JP2011071680A - Video display device and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video display device capable of changing the color temperature more appropriately according to the ambient lighting conditions and the human biorhythm. <P>SOLUTION: A microcomputer 3 operates the color temperature detected by a color temperature detector 6 arranged around a display unit 7, together with color temperature correction values stored in a memory 4, the each correction value being correspondent to each time, and then the environmental color temperature is determined from the operation result. The microcomputer 3 sets the video color temperature based on a table showing the relationship of the environmental color temperature stored in the memory 4 and the video color temperature, and then outputs a color temperature adjustment signal to a color temperature setter 2, and the display unit 7 displays the video image of adjusted color temperature. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a display device capable of automatically setting display conditions such as a television receiver or a personal computer in accordance with a user environment such as an indoor lighting environment around a viewing user.

  Conventionally, it is known that even if the light quality of illumination changes, the human eye has a chromatic adaptation reaction that makes the appearance of the color look the same according to the color temperature of the light source. For example, human eyes illuminate so that the color of the room seen under an incandescent lamp (low color temperature) and the color seen under a fluorescent lamp (high color temperature) do not feel that the color has changed significantly A chromatic adaptation function is provided so as to judge relative colors according to the environment.

  Due to such a color adaptation effect, for example, when the user is viewing a television program or the like, and the indoor lighting environment and the color temperature of the display are different, the difference may feel uncomfortable. Therefore, there is a technique of automatically detecting the color temperature of the room by the color temperature detection means and adjusting the color temperature of the television to the color corresponding to the color temperature (for example, Patent Document 1). With this technology, the color of the room always matches the color of the television, and the user feels uncomfortable.

  By the way, according to recent research reports, there are sleep / wake rhythms that people are active during the day and sleep at night, and body temperature rhythms that are the highest temperature in the evening and the lowest temperature in the morning. There is a report that it is considered to be representative (Non-patent Document 1). The circadian rhythm is a life rhythm that fluctuates in a 24-hour cycle, and light is an important role for maintaining normality. As one of the effects of light on a living body, it is generally known that a person induces sleepiness by secretion of a hormone called melatonin, and light secretion is received by the retina to suppress the secretion of melatonin.

  In addition, there is a correlation between melatonin and color temperature. The higher the color temperature, the stronger the awakening action, and the action that leads to the activation of human life rhythm. The lower the color temperature, the better the mood. It is said that it works to calm down and bring people's life rhythm to a resting state.

  Patent Document 1 discloses a technique for adjusting the color temperature of the display in accordance with the color temperature of the illumination environment around the display by the color temperature detection means. However, in the disclosed technology, the color temperature of the display is adjusted according to the surrounding lighting environment, and the adjustment of the color temperature according to the time is not described. For example, in a room where external light is difficult to enter. In a situation where there is little change in the lighting environment, the color temperature of the video display device cannot be changed, and the user sees the display device having the same color. This is considered to be harmful to the rhythm of the living body for the reasons described above.

  Furthermore, Patent Document 2 discloses a technique related to a camera that adjusts white balance by following the color temperature of outdoor light according to a time zone. However, in the technique disclosed in Patent Document 2, since white balance is adjusted based on the time built in the memory of the camera body in advance, it cannot be adjusted appropriately according to the surrounding lighting environment.

  Therefore, there has been a demand for an image display device that can change the color temperature so as to match the surrounding lighting environment and the biological rhythm of a person.

JP 2003-78920 (published March 14, 2003) JP 62-199191 (published September 2, 1987) Akira Yasugauchi, “Human Adaptability to Illuminated Light-Approach from Physiological Anthropology”, [online], September 5, 2007, Ministry of Education, Culture, Sports, Science and Technology, [Search June 18, 2009], Internet <URL : http: //www.mext.go.jp/b_menu/shingi/gijyutu/gijyutu3/toushin/07091111/006.htm>

  In situations where the indoor lighting environment is unlikely to change, the video display device having only the color temperature detection means without the means for adjusting the color temperature according to the time is the same color temperature as the color temperature of the surrounding illumination. Will be displayed. However, as described above, such a video display device has a problem that it adversely affects human life rhythm. The present invention has been made in view of the above problems, and an object of the present invention is to realize a video display device capable of adjusting a color temperature so as to be adapted to a viewing environment and a human life rhythm.

  The video display device according to the present invention is a video display device comprising color temperature detection means for detecting a color temperature around the display means in order to correct the color temperature of the video displayed on the display means, Color temperature correction means for correcting the color temperature detected by the color temperature detection means according to time is provided.

  According to the video display device according to the present invention, in addition to the conventional technique for detecting ambient light of a video display device, determining the ambient light, and adjusting the color temperature of the display device, the time display depends on time. By correcting the color temperature, it is possible to adjust the color temperature to match the human rhythm even in situations where the surrounding lighting environment is unlikely to change, such as a room without a window or an underground shopping center. A video display device can be provided.

Relationship diagram showing changes in color temperature with time of viewing environment Block configuration diagram of the first embodiment of the present invention Relationship diagram showing change in color temperature correction value with time Relationship diagram showing the color temperature of the image with respect to the environmental color temperature The flowchart regarding the 1st thru | or 4th Example of this invention Block diagram of the second embodiment of the present invention FIG. 6 is a relationship diagram showing changes in color temperature correction values due to weather differences in the second embodiment of the present invention. Flowchart for the third embodiment of the present invention. FIG. 10 is a relational diagram showing a change in color temperature correction value determined by a user according to the third embodiment of the present invention. Block configuration diagram of the fourth embodiment of the present invention The block diagram regarding the LED backlight regarding the 4th Example of this invention Block diagram of the third embodiment of the present invention

  Several embodiments of the invention are described below. In addition, this invention is not limited to a following example.

  A first embodiment of the present invention will be described with reference to FIGS. FIG. 2 is a block diagram of the first embodiment of the present invention. In the first embodiment, the signal processing means 1 inputs a video signal to the color temperature setting means 2. The color temperature detection means 6 is, for example, an RGB sensor, detects the color temperature around the display means 7, and inputs the detected signal to the memory 4 via the microcomputer 3.

  As shown in FIG. 2, the built-in calendar 5 has information such as time and date and outputs it to the microcomputer 3. The memory 4 stores a color temperature correction value table that defines the relationship between the color temperature detected by the color temperature detection means 6, the time and the color temperature correction value as shown in FIG. The microcomputer 3 calculates the color temperature detected by the color temperature detection means 6, the time inputted from the built-in calendar 5, and the color temperature correction value determined from the date information to obtain the environmental color temperature. The environmental color temperature is calculated in the order shown in FIG. That is, the color temperature correction value (B) is calculated by adding the color temperature correction value corresponding to the current time shown in FIG. The color temperature (C) is determined and the value is stored in the memory 4.

  The video color temperature is set by the microcomputer 3 based on a table showing the relationship between the environmental color temperature and the video color temperature stored in advance in the memory 4 as shown in FIG. Output to. The color temperature setting unit 2 sets the input color temperature adjustment signal and the video signal input from the signal processing unit 1 as the color temperature of the video to be displayed on the display unit 7. The display means 7 displays an image according to the output from the color temperature setting means 2.

  Next, the operation of the first embodiment will be described. The color temperature around the display means 7 detected by the color temperature detection means 6 is input to the memory 4 via the microcomputer 3. The color temperature detection means 6 is an RGB sensor, for example, and receives light with a photodiode, performs analog-digital conversion, and outputs a voltage signal. FIG. 1 shows an approximate detection result detected by the color temperature detection means 6 in a room where external light enters and a room where no external light enters for comparison. A broken line is a detection result of the color temperature in a room where external light enters. A solid line is a detection result of the color temperature in a room where no external light enters, and generally corresponds to a daylight fluorescent lamp (about 5000 (K)) used indoors. The built-in calendar 5 inputs time information to the microcomputer 3.

  The microcomputer 3 determines a color temperature correction value corresponding to the time stored in advance in the memory 4 as shown in FIG. 3, and detects the color temperature correction value detected by the color temperature detection means 6 and adds the color temperature correction value to the input color temperature. To calculate the environmental color temperature. Further, the video color temperature is set by the microcomputer 3 based on the table showing the relationship between the environmental color temperature and the video color temperature as shown in FIG. Output to 2. The relationship between the environmental color temperature and the video color temperature as shown in FIG. 4 is a function determined by the characteristics of the video display device.

  In addition, regarding the correction value to be added, the reference value shown on the vertical axis in FIG. 3 is described as (0 (K)) for convenience, but originally, the color temperature of a fluorescent lamp generally used indoors. Value (5000 (K)). In other words, when a room without external light is illuminated by a general fluorescent lamp, the color temperature value detected by the color temperature detection means is about (5000 (K)), and how much is relative to this value? In order to express whether it is added as a color temperature correction value, it is described formally as a reference value (0 (K)). More specifically, for example, the correction value (+7000 (K)) of the color temperature according to the time at noon is added to the color temperature value (5000 (K)) of the fluorescent lamp detected indoors by the color temperature detection means 6. When the calculation is performed, the environmental color temperature becomes (12000 (K)), which matches the color temperature of the blue sky light (about 12000 (K)). Accordingly, the color temperature of the noon video can be displayed even in a situation where the lighting environment does not change. The signal processing means 1 inputs the video signal to the color temperature setting means 2. The color temperature setting means 2 sets the color temperature of the video based on the input color temperature adjustment signal and outputs it to the display means 7. The display means 7 displays an image of the adjusted color temperature. With the above configuration, the color temperature detection means detects the color temperature around the display device, and further corrects by adding the correction value of the color temperature according to the time, thereby taking into account the user's lighting environment and the circadian rhythm of the person An image display device capable of displaying an image can be provided.

Next, a second embodiment of the present invention will be described with reference to FIGS. In FIG. 6, the antenna 11 receives a broadcast signal and outputs it to the tuner 10. The broadcast signal includes, for example, a data broadcast signal having weather-related data in addition to a television broadcast video signal. The tuner 10 selects the received broadcast signal and outputs the video signal and the data broadcast signal to the signal processing means 1. After the signal processing is performed, the signal processing unit 1 outputs the video signal to the color temperature setting unit 2. Further, the signal processing means 1 outputs a data broadcast signal to the microcomputer 3, data relating to the weather in the data broadcast signal is extracted and stored in the memory 4. The color temperature detection means 6 detects the color temperature around the display means 7 and outputs the detected signal to the memory 4 via the microcomputer 3. The built-in calendar 5 has information such as time and date and outputs it to the microcomputer 3. The memory 4 is a color temperature correction value table that defines the relationship between the color temperature detected by the color temperature detection means 6, the time and the color temperature correction value as shown in FIG. Is stored.
The microcomputer 3 selects a color temperature correction value table determined from the time and date information input from the built-in calendar 5 based on the weather-related data stored in the memory 4, and the color temperature detection means 6 An environmental color temperature is calculated by calculating the detected color temperature.

Similarly to the above, the environmental color temperature is calculated in the order shown in FIG. 5, and based on a table showing the relationship between the environmental color temperature and the video color temperature stored in advance in the memory 4 as shown in FIG. The video color temperature is set by the microcomputer 3 and is output to the color temperature setting means 2 as a color temperature adjustment signal.
The color temperature setting unit 2 sets the input color temperature adjustment signal and the video signal input from the signal processing unit 1 as the color temperature of the video to be displayed on the display unit 7. The display means 7 displays an image according to the input from the color temperature setting means 2.

  Next, the operation of the second embodiment will be described. The antenna 11 receives a broadcast signal and outputs it to the tuner 10. The tuner 10 selects the received broadcast signal and outputs the video signal and the data broadcast signal to the signal processing means 1. After the signal processing is performed, the signal processing unit 1 outputs the video signal to the color temperature setting unit 2. Further, the signal processing means 1 outputs a data broadcast signal to the microcomputer 3, data relating to the weather in the data broadcast signal is extracted and stored in the memory 4.

  The color temperature detection means 6 detects the color temperature around the display means 7 and inputs the detected signal to the memory 4 via the microcomputer 3. The configuration of the color temperature detecting means 6 is as shown in the first embodiment. The built-in calendar 5 has information such as time and date and outputs it to the microcomputer 3. The memory 4 is a color temperature correction value table that defines the relationship between the color temperature detected by the color temperature detection means 6, the time and the color temperature correction value as shown in FIG. Is stored. The relationship between the time indicated by the broken line in FIG. 7 and the color temperature correction value is based on a sunny day, and the dotted line is based on a cloudy day.

  The microcomputer 3 selects a color temperature correction value table determined from the time and date information input from the built-in calendar 5 based on the weather-related data stored in the memory 4, and the color temperature detection means 6 An environmental color temperature is calculated by calculating the detected color temperature.

  For example, if the weather-related data stored in the memory 4 is cloudy, the color temperature correction value table shown in FIG. 7 is selected as the cloudy mode table and calculated with the color temperature detected by the color temperature detection means 6. Environment color temperature.

  Data relating to the weather stored in the memory 4 is referred to by the microcomputer 3 at regular intervals, and is used as a reference for selecting the color temperature correction value table. To be referred to every certain time means to be referred to every other hour, for example. In the present embodiment, the color temperature correction value table is selected based on the weather-related data in the data broadcast signal. However, the present invention is not limited to this. It is good also as a structure which acquires data. Since it is the same as that of the first embodiment, it is omitted here.

  With the above configuration, in addition to the effects shown in the first embodiment, a more accurate color temperature correction value can be reproduced by making it possible for the user to select a color temperature correction value corresponding to the difference in weather. A video display device can be provided.

  Next, a third embodiment of the present invention will be described with reference to FIGS. 4, 5, 8, 9, and 12. FIG. In FIG. 12, the signal processing means 1 inputs the video signal to the color temperature setting means 2. The color temperature detection means 6 detects the color temperature around the display means 7 and inputs the detected signal to the memory 4 via the microcomputer 3. The built-in calendar 5 has information such as time and date and outputs it to the microcomputer 3. The memory 4 stores a color temperature correction value table that defines the relationship between the color temperature detected by the color temperature detection means 6, the time and the color temperature correction value as shown in FIG. The remote control device can select a color temperature correction value table that defines the relationship between the time of the memory 4 and the color temperature correction value as shown in FIG. 9 by the user.

  The microcomputer 3 calculates the color temperature detected by the color temperature detection means 6 and the color temperature correction value of the table selected by the input from the remote control device to obtain the environmental color temperature. The environmental color temperature is calculated in the order shown in FIG. 5, and the image is displayed by the microcomputer 3 on the basis of the table showing the relationship between the environmental color temperature and the video color temperature stored in advance in the memory 4 as shown in FIG. The color temperature is set and output to the color temperature setting means 2 as a color temperature adjustment signal. The color temperature setting unit 2 sets the input color temperature adjustment signal and the video signal input from the signal processing unit 1 as the color temperature of the video to be displayed on the display unit 7. The display means 7 displays an image according to the input from the color temperature setting means 2.

  Next, the operation of the third embodiment will be described. The operation of this embodiment follows the procedure shown in FIG. That is, when the user does not make a determination on the read value (A) at the color temperature detection means 6, the color temperature correction value (B) is calculated by adding the color temperature correction value for the current time. The environmental color temperature (D) is determined, and the value is stored in the memory 4. When the determination is made by the user, the color temperature correction value (C) is calculated by adding the color temperature correction value for the current time selected by the user, the environmental color temperature (E) is determined, and the value is stored in the memory 4. To store.

  The color temperature around the display means 7 detected by the color temperature detection means 6 is input to the memory 4 via the microcomputer 3. The configuration of the color temperature detecting means 6 is as shown in the first embodiment. The built-in calendar 5 inputs time information to the microcomputer 3.

  Also, an instruction to select a color temperature correction value table as shown by a broken line in FIG. 9 stored in the memory 4 is given by the user's input to the microcomputer 3 at the remote control device. The relationship between the time indicated by the broken line in FIG. 9 and the color temperature correction value is the entire color temperature correction value in the table defining the relationship between the time and color temperature correction value shown in FIG. 3 in the first embodiment. About 10%.

  The relationship indicated by the broken line is a table of color temperature correction values that can be selected by the user using the remote control device in this embodiment, and is stored in the memory 4 in advance. In this embodiment, compared with the relationship indicated by the broken line, the overall increase is about 10%. In addition to this, for example, the relationship between the time reduced by 20% and the color temperature correction value is stored in the memory. , May be selectable by the user.

  As described above, by making it possible to select the color temperature correction value, the correction value of the color temperature according to the time can be emphasized, and it is effective for a user who hardly feels that the video changes with the time under normal settings. The microcomputer 3 performs an operation of adding the color temperature detected by the color temperature detecting means 6 and the color temperature correction value of the table selected by the remote control device to obtain the environmental color temperature. Since it is the same as that of the first embodiment, it is omitted here.

  Although not shown in the figure, since the sunlight hours and illuminance of sunlight differ depending on the season, such as the season and the rainy season, there is a color temperature correction value table that defines the relationship between the time and the color temperature correction value according to those periods. It is good also as a structure which is stored in memory and a user can select. Alternatively, a color temperature correction value table that defines the relationship between the time corresponding to the weather such as rain or cloudy and the color temperature correction value is stored in the memory, and may be configured so that the user can select it.

  With the above configuration, in addition to the effects shown in the first embodiment, the user can select a color temperature correction value corresponding to the time so that the video can be displayed in consideration of the user's preference. A device can be provided.

  Next, a fourth embodiment of the present invention will be described with reference to FIGS. 3 to 5, FIG. 10, and FIG. This embodiment is applied to a display device using an LED (light emitting diode) backlight as shown in FIG.

  In the fourth embodiment, in FIG. 10, the antenna 11 receives a broadcast signal and outputs it to the tuner 10. The tuner 10 selects the received broadcast signal and outputs the video signal to the signal processing means 1. The signal processing unit 1 outputs the video signal to the display control unit 9 after the video processing is performed. The color temperature detection means 6 is, for example, an RGB sensor, detects the color temperature around the display means 7, and outputs the detected signal to the memory 4 via the microcomputer 3.

  The built-in calendar 5 has information such as time and date and outputs it to the microcomputer 3. The memory 4 stores a color temperature detected by the color temperature detecting means 6 and a color temperature correction value table defining the relationship between the time and the color temperature correction value as shown in FIG. The microcomputer 3 calculates a color temperature correction value determined from the color temperature detected by the color temperature detection means 6, the time and date information input from the built-in calendar 5, and obtains the environmental color temperature.

  Similarly to the above, the environmental color temperature is calculated in the order shown in FIG. 5, and based on a table showing the relationship between the environmental color temperature and the video color temperature stored in advance in the memory 4 as shown in FIG. The video color temperature is set by the microcomputer 3 and is output to the LED control means 8 as a backlight luminance adjustment signal.

  The LED control means 8 adjusts the brightness of the backlight based on the input backlight brightness adjustment signal and outputs it to the LED backlight 12 as an LED drive signal for changing the color temperature. The LED backlight 12 is configured as shown in FIG. In FIG. 11, an LED backlight 12 includes a diffuser plate 32 in a housing 30 attached to the back surface of the liquid crystal panel 20, a plurality of LED light sources composed of three primary colors of red, green, and blue, that is, a red LED light source 41 and a green LED. A light source 42 and a blue LED light source 43 are arranged.

  Although not shown, the LED backlight 12 uses, as a dimming signal, a pulse width modulation output in which the signal period ratio between the high potential level and the low potential level of the rectangular wave changes according to the LED drive signal input from the LED control means 8. It includes a dimming control circuit that outputs, and an inverter that drives the lighting by receiving a dimming signal from the dimming control and generating an alternating voltage with a period and voltage corresponding to the dimming signal. The display control unit 9 outputs a liquid crystal drive signal to the display unit 7 based on the video signal input from the signal processing unit 1. The display means 7 displays an image that has been changed to a predetermined color temperature in response to inputs from the LED control means 8 and the display control means 9.

  Next, the operation of the fourth embodiment will be described. The antenna 11 receives a broadcast signal and outputs it to the tuner 10. The tuner 10 selects the received broadcast signal and outputs the video signal to the signal processing means 1. The color temperature around the display means 7 detected by the color temperature detection means 6 is input to the memory 4 via the microcomputer 3. The color temperature detecting means 6 is an RGB sensor, for example.

  The built-in calendar 5 outputs time information to the microcomputer 3. The microcomputer 3 determines a color temperature correction value corresponding to the time stored in advance in the memory 4 as shown in FIG. 3, and detects the color temperature correction value detected by the color temperature detection means 6 and adds the color temperature correction value to the input color temperature. To calculate the environmental color temperature.

  Further, the image color temperature is set based on a table showing the relationship between the environmental color temperature and the image color temperature as shown in FIG. 8 is output. The LED control means 8 adjusts the brightness of the backlight using the input backlight brightness adjustment signal and outputs a signal for causing the LED elements of each color to emit light to the LED backlight 12 as an LED drive signal.

  The LED backlight 12 performs lighting driving according to the input LED driving signal. The display control means 9 outputs a liquid crystal drive signal to a gate driver and a source driver (not shown) of the display means 7 based on the video signal input from the signal processing means 1, and displays an image according to the video signal on the display means 7. . The display means 7 displays an image having a predetermined color temperature in response to inputs from the display control means 9 and the LED control means 8.

  With the above configuration, the color temperature detection means detects the color temperature around the display means 7, and further corrects by adding the correction value of the color temperature according to the time, so that the lighting environment of the user and the circadian rhythm of the person can be reduced. It is possible to provide a video display device capable of displaying a video in consideration.

  According to the present invention, the display conditions of the display device can be automatically set according to the user environment such as the indoor lighting environment around the viewing user, and is particularly useful for a television receiver or a personal computer.

DESCRIPTION OF SYMBOLS 1 Signal processing means 2 Color temperature setting means 3 Microcomputer 4 Memory 5 Built-in calendar 6 Color temperature detection means 7 Display means 8 LED control means 9 Display control means 10 Tuner 11 Antenna 12 LED backlight 20 Liquid crystal panel 30 Case 32 Diffusion plate 41 Red LED light source 42 Green LED light source 43 Blue LED light source

Claims (12)

An image display device comprising color temperature detection means for detecting the color temperature around the display means in order to correct the color temperature of the image displayed on the display means,
An image display device comprising color temperature correction means for correcting the color temperature detected by the color temperature detection means according to time. An image display device comprising color temperature detection means for detecting a color temperature around the display means in order to correct the color temperature of the backlight that irradiates the display means with light from the back,
An image display device comprising color temperature correction means for correcting the color temperature detected by the color temperature detection means according to time.   The video display device according to claim 1, wherein a correction value of correction according to time by the color temperature correction unit is changed based on external information related to weather.   4. The video display device according to claim 3, wherein the external information related to the weather is at least data related to the weather acquired by a data broadcast signal or data related to the weather acquired via the Internet.   The video display device according to claim 1 or 2, wherein a correction value of correction according to time by the color temperature correction means is changed based on at least one of weather and time of the year.     The video display apparatus according to claim 1, wherein a correction value of correction according to time by the color temperature correction unit is changed based on user preference. An image display method comprising a step of detecting a color temperature around the display means in order to correct a color temperature of the image displayed on the display means,
An image display method comprising a step of correcting the detected color temperature according to time. An image display method comprising a step of detecting a color temperature around the display means in order to correct a color temperature of a backlight that irradiates light from the back to the display means,
An image display method comprising a step of correcting the detected color temperature according to time.   9. The video display method according to claim 7, wherein the correction value of the step of correcting according to the time is changed based on external information related to the weather.   10. The video display method according to claim 9, wherein the external information related to the weather is at least data related to the weather acquired from a data broadcast signal or data related to the weather acquired via the Internet.   9. The video display method according to claim 7, wherein the correction value of the step of correcting in accordance with the time is changed based on at least one of weather and season. The video display method according to claim 7 or 8, wherein the correction value of the step of correcting according to the time is changed based on the user's preference.