtained regardless of the gradation value of the image data. It will be realized (image quality degradation). In the technique disclosed in Patent Document 2, the light emission luminance of the backlight unit is reduced according to a user operation. However, since the temperature of the liquid crystal panel (display panel) is not taken into consideration, an increase in the temperature of the liquid crystal panel cannot be suppressed.

  An object of the present invention is to provide a technique capable of achieving both suppression of image quality degradation of a display image and suppression of temperature increase of a display panel.

The first aspect of the present invention is:
Light emitting means;
Display means for displaying an image by transmitting light emitted from the light emitting means based on display image data;
Obtaining means for obtaining temperature information relating to the temperature of the display means;
Based on the temperature information, a reducing means for reducing the light emission luminance of the light emitting means from a set luminance;
Increase means for generating the display image data by increasing the gradation value of the target image data when the light emission brightness of the light emitting means is reduced from the set brightness;
It is a display device characterized by having.

The second aspect of the present invention is:
Light emitting means;
Display means for displaying an image by transmitting light emitted from the light emitting means based on display image data;
A display device control method comprising:
Obtaining temperature information relating to the temperature of the display means;
Reducing the emission luminance of the light emitting means from a set luminance based on the temperature information;
When the light emission luminance of the light emitting means is reduced from the set luminance, generating the display image data by increasing the gradation value of the target image data;
It is the control method characterized by having.

  A third aspect of the present invention is a program for causing a computer to execute each step of the control method described above. A fourth aspect of the present invention is a computer-readable storage medium storing a program for causing a computer to execute each step of the control method described above.

  ADVANTAGE OF THE INVENTION According to this invention, suppression of the image quality deterioration of a display image and suppression of the temperature increase of a display panel can be made compatible.

Configuration example of liquid crystal display device according to embodiment 1 Example of processing flow according to Embodiment 1 Example of correspondence relationship between panel temperature and upper limit display luminance according to embodiment 1 Example of correspondence relationship between panel temperature, light emission luminance, and target gradation value according to embodiment 1 Example of correspondence relationship between target gradation value and display gradation value according to embodiment 1 Example of correspondence relationship between target gradation value and display luminance according to embodiment 1 Example of correspondence relationship between panel temperature and upper limit display luminance according to embodiment 1 Example of correspondence relationship between panel temperature and upper limit display luminance according to embodiment 2 Example of correspondence relationship between panel temperature, light emission luminance, and target gradation value according to embodiment 2 Example of correspondence relationship between target gradation value and display gradation value according to embodiment 2 Example of correspondence relationship between target gradation value and display luminance according to embodiment 2 Configuration example of liquid crystal display device according to embodiment 3 Example of correspondence relationship between target gradation value and display gradation value according to embodiment 3 Example of correspondence relationship between first target gradation value and first display gradation value according to embodiment 3 Example of correspondence relationship between target gradation value and display gradation value according to embodiment 3 Example of correspondence relationship between panel temperature, light emission luminance, and increase rate according to Example 4 Example of correspondence relationship between APL, emission luminance, and increase rate according to Example 4

<Example 1>
Embodiment 1 of the present invention will be described below. The display device according to the present embodiment includes a light emitting unit and a display unit that displays an image on a display surface by transmitting light emitted from the light emitting unit based on display image data. Below, the example of a liquid crystal display device is demonstrated. The display device is not limited to a liquid crystal display device. For example, a display device is a MEMS (Mic) instead of a liquid crystal panel.
(ro Electro Mechanical System) A shutter-type display panel may be included. The display device may be a projector.

  FIG. 1 is a block diagram illustrating a configuration example of a liquid crystal display device 100 according to the present embodiment. The liquid crystal display device 100 includes an image input unit 101, an image processing unit 102, a panel drive circuit 103, a liquid crystal panel 104, a backlight unit 105, a backlight drive circuit 106, a panel temperature detection unit 107, a storage unit 108, and a control unit. 110.

  The image input unit 101 acquires image data output from an external device (not shown) (an imaging device, a playback device, etc.). Then, the image input unit 101 outputs the acquired image data (input image data) to the image processing unit 102. Note that the image input unit 101 may acquire the image data recorded in the storage unit 108 from the storage unit 108.

  The image processing unit 102 generates target image data by performing predetermined processing on the input image data output from the image input unit 101. Then, the image processing unit 102 outputs the target image data to the panel drive circuit 103. The predetermined processing includes, for example, decoding processing, resolution conversion processing, blurring processing, edge enhancement processing, luminance conversion processing, color conversion processing, and the like, and is performed according to an instruction from the control unit 110. Note that input image data may be used as target image data without performing predetermined processing.

The image processing unit 102 may generate luminance data representing the luminance of each pixel of the target image data from the input image data or the target image data. Data formats such as input image data, target image data, and luminance data are not particularly limited. For example, the luminance data may or may not be data indicating the Y value (luminance value) of each pixel. When the pixel value of the target image data is an RGB value (R value, G value, B value) = (R, G, B), the Y value (luminance value) of the target image data is calculated using the following equation. It can be calculated. In the following equations, “α”, “β”, and “γ” are predetermined coefficients (luminance conversion coefficients) for converting RGB values into Y values. When the pixel value of the target image data is a YCbCr value, the Y value of the target image data can be acquired (extracted) from the YCbCr value of the target image data without performing a calculation.

Y = α × R + β × G + γ × B

  The panel drive circuit 103 generates display image data based on the target image data output from the image processing unit 102, an instruction from the control unit 110, and the like. Panel drive circuit 103 then outputs display image data to liquid crystal panel 104. Specifically, the panel drive circuit 103 generates a panel drive signal (voltage or current) corresponding to the display image data based on the target image data, an instruction from the control unit 110, and the like. The panel drive circuit 103 supplies a panel drive signal to the liquid crystal panel 104.

  The liquid crystal panel 104 displays an image on the display surface by transmitting the light emitted from the backlight unit 105 based on the display image data. Specifically, the panel drive signal is supplied from the panel drive circuit 103 to each liquid crystal element of the liquid crystal panel 104, whereby the transmittance of each liquid crystal element is controlled to the transmittance corresponding to the panel drive signal. In this state, light emitted from the backlight unit 105 is transmitted through each liquid crystal element, whereby an image is displayed on the display surface.

The data format of the display image data, the characteristics of the liquid crystal panel 104 (each liquid crystal element), the method for controlling the transmittance of the liquid crystal panel 104, and the like are not particularly limited. For example, the gradation value of the display image data is an 8-bit value (a value between 0 and 255), and the transmittance corresponding to the gradation value (display gradation value) of the display image data is determined according to a predetermined gamma curve. The transmittance of the liquid crystal element is controlled. The gamma curve is a curve (function) representing the correspondence between the display gradation value and the transmittance of the liquid crystal panel 104, and the predetermined gamma curve is, for example, a gamma curve with a gamma value = 2.2. When the transmittance of the liquid crystal element is controlled to X%, X% of the light irradiated to the liquid crystal element transmits the liquid crystal element. When the transmittance of the liquid crystal element is controlled to 0%, the light applied to the liquid crystal element is substantially completely blocked by the liquid crystal element (“abbreviation” includes “complete”). When the transmittance of the liquid crystal element is controlled to 100%, the light applied to the liquid crystal element is transmitted almost completely through the liquid crystal element.

  The backlight unit 105 irradiates the back surface of the liquid crystal panel 104 with light. When a backlight drive signal (voltage or current) is supplied from the backlight drive circuit 106 to the backlight unit 105, the light emission luminance of the backlight unit 105 is controlled to the light emission luminance corresponding to the backlight drive signal. Specifically, the backlight unit 105 includes one or more light sources (light emitting elements), and the backlight driving signal is supplied to the light source of the backlight unit 105, so that the light emission luminance of the light source is changed to the backlight driving. The light emission brightness is controlled according to the signal. As the light source, an LED, an organic EL element, a cold cathode tube (CCFL), or the like can be used.

  Note that the structure of the backlight unit 105 is not particularly limited. For example, an edge-type backlight unit having a light guide plate may be used as the backlight unit 105. As the backlight unit 105, a direct type backlight unit provided with a light source so as to face the back surface of the liquid crystal panel 104 may be used. In the backlight unit 105, light of a color different from the emission color of the light source may be generated by excitation of a photophosphor or a quantum dot. In that case, light emitted from the light source (light that causes excitation) is red light, green light, blue light, cyan light, magenta light, yellow light, ultraviolet light (including near ultraviolet light), and the like. Light generated by excitation is red light, green light, blue light, cyan light, magenta light, yellow light, and the like.

  The backlight drive circuit 106 generates a backlight drive signal based on an instruction from the control unit 110 or the like. Then, the backlight drive circuit 106 supplies a backlight drive signal to the backlight unit 105.

  The light emission luminance of the backlight unit 105 is changed by changing at least one of the magnitude of the backlight drive signal (pulse amplitude, etc.) and the supply time (pulse width, etc.) for supplying the backlight drive signal to the backlight unit 105. Can be changed. The larger the backlight drive signal is, the higher the emission brightness of the backlight unit 105 is controlled. Further, the longer the supply time, the higher the emission luminance of the backlight unit 105 is controlled.

  Here, consider PWM (Pulse Width Modulation) control for controlling the light emission luminance of the backlight unit 105 by controlling the pulse width of a pulse signal that is a backlight drive signal. In the PWM control, for example, a backlight drive signal corresponding to a PWM value (level value) corresponding to the duty ratio is generated. The duty ratio is a ratio of a lighting period of the backlight unit 105 to a predetermined period (a PWM period of a predetermined period; for example, one frame period). Here, it is assumed that the PWM value is 0 or more and 4095 or less. The PWM value 0 corresponds to a duty ratio of 0% and corresponds to the lower limit (0%; extinguishment) of light emission luminance. The PWM value 4095 corresponds to a duty ratio of 100% and corresponds to the upper limit (100%) of the light emission luminance. In this embodiment, in order to make the explanation easy to understand,% is used as a unit of light emission luminance, and% is also used as a unit of gradation value.

In the PWM period, the backlight unit 105 is turned on during a period corresponding to the PWM value, and is turned off during other periods. When the PWM value is 0, the backlight unit 105 is turned off over the entire PWM period. When the PWM value is 4095, the backlight unit 105 lights up over the entire PWM period. When the PWM value is other than those, a part of the PWM period is a lighting period, and the other part of the PWM period is a light extinction period.

  When the timing of the Vsync signal, which is a vertical synchronization signal of the liquid crystal panel 104, is the start timing of one frame, the start timing of the PWM period is determined based on the timing of the Vsync signal. The PWM period may be a period starting from the lighting period of the backlight unit 105 or may be a period starting from the extinguishing period of the backlight unit 105. When the period starting from the lighting period is the PWM period, the period having a length corresponding to the duty ratio (PWM value) from the start timing of the PWM period is set as the lighting period, and the remaining period of the PWM period is the extinguishing period. It is said. When the period starting from the extinguishing period is set as the PWM period, the period from the end timing of the PWM period to the timing retroactive to the time corresponding to the duty ratio (PWM value) is set as the lighting period, and the remaining period of the PWM period The period is the extinguishing period. Here, consider a case where the frequency of the PWM period is 60 Hz. The backlight drive circuit 106 uses the time obtained by dividing 1/60 seconds by 4095 as the increase time of the lighting period when the PWM value increases by one, and the lighting corresponding to the set PWM value Determine the time (length of lighting period). Specifically, the backlight drive circuit 106 determines the lighting time by multiplying the set PWM value by the increase time. When the frame frequency is 60 Hz, the length of the PWM period is equal to the length of one frame period.

  Note that the characteristics of the backlight unit 105, the method for controlling the light emission luminance of the backlight unit 105, and the like are not particularly limited. For example, the backlight unit 105 may be repeatedly turned on and off during the PWM period. The backlight unit 105 may include a plurality of light source units, and the backlight drive circuit 106 may individually generate a backlight control signal for each of the plurality of light source units. Each light source unit has one or more light sources. Thereby, the light emission luminance of each light source unit can be individually controlled. In this case, the backlight drive circuit 106 is configured using a plurality of constant current circuits, a plurality of PWM drive circuits, and the like.

  The panel temperature detection unit 107 acquires temperature information related to the temperature of the liquid crystal panel 104 and outputs the acquired temperature information to the control unit 110. In this embodiment, the panel temperature detection unit 107 is a sensor that detects the temperature of the liquid crystal panel 104, and outputs the detected value to the control unit 110 as temperature information.

  The temperature information may be information indicating the temperature of the liquid crystal panel 104 or may be other information related to the temperature of the liquid crystal panel 104. For example, the panel temperature detection unit 107 detects a temperature highly relevant to the temperature of the liquid crystal panel 104 (the temperature of the backlight unit 105, the temperature between the backlight unit 105 and the liquid crystal panel 104, etc.), and the detected value May be output as temperature information. The panel temperature detection unit 107 may estimate the temperature of the liquid crystal panel 104 from the temperature highly related to the temperature of the liquid crystal panel 104 and output the estimated value as temperature information. The sensor which is the panel temperature detection part 107 is attached to the liquid crystal panel 104 or the backlight part 105, for example.

  Panel temperature detection unit 107 may estimate the temperature of liquid crystal panel 104 from other information in liquid crystal display device 100 and output the estimated value as temperature information. As other information, for example, at least one of the driving conditions (emission luminance, backlight control signal, PWM value, etc.) of the backlight unit 105, the driving time of the liquid crystal display device 100, and the time accumulated value of the representative display luminance. Can be used. The representative display luminance is a representative value of display luminance (luminance on the display surface) at each position on the display surface. For example, an average value, maximum value, minimum value, intermediate value of display luminance at each position on the display surface, Mode, etc.

The storage unit 108 stores various information. For example, the storage unit 108 displays temperature-display luminance information (table or function) indicating the correspondence between the temperature of the liquid crystal panel 104 (detected value of the panel temperature detection unit 107) and the upper limit display luminance (upper limit of display luminance). Remember. The storage unit 108 also stores display luminance-light emission luminance information (table or function) indicating the correspondence between the upper limit display luminance and the light emission luminance of the backlight unit 105. The storage unit 108 also stores display luminance-increase rate information (table or function) indicating the correspondence between the upper limit display luminance and the gradation value increase rate. Such information is determined in advance, for example, when the liquid crystal display device 100 is manufactured. Furthermore, the storage unit 108 stores a program for performing various processes (controls) described later.

  The control unit 110 is configured by a CPU or FPGA (Field Programmable Gate Array), and implements various processes described later by executing programs read from the storage unit 108. For example, the control unit 110 outputs an instruction to the backlight drive circuit 106 so that the light emission luminance of the backlight unit 105 is reduced from the set luminance based on the temperature information output from the panel temperature detection unit 107. The set brightness is a preset light emission brightness, such as a light emission brightness predetermined by a manufacturer, a light emission brightness in accordance with a user operation, a light emission brightness based on target image data, and the like. In this embodiment, the set luminance is 100%. Then, when the light emission luminance of the backlight unit 105 is reduced from the set luminance, the control unit 110 increases the gradation value (target gradation value) of the target image data and generates display image data. An instruction is output to the drive circuit 103. When the light emission luminance of the backlight unit 105 is halved, the display luminance can be kept substantially constant by increasing each gradation value of the target image data so that the transmittance of the liquid crystal panel 104 is doubled.

  In the present embodiment, the control unit 110 determines the upper limit display luminance based on the temperature information. Specifically, control unit 110 acquires the upper limit display brightness corresponding to the temperature indicated by the temperature information (the temperature of liquid crystal panel 104) from the temperature-display brightness information. Then, the control unit 110 outputs an instruction to the backlight drive circuit 106 so that the light emission luminance of the backlight unit 105 is reduced from the set luminance based on the acquired upper limit display luminance. Specifically, the control unit 110 acquires the light emission luminance corresponding to the acquired upper limit display luminance from the display luminance-light emission luminance information, and transmits the acquired light emission luminance (or PWM value or the like) to the backlight drive circuit 106. Notice. The backlight drive circuit 106 generates a backlight drive signal so that the backlight unit 105 emits light with the light emission luminance notified from the control unit 110. In addition, the control unit 110 acquires an increase rate corresponding to the acquired upper limit display luminance from the display luminance-increase rate information, and notifies the panel drive circuit 103 of the acquired increase rate. The panel drive circuit 103 generates display image data (panel drive signal) by increasing each gradation value of the target image data at the increase rate notified from the control unit 110.

  In addition, the process of the control part 110 is not restricted to the said process. For example, instead of the display luminance-emission luminance information, temperature-emission luminance information (a table or the like) indicating the correspondence between the temperature of the liquid crystal panel 104 (detected value of the panel temperature detection unit 107) and the emission luminance of the backlight unit 105 is used. Function) may be prepared in advance. Then, the control unit 110 may acquire the light emission luminance corresponding to the temperature indicated by the temperature information from the temperature-light emission luminance information. The control unit 110 acquires the decrease rate of the emission luminance, and the control unit 110 or the backlight drive circuit 106 determines the emission luminance of the backlight unit 105 by reducing the set luminance at the acquired decrease rate. Also good.

  Instead of the display luminance-increase rate information, temperature-increase rate information (table or function) indicating the correspondence between the temperature of the liquid crystal panel 104 (detected value of the panel temperature detection unit 107) and the increase rate is prepared in advance. Also good. And the control part 110 may acquire the increase rate corresponding to the temperature shown by temperature information from temperature-increase rate information. Light emission luminance-increase rate information (table or function) indicating a correspondence relationship between the light emission luminance of the backlight unit 105 and the increase rate may be prepared in advance. And the control part 110 may acquire the increase rate corresponding to the acquired light emission luminance from light emission luminance-increase rate information.

  FIG. 2 is a flowchart illustrating an example of a processing flow of the control unit 110. The processing flow in FIG. 2 is started in response to, for example, a power ON operation for turning on the liquid crystal display device 100.

  In step S <b> 111, control unit 110 acquires temperature information that is a detected value of the temperature of liquid crystal panel 104 from panel temperature detection unit 107.

  In step S112, control unit 110 determines whether or not the temperature (temperature of liquid crystal panel 104; panel temperature) indicated by the temperature information in step S111 is higher than a threshold value. Although the threshold value compared with the temperature of the liquid crystal panel 104 is not particularly limited, it is assumed that the threshold value is 40 ° C. in this embodiment. Note that the threshold value to be compared with the temperature of the liquid crystal panel 104 may or may not be a fixed value determined in advance by the manufacturer. For example, the threshold value compared with the temperature of the liquid crystal panel 104 may be a value (temperature) designated by the user.

  If it is determined that the temperature of the liquid crystal panel 104 is higher than the threshold value, the process proceeds to step S114; otherwise, the process proceeds to step S113. Thereby, when the temperature of the liquid crystal panel 104 is higher than the threshold value, the light emission luminance of the backlight unit 105 is reduced from the set luminance. Note that the light emission luminance of the backlight unit 105 may be reduced from the set luminance regardless of whether or not the temperature of the liquid crystal panel 104 is higher than the threshold value.

  In step S113, panel drive circuit 103 and backlight drive circuit 106 perform normal operations. For example, the panel drive circuit 103 uses the target image data as display image data, and the backlight drive circuit 106 controls the light emission luminance of the backlight unit 105 to 100% (set luminance).

In step S114, control unit 110 acquires the upper limit display luminance corresponding to the temperature (temperature of liquid crystal panel 104) indicated by the temperature information in step S111 from the temperature-display luminance information. FIG. 3 shows an example of the correspondence indicated by the temperature-display luminance information. According to the correspondence 120 in FIG. 3, when the temperature of the liquid crystal panel 104 is higher than 40 ° C. (when the temperature of the liquid crystal panel 104 exceeds 40 ° C.), the upper limit display luminance is 1000 cd / m ² to 600 cd / m. Reduced to ² . In this embodiment, the upper limit display luminance is determined according to the correspondence 120.

In step S115, control unit 110 acquires the light emission luminance corresponding to the upper limit display luminance acquired in step S114 from the display luminance-light emission luminance information. FIG. 4A shows an example of a correspondence relationship between the temperature of the liquid crystal panel 104 (the detection value of the panel temperature detection unit 107) and the light emission luminance of the backlight unit 105. The correspondence 122 in FIG. 4A is a correspondence according to temperature-display luminance information and display luminance-light emission luminance information. In this embodiment, the light emission luminance is determined according to the correspondence 122. According to the correspondence 122, when the temperature of the liquid crystal panel 104 is higher than 40 ° C., the light emission luminance (light emission luminance ratio) of the backlight unit 105 is reduced from 100% to 60%. Therefore, when the temperature of the liquid crystal panel 104 is 40 ° C. or lower, the emission luminance of the backlight unit 105 is set to 100% regardless of the corresponding gradation value as in the correspondence 123 in FIG. Be controlled. When the temperature of the liquid crystal panel 104 is higher than 40 ° C., the light emission luminance of the backlight unit 105 is set to 60% regardless of the corresponding gradation value as in the correspondence 124 in FIG. Be controlled. A light emission luminance of 100% is a light emission luminance capable of realizing an upper limit display luminance of 1000 cd / m ² , and a light emission luminance of 60% is a light emission luminance capable of realizing an upper limit display luminance of 600 cd / m ² .

In step S116, control unit 110 acquires an increase rate corresponding to the upper limit display luminance acquired in step S114 from the display luminance-increase rate information. In the present embodiment, when the light emission luminance of the backlight unit 105 is reduced from 100%, an increase rate is obtained so that the display luminance below the upper limit display luminance is kept substantially constant. Specifically, when the light emission luminance of the backlight unit 105 is 100%, the target gradation value is used as the display gradation value as it is, as in the correspondence 125 in FIG. Then, when the light emission luminance of the backlight unit 105 is reduced from 100% to 60%, an increase rate that realizes the correspondence 126 of FIG. 5 is acquired. The correspondence 126 can be realized by using an increase rate of 1.67 (= 100/60) such that the target gradation value 60% is converted to the display gradation value 100%. Note that, as in the correspondence 126, a target gradation value larger than 60% is converted into a display gradation value of 100% (gradation value clipping; gradation value saturation).

  In step S117, the control unit 110 notifies the backlight drive circuit 106 of the light emission luminance acquired in step S115, and notifies the panel drive circuit 103 of the increase rate acquired in step S116. Thereafter, the backlight drive circuit 106 controls the light emission luminance of the backlight unit 105 to the light emission luminance 60% acquired in step S115. The panel drive circuit 103 generates display image data by increasing each gradation value of the target image data by the increase rate 1.67 acquired in step S116. In other words, the panel drive circuit 103 generates display image data by converting each gradation value of the target image data according to the correspondence 126 in FIG. The panel drive circuit 103 controls the transmittance of the liquid crystal panel 104 based on the generated display image data.

  In step S118, control unit 110 determines whether or not a power-off operation for turning off power to liquid crystal display device 100 has been performed. If it is determined that the power-off operation has been performed, the process flow ends. If not, the process returns to step S111.

When the temperature of the liquid crystal panel 104 is 40 ° C. or less according to the processing flow of FIG. 2, the display luminance is increased with respect to the increase in the target gradation value from 0% to 100% as in the correspondence 127 of FIG. Increases from 0 cd / m ² to 1000 cd / m ² . When the temperature of the liquid crystal panel 104 exceeds 40 ° C., the display brightness of the upper limit display brightness of 600 cd / m ² or less is kept substantially constant as shown by the correspondence 128 in FIG. In other words, the display brightness of the upper limit display brightness of 600 cd / m ² or less substantially matches the display brightness of the correspondence 127. Then, the display luminance corresponding to the target gradation value larger than 60% is reduced to the upper limit display luminance 600 cd / m ² (display luminance clip; display luminance saturation).

  As described above, according to the present embodiment, the light emission luminance of the backlight unit 105 is reduced from the set luminance based on the temperature information (temperature of the liquid crystal panel 104). Thereby, the temperature increase of the liquid crystal panel 104 can be suppressed, and deterioration or failure of the liquid crystal panel 104 can be suppressed. When the light emission luminance of the backlight unit 105 is reduced from the set luminance, display image data is generated by increasing the gradation value of the target image data. Thereby, it is also possible to suppress deterioration in image quality of the display image (image displayed on the display surface). That is, according to the present embodiment, it is possible to achieve both suppression of image quality degradation of a display image and suppression of temperature increase of the liquid crystal panel 104.

  Note that the various correspondence relationships are not limited to the above-described correspondence relationships. For example, the correspondence between the temperature of the liquid crystal panel 104 and the light emission luminance of the backlight unit 105, the correspondence between the temperature of the liquid crystal panel 104 and the upper limit display luminance, and the like are determined based on the temperature characteristics and heat dissipation performance of the liquid crystal panel 104. May be. Like the correspondence 129 in FIG. 7, the temperature range of the liquid crystal panel 104 may include a plurality of ranges in which the inclination of the correspondence between the temperature of the liquid crystal panel 104 and the upper limit display luminance is different from each other. In this case, the slopes of the correspondence relationship between the temperature of the liquid crystal panel 104 and the light emission luminance of the backlight unit 105 are different between the plurality of ranges.

<Example 2>
Embodiment 2 of the present invention will be described below. In Example 1, the display luminance is saturated. In this embodiment, an example will be described in which the display luminance is not saturated. Hereinafter, points (configuration and processing) different from those in the first embodiment will be described in detail, and descriptions of the same points as those in the first embodiment will be omitted.

In the present embodiment, the same processing as that of the first embodiment is performed in steps S111 to S113, S117, and S118 of FIG. In step S114, the upper limit display luminance is determined according to the correspondence 220 in FIG. According to correspondence 220, when the temperature of the liquid crystal panel 104 is higher than 40 ° C., the upper limit display brightness is reduced from 1000 cd / ^{m 2} to 800 cd / ^{m 2.}

In step S115, the light emission luminance of the backlight unit 105 is determined in accordance with the correspondence 222 in FIG. According to the correspondence relationship 222, when the temperature of the liquid crystal panel 104 is higher than 40 ° C., the light emission luminance of the backlight unit 105 is reduced from 100% to 80%. Therefore, when the temperature of the liquid crystal panel 104 is higher than 40 ° C., the light emission luminance of the backlight unit 105 is set to 80% regardless of the target gradation value as in the correspondence 224 in FIG. 9B. Be controlled. The light emission luminance of 80% is a light emission luminance capable of realizing the upper limit display luminance of 800 cd / m ² .

  In step S116, control unit 110 obtains an increase rate that does not cause display luminance saturation. Specifically, an increase rate that realizes the correspondence 226 in FIG. 10 is acquired. In the range from the target gradation value 0% to the target gradation value 60%, the increase rate for increasing the display gradation value from 0% to 75% with respect to the increase in the target gradation value from 0% to 60%. 1.25 (= 100/80) is acquired. For the range from the target gradation value 60% to the target gradation value 100%, the increase rate for increasing the display gradation value from 75% to 100% with respect to the increase in the target gradation value from 60% to 100%. 0.625 is acquired. The correspondence 226 can be realized by these two increasing rates. For the range from the target gradation value 0% to the target gradation value 60%, the display gradation value can be calculated by multiplying the target gradation value by the increase rate. For the range from the target gradation value 60% to the target gradation value 100%, the display gradation value can be calculated by the expression “(target gradation value−60%) × increase rate + 75%”. In the correspondence relationship 226, gradation value saturation does not occur.

In this embodiment, the processing flow of FIG. 2, when the temperature of the liquid crystal panel 104 exceeds 40 ° C., as in the relationship 228 in FIG. 11, the upper display luminance 800 cd / ^m lower than ² 600 cd / ^{m 2} The display brightness below (specific brightness or below) is kept substantially constant. In other words, the display luminance of the specific luminance of 600 cd / m ² or less substantially matches the display luminance of the correspondence 127. In the range from the target gradation value 60% to the target gradation value 100%, the display luminance is increased from the specific luminance 600 cd / m ² to the upper limit display luminance with respect to the increase in the target gradation value from 60% to 100%. to increase up to 800cd / ^{m 2.} For this reason, display luminance saturation does not occur.

  As described above, according to the present embodiment, when the emission luminance of the backlight unit 105 is reduced from the set luminance, the gradation value of the target image data is increased so that the display luminance is not saturated. Display image data is generated. Thereby, the image quality deterioration of a display image can be suppressed more. Specifically, it is possible to obtain a display image that expresses the difference in the target gradation value for the bright portion of the target image data.

<Example 3>
Embodiment 3 of the present invention will be described below. In this embodiment, an example in which a liquid crystal display device has a plurality of liquid crystal panels will be described. In the following, points (configuration and processing) that are different from the first and second embodiments will be described in detail, and a description of the same points as the first and second embodiments will be omitted.

FIG. 12 is a block diagram illustrating a configuration example of the liquid crystal display device 300 according to the present embodiment. The liquid crystal display device 300 includes an image input unit 301, an image processing unit 302, a first panel drive circuit 303, a first liquid crystal panel 304, a backlight unit 305, a backlight drive circuit 306, a panel temperature detection unit 307, and a storage unit. 308 and a control unit 310. Further, the liquid crystal display device 300 includes a second panel drive circuit 311 and a second liquid crystal panel 312.

  The image input unit 301 has the same function as the image input unit 101 of the first and second embodiments. The image processing unit 302 has the same function as the image processing unit 102 of the first and second embodiments. However, the image processing unit 302 generates first target image data and second target image data as target image data. Then, the image processing unit 302 outputs the first target image data to the first panel drive circuit 303, and outputs the second target image data to the second panel drive circuit 311. Note that the first target image data may be the same as or different from the second target image data.

  Each of the first panel drive circuit 303 and the second panel drive circuit 311 has the same function as the panel drive circuit 103 of the first and second embodiments. The first panel drive circuit 303 generates first display image data based on the first target image data and the like, and outputs the first display image data to the first liquid crystal panel 304. The second panel drive circuit 311 generates second display image data based on the second target image data and the like, and outputs the second display image data to the second liquid crystal panel 312.

  Each of the first liquid crystal panel 304 and the second liquid crystal panel 312 has the same function as the liquid crystal panel 104 of the first and second embodiments. The first liquid crystal panel 304 transmits light emitted from the backlight unit 305 based on the first display image data. The second liquid crystal panel 312 displays an image on the display surface by transmitting the light emitted from the backlight unit 305 and transmitted through the first liquid crystal panel 304 based on the second display image data. In this embodiment, for easy understanding, as shown in FIG. 13, the first display gradation value (the gradation value of the first display image data) and the second display gradation value (the second display gradation value) ) Of the display image data) corresponds to the display gradation values of the first and second embodiments. That is, when the combination of the first liquid crystal panel 304 and the second liquid crystal panel 312 is regarded as the liquid crystal panel 104 of the first and second embodiments, the transmittance of the liquid crystal panel 104 has a combined gradation value (first The transmittance is controlled in accordance with the sum of the display gradation value and the second display gradation value. In FIG. 13, the correspondence relationship 321 is a correspondence relationship between the first target gradation value (the gradation value of the first target image data) and the first display gradation value, and the correspondence relationship 322 is a second relationship. Is a correspondence relationship between the target gradation value (the gradation value of the second target image data) and the second display gradation value. The correspondence relationship 323 is a composite correspondence relationship that is the sum of the correspondence relationship 321 and the correspondence relationship 322, and corresponds to the correspondence relationship between the target gradation value of the first and second embodiments and the display gradation value of the first and second embodiments. . The correspondences 321 to 333 are correspondences when the light emission luminance of the backlight unit 305 is 100%.

  The backlight unit 305 has the same function as the backlight unit 105 of the first and second embodiments. The panel temperature detection unit 307 has the same function as the panel temperature detection unit 107 of the first and second embodiments. In the present embodiment, the panel temperature detection unit 307 is a sensor that detects the temperature of the first liquid crystal panel 304 and outputs the detected value to the control unit 310 as temperature information. Note that the panel temperature detection unit 307 may detect the temperature of the second liquid crystal panel 312 or may detect the average temperature of the first liquid crystal panel 304 and the second liquid crystal panel 312. Information regarding the temperature of the display unit including the first liquid crystal panel 304 and the second liquid crystal panel 312 may be acquired as temperature information. The storage unit 308 has the same function as the storage unit 108 of the first and second embodiments. The control unit 310 has the same function as the control unit 110 of the first and second embodiments.

An example of the processing flow of the control unit 310 will be described with reference to FIG. The processes in steps S111 to S113 and S118 are the same as those in the first and second embodiments. In step S114, the upper limit display luminance is determined in accordance with the correspondence 220 in FIG. Therefore, when the temperature of the liquid crystal panel 104 is higher than 40 ° C., the upper limit display brightness is reduced from 1000 cd / ^{m 2} to 800 cd / ^{m 2.} In step S115, the light emission luminance of the backlight unit 105 is determined in accordance with the correspondence 222 in FIG. Therefore, when the temperature of the liquid crystal panel 104 is higher than 40 ° C., the light emission luminance of the backlight unit 105 is reduced from 100% to 80%.

  In step S116, control unit 110 acquires an increase rate for increasing the first target gradation value in accordance with the upper limit display luminance acquired in step S114. Specifically, an increase rate that realizes the correspondence 324 in FIG. 14 is acquired. For the range from the first target gradation value 0% to the first target gradation value 60%, the first display gradation with respect to the increase in the first target gradation value from 0% to 60% An increase rate of 1.5 is obtained which increases the value from 0% to 90%. For the range from the first target gradation value 60% to the first target gradation value 100%, the first display gradation is increased with respect to the increase in the first target gradation value from 60% to 100%. An increase rate of 0.25 is obtained that increases the value from 90% to 100%. In the correspondence 324, saturation of gradation values does not occur.

  When the combination of the first liquid crystal panel 304 and the second liquid crystal panel 312 is regarded as the liquid crystal panel 104 of the first and second embodiments by the process of step S116, the composite correspondence 326 in FIG. 15 is realized. It becomes. Even in the composition correspondence 326, saturation of gradation values does not occur. Note that even if gradation value saturation occurs in one generation of the first display image data and second display image data, if gradation value saturation does not occur in the other generation, the level in the composite correspondence relationship does not occur. Saturation of tone values does not occur.

  In step S117, the control unit 310 notifies the backlight drive circuit 306 of the light emission luminance acquired in step S115, and notifies the first panel drive circuit 303 of the increase rate acquired in step S116. Thereafter, the backlight drive circuit 306 controls the light emission luminance of the backlight unit 305 to the light emission luminance 80% acquired in step S115. The first panel drive circuit 303 generates first display image data by increasing each gradation value of the first target image data at the increase rate acquired in step S116. In other words, the first panel drive circuit 303 converts the gradation values of the first target image data according to the correspondence 324 in FIG. 14 to generate first display image data. Then, the first panel drive circuit 303 controls the transmittance of the first liquid crystal panel 304 based on the generated first display image data. The second panel drive circuit 311 controls the transmittance of the first liquid crystal panel 304 using the second target image data as the second display image data.

Also in the present embodiment, the same effect as that of the second embodiment can be obtained as an effect of the processing flow of FIG. Specifically, when the temperature of the liquid crystal panel 104 exceeds 40 ° C., a display luminance of a specific luminance of 600 cd / m ² or lower, which is lower than the upper limit display luminance of 800 cd / m ² , as shown in the correspondence 228 of FIG. It is kept almost constant. For a range from 60% to the target gradation value (first target gradation value or second target gradation value) 60% to the target gradation value 100%, the target gradation value from 60% to 100% The display luminance increases from the specific luminance 600 cd / m ² to the upper limit display luminance 800 cd / m ^{2 with} respect to the increase. For this reason, display luminance saturation does not occur.

  As described above, according to the present embodiment, in the liquid crystal display device having a plurality of liquid crystal panels, the same effects as in the first and second embodiments can be obtained by the same processing as in the first and second embodiments.

  In the present embodiment, the example in which the first display image data is generated by increasing the gradation value of the first target image data has been described. However, the gradation value of the second target image data is increased. Second display image data may be generated. A process of generating the first display image data by increasing the gradation value of the first target image data, and a process of generating the second display image data by increasing the gradation value of the second target image data One may be performed, or both may be performed.

<Example 4>
Embodiment 4 of the present invention will be described below. In the present embodiment, an example will be described in which the temperature of the liquid crystal panel is easily lowered in consideration of the representative luminance of the target image data. The representative luminance is a representative value (average value, maximum value, minimum value, intermediate value, mode value, etc.) of the luminance of the target image data. Specifically, the representative luminance is a representative value (average value (APL), maximum value, minimum value, intermediate value, mode value, etc.) of the Y value of the target image data. APL (Average Picture Level) can be calculated by dividing the total Y value of each pixel of the target image data by the total number of pixels. In the following, points (configuration and processing) that are different from the first and second embodiments will be described in detail, and a description of the same points as the first and second embodiments will be omitted.

In the present embodiment, similarly to the first embodiment, the upper limit display luminance is determined according to the correspondence 120 in FIG. Therefore, when the temperature of the liquid crystal panel 104 is higher than 40 ° C., the upper limit display brightness is reduced from 1000 cd / ^{m 2} to 600 cd / ^{m 2.} In Example 1, according to the upper limit display luminance 600 cd / m ² , the light emission luminance 60% is determined as in the correspondence 421 in FIG. 16A, and the increase rate 1.67 is determined as in the correspondence 422. . In this embodiment, when the representative brightness of the target image data is low, the light emission brightness of the backlight unit 105 is reduced to a light emission brightness lower than that when the representative brightness is high. Specifically, light emission luminance of 50% (about 0.83 times of 60%; about 17% decrease) is determined as in the correspondence 423 in FIG. 16B, and the increase rate 2 (in correspondence 424) 1.67 times 1.67; about 17% increase) may be determined. As a result, the temperature of the liquid crystal panel 104 is more likely to be lower than that in the first embodiment while suppressing deterioration in the image quality of the display image.

  FIG. 17A illustrates an example of a correspondence relationship between APL, which is representative luminance, and light emission luminance of the backlight unit 105. When the temperature of the liquid crystal panel 104 is 40 ° C. or lower, as in the correspondence 425, the light emission luminance of 100% is determined regardless of the representative luminance. When the temperature of the liquid crystal panel 104 is higher than 40 ° C., the light emission luminance is determined in consideration of the representative luminance as in the correspondence 426. According to the correspondence 426, when the APL is higher than 50% (threshold), the light emission luminance 60% according to the temperature information (specifically, the upper limit display luminance) is determined, and the APL is 50% or less (below the threshold). ), An emission luminance of 50% lower than 60% is determined. Note that the APL threshold value may or may not be a fixed value predetermined by the manufacturer. For example, the APL threshold may be a value specified by the user.

  FIG. 17B shows an example of a correspondence relationship between APL and increase rate. When the temperature of the liquid crystal panel 104 is 40 ° C. or lower, the increase rate 1 is determined regardless of the representative luminance as in the correspondence 427. When the temperature of the liquid crystal panel 104 is higher than 40 ° C., the increase rate is determined in consideration of the representative luminance as in the correspondence 428. According to the correspondence 428, when APL is higher than 50%, an increase rate of 1.67 according to temperature information (specifically, upper limit display luminance) is determined, and when APL is 50% or less, An increase rate of 2 higher than 1.67 is determined. When APL is low, even if the increase rate is high, saturation of gradation values and display luminance hardly occurs, and a display image in which image quality deterioration is suppressed can be obtained.

  As described above, according to the present embodiment, the light emission luminance of the backlight unit 105 is further reduced in consideration of the representative luminance of the target image data. As a result, the temperature of the liquid crystal panel 104 is more likely to be lower than that of the first embodiment while suppressing deterioration in the image quality of the display image. When the configuration of the present embodiment is combined with the configuration of the third embodiment, the representative luminance corresponding to only one of the first target image data and the second target image data may be used, or both A corresponding representative luminance may be used. An average value or an intermediate value between the representative luminance of the first target image data and the representative luminance of the second target image data may be used. The representative luminance of the input image data may be used.

Each functional unit of the first to fourth embodiments may or may not be individual hardware. The functions of two or more functional units may be realized by common hardware. Each of a plurality of functions of one functional unit may be realized by individual hardware. Two or more functions of one functional unit may be realized by common hardware. Each functional unit may be realized by hardware or not. For example, the apparatus may include a processor and a memory in which a control program is stored. The functions of at least some of the functional units included in the apparatus may be realized by the processor reading and executing the control program from the memory.

  Examples 1-4 are examples to the last, and the structure obtained by changing suitably and changing the structure of Examples 1-4 within the range of the summary of this invention is also contained in this invention. Configurations obtained by appropriately combining the configurations of Examples 1 to 4 are also included in the present invention.

  For example, the user may confirm whether or not to allow the reduction at a timing before the timing at which the light emission luminance of the backlight unit is reduced from the set luminance. In other words, the confirmation may be performed at a timing when the light emission luminance of the backlight unit is reduced. Alternatively, the confirmation may be performed at a timing before the timing at which the light emission luminance of the backlight unit is reduced. Then, the reduction may be performed only when the reduction of the emission luminance is permitted.

  The user may be notified that there is a possibility that the light emission luminance of the backlight unit may be reduced from the set luminance at a timing before the light emission luminance of the backlight unit is reduced from the set luminance. In that case, the confirmation may be further performed or may not be performed.

The timing before the timing at which the light emission luminance of the backlight unit is reduced from the set luminance is, for example, the following timing. In order to determine the timing of (3), you may acquire the information regarding environmental temperature. In order to determine the timing of (4), information regarding the internal temperature may be acquired, or temperature information regarding the temperature of the liquid crystal panel may be used.
(1) Timing that goes back a predetermined time from the timing at which the light emission luminance of the backlight unit is reduced (2) Driving conditions in which the temperature of the liquid crystal panel may exceed a threshold value (display in which light emission luminance above the threshold value is set luminance) (3) Timing when the external environment temperature (environment temperature) of the liquid crystal display device exceeds the threshold value (4) Internal temperature of the liquid crystal display device exceeds the threshold value timing

  The above confirmation may or may not be performed only when the liquid crystal display device is driven under a driving condition in which the internal temperature of the liquid crystal display device may exceed the threshold value of the liquid crystal panel. Various confirmations and notifications to the user are realized by screen display, audio output, lamp lighting, and the like.

  If the reduction of the light emission luminance is not permitted, the remaining time (expected time) until the temperature of the liquid crystal panel reaches the rated temperature of the liquid crystal panel may be notified to the user. The remaining time until the rated temperature is reached is determined based on, for example, display luminance setting, target image data (such as representative luminance), and the like.

<Other examples>
The present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program This process can be realized. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

DESCRIPTION OF SYMBOLS 100,300: Liquid crystal display device 103: Panel drive circuit 104: Liquid crystal panel 105,305: Backlight part 106,306 Backlight drive circuit 107,307: Panel temperature detection part 110,310: Control part 303: 1st panel Drive circuit 304: first liquid crystal panel 311: second panel drive circuit 312: second liquid crystal panel

Claims (16)

Light emitting means;
Display means for displaying an image by transmitting light emitted from the light emitting means based on display image data;
Obtaining means for obtaining temperature information relating to the temperature of the display means;
Based on the temperature information, a reducing means for reducing the light emission luminance of the light emitting means from a set luminance;
Increase means for generating the display image data by increasing the gradation value of the target image data when the light emission brightness of the light emitting means is reduced from the set brightness;
A display device comprising: The display device according to claim 1, wherein the reducing unit reduces the light emission luminance of the light emitting unit from the set luminance when the temperature of the display unit is higher than a first threshold. Determining means for determining an upper limit display luminance based on the temperature information;
The display device according to claim 1, wherein the reducing unit reduces the light emission luminance of the light emitting unit from the set luminance based on the upper limit display luminance. The increasing means increases the gradation value of the target image data so that the display brightness below the upper limit display brightness is kept substantially constant when the light emission brightness of the light emitting means is reduced from the set brightness. The display device according to claim 3. 4. The increase means increases the gradation value of the target image data so that display brightness is not saturated when the light emission brightness of the light emission means is reduced from the set brightness. The display device described in 1. The increasing means is configured to increase the display brightness of the target image data so that a display brightness equal to or lower than a specific brightness lower than the upper limit display brightness is maintained substantially constant when the light emission brightness of the light emitting means is reduced from the set brightness. The display device according to claim 5, wherein the gradation value is increased. 7. The temperature range of the display unit includes a plurality of ranges in which the inclination of the correspondence relationship between the temperature of the display unit and the light emission luminance of the light emitting unit is different from each other. The display device described. The display means includes
First transmission means for transmitting light emitted from the light emitting means;
A second transmission means for displaying an image by transmitting light emitted from the light emitting means and transmitted through the first transmission means;
The display device according to claim 1, comprising: The first transmitting means transmits light emitted from the light emitting means based on first display image data corresponding to first target image data,
The second transmission means transmits light emitted from the light emitting means and transmitted through the first transmission means based on second display image data corresponding to second target image data,
In the case where the light emission luminance of the light emission unit is reduced from the set luminance, the increase unit is
Processing for increasing the gradation value of the first target image data and generating the first display image data;
Processing for increasing the gradation value of the second target image data and generating the second display image data;
The display device according to claim 8, wherein at least one of the following is performed. The reduction means lowers the light emission brightness of the light emitting means based on the temperature information and the representative brightness of the target image data from the set brightness when the representative brightness is high when the representative brightness is low. The display device according to claim 1, wherein the display device is reduced to light emission luminance. The reducing means is
When the representative brightness is higher than a second threshold, the light emission brightness of the light emitting means is reduced from the set brightness according to the temperature information,
The light emission luminance of the light emitting means is reduced from the set luminance to a light emission luminance lower than the light emission luminance according to the temperature information when the representative luminance is equal to or less than the second threshold value. Item 11. The display device according to Item 10. 12. The apparatus according to claim 1, further comprising confirmation means for confirming to a user whether or not to permit the reduction at a timing before a timing at which the light emission luminance of the light emission means is reduced from the set luminance. The display device according to any one of the above. 13. The information processing apparatus according to claim 12, further comprising notification means for notifying the user of a remaining time until the temperature of the display means reaches a rated temperature of the display means when the reduction is not permitted. Display device. Light emitting means;
Display means for displaying an image by transmitting light emitted from the light emitting means based on display image data;
A display device control method comprising:
Obtaining temperature information relating to the temperature of the display means;
Reducing the emission luminance of the light emitting means from a set luminance based on the temperature information;
When the light emission luminance of the light emitting means is reduced from the set luminance, generating the display image data by increasing the gradation value of the target image data;
A control method characterized by comprising:   The program for making a computer perform each step of the control method of Claim 14.   The computer-readable storage medium which stored the program for making a computer perform each step of the control method of Claim 14.

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