JP2008066830A - Image display system, television receiver, and image display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable a viewer to easily make a suitable color correction matching a color to be viewed. <P>SOLUTION: A remote controller 30 attached to a television receiver 10 is provided with an image sensor 33 which picks up a calibration image. Then when a broadcasting channel is switched by the remote controller 30, or when the power source is turned on, the calibration image is displayed on a receiver main body 20 and the image sensor 33 of the remote controller 30 picks up the calibration image. A calibration is made based upon the imaging result. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an image display system including a remote control device and a television receiver.

  In recent years, the quality of home television has been improved. On the other hand, television receivers are easily affected by ambient light, temperature, aging, etc., and image quality adjustment is difficult. To adjust the image quality of a TV, an optical sensor is attached to the center of the TV screen, the colorimetric data obtained by the optical sensor is compared with the reference color, and color correction is performed based on the color difference. There are calibration techniques to perform.

  Furthermore, as shown in Patent Document 1, a configuration has been proposed in which an optical sensor is provided in the vicinity of a backlight disposed on the back side of a liquid crystal panel, and calibration is performed using a signal detected by the optical sensor. Yes.

JP 2006-91235 A

  However, in the prior art, the colorimetric data is only obtained on the light emitting side, and there is a deviation from the color received by the viewer. This is because a color change occurs due to various factors including ambient light and the like before reaching the viewer's eyes from the light emitting surface. For this reason, there has been a problem that it is impossible to perform optimum color correction that matches the color viewed by the viewer.

  In the former technique of attaching the optical sensor to the center of the screen, it is necessary to repeatedly perform local measurement, and there is a problem in that it is inconvenient for the operator.

  The problem to be solved by the present invention is to make it possible to easily perform optimum color correction suitable for the color viewed by the viewer.

  As means for solving at least a part of the problems described above, the following configuration is adopted.

The image display system of the present invention includes:
An image display device for displaying an input image; and
An image display system comprising: a remote control device for remotely operating the image display device main body;
A calibration image display means provided in the image display device body for displaying a calibration image;
An image pickup means provided in the remote control device for picking up a calibration image displayed on the image display device main body;
Based on imaging information from the imaging means, imaging color calculation means for obtaining an imaging color for a calibration image displayed on the image display device main body,
Color conversion data generating means for generating color conversion data for converting the captured color into a reference color;
The gist of the invention is that the image display apparatus includes a color correction unit that is provided in the image display device body and corrects the color of the input image based on the color conversion data.

  The remote control device is always used toward the display surface of the image display device main body during operation, and the position where the remote control device is used substantially coincides with the position where the operator views the input image. According to the image display system having the above-described configuration, since the imaging unit that captures the calibration image is provided in the remote control device, the color received by the operator of the remote control device can be obtained by the imaging unit and the imaging color calculation unit. For this reason, it is possible to generate color conversion data for converting the color seen by the operator into the reference color by the color conversion data generation means. Therefore, it is possible to perform optimal color correction that matches the color seen by the operator. In addition, the operator can easily perform color correction because no special work for calibration is required.

  In the image display system, the image display system further includes a determination unit that determines whether an input to the remote controller by the operator is a predetermined operation command that is determined in advance, and the calibration image display unit is configured to perform the predetermined operation by the determination unit. The calibration image is displayed when it is determined that the operation command is determined, and the imaging unit is configured to capture the calibration image when the determination unit determines that the predetermined operation command is determined. Also good.

  According to this configuration, calibration is performed when the remote control device is operated. Since the position when the operation of the remote control device is substantially the same as the position where the operator views the input image, the optimum color correction suitable for the color viewed by the operator can be more reliably performed.

  The image display device main body may be a television receiver main body, and the predetermined operation command may be a broadcast channel switching command.

  According to this configuration, calibration can be performed in a daily operation of switching broadcast channels. In addition, since the calibration image is displayed for a moment when the broadcast channel is switched, the operator is unlikely to feel visually uncomfortable even when looking at the display surface.

The predetermined operation command may be a command to turn on the power source of the image display apparatus main body.

  According to this configuration, calibration can be performed when the power source of the image display apparatus main body is turned on by the remote control device.

The television receiver of the present invention is
A receiver that receives television broadcasts;
A television receiver comprising: a remote control device for remotely operating the receiver body;
The receiver body is
A calibration image display means for displaying a calibration image when a predetermined operation command is input in advance from the remote control device body;
The remote controller is
Imaging means for capturing a calibration image displayed on the receiver body;
Based on imaging information from the imaging means, imaging color calculation means for obtaining an imaging color for a calibration image displayed on the receiver body;
Imaging color information indicating the obtained imaging color is converted into a transmission signal exchanged with the receiver main body and transmitted to the receiver main body, and is provided with imaging color information transmitting means.
further,
The receiver body is
Imaging color information receiving means for receiving the signal transmitted by the imaging color information transmitting means and obtaining the imaging color information;
Color conversion data generating means for generating color conversion data for converting the captured color indicated by the captured color information into a reference color;
And a color correction unit that performs color correction on the television broadcast video based on the color conversion data.

  The remote control device is always used toward the display surface of the receiver main body during operation, and the position where the remote control device is used substantially coincides with the position where the viewer views the television image. According to the television receiver having the above-described configuration, since the imaging unit that captures the calibration image is provided in the remote control device, the color received by the viewer operating the remote control device can be obtained by the imaging unit and the imaging color calculation unit. . For this reason, it is possible to generate color conversion data for converting the color seen by the viewer into the reference color by the color conversion data generation means. Therefore, it is possible to perform optimal color correction that matches the color viewed by the viewer. In addition, the viewer can easily perform color correction since no special work for calibration is required.

  The remote control device may include a unit that compresses image color information indicating the image color obtained by the image color calculation unit and uses the compressed video color information for the conversion.

  According to this configuration, since the amount of data communicated from the remote control device to the receiver body can be reduced, the remote control device can also be used for communication using a method with a relatively narrow transmission band such as infrared rays. Easy to do.

The image display method of the present invention includes:
An image display method for remotely operating an image display device body using a remote control device and displaying an image on the image display device body,
Determining whether an input by an operator to the remote control device is a predetermined operation command determined in advance;
When it is determined that it is the predetermined operation command, a command signal indicating that it is time to execute calibration is transmitted to the image display device body,
In the image display device main body, a calibration image is displayed,
The imaging means provided in the remote control device captures a calibration image displayed on the image display device body,
Based on the imaging information from the imaging means, obtain the imaging color for the calibration image displayed on the image display device body,
Generating color conversion data for converting the captured color into a reference color;
The gist of the image display device main body is to perform color correction of the input image based on the color conversion data.

  The image display method of the present invention has an effect that it is possible to easily perform optimum color correction suitable for the color viewed by the viewer, as in the image display system of the present invention.

Hereinafter, embodiments of the present invention will be described based on examples.
A. Entire system:
B. Function of each part C. Process flow:
D. Action / Effect:
E. Other embodiments:

A. Entire system:
FIG. 1 is a schematic configuration diagram of a television receiver 10 constituting an image display system according to an embodiment of the present invention. The television receiver 10 is for home use, and includes a receiver body 20 that receives a television broadcast, and a remote control device 30 that remotely operates the receiver body 20. The remote controller 30 is used by an operator with its front surface 30a facing the television receiver 10, and various button switches are provided on the operation panel 31, and these button switches are used when the receiver main body 20 is operated remotely. Pressed. As various button switches, a power button for instructing power on / off, a channel switching button for designating a broadcast channel, and the like are provided.

  FIG. 2 is a front view of the remote control device 30. As shown in the figure, an infrared transmitter 32 is provided on the front surface 30 a of the remote control device 30. The remote control device 30 emits information indicating an operation command by infrared rays transmitted from the infrared transmission unit 32. The infrared rays transmitted from the infrared transmission unit 32 travel straight as indicated by the broken line in FIG. 1 and are received by the infrared reception unit 21 of the receiver body 20.

  Further, as a specific configuration of the present embodiment, as shown in FIG. 2, a light receiving portion 33 a of an image sensor 33 (FIG. 3) is provided on the front surface 30 a of the remote control device 30. The image sensor 33 corresponds to the image pickup means in the present invention. The image sensor 33 is configured by an image sensor such as a CCD or a CMOS, for example, and the display surface of the display unit 22 of the receiver body 20 when the remote control device 30 is used at a normal distance from the receiver body 20. Is designed to be the shooting range. The imaging result of the image sensor 33 is output as R (red), G (green), and B (blue) signals.

B. Functions of Each Part FIG. 3 is a block diagram showing functions realized in the receiver body 20 and the remote control device 30. As shown in the figure, the remote control device 30 includes an operation command generation unit 34, a calibration timing determination unit 35, a display area detection unit 38, and a chromaticity calculation unit in addition to the operation panel 31, infrared transmission unit 32, and image sensor 33 described above. 36 and a compression unit 37. The functions of these units 34 to 37 are executed when a CPU (not shown) built in remote controller 30 exchanges data with a memory (not shown) built in remote controller 30. This is realized by various processes.

  When various button switches provided on the operation panel 31 are pressed by the operator, the operation command generation unit 34 generates an operation command signal S1 indicating an operation command corresponding to the pressed button switch, and an infrared transmission unit The operation command signal S 1 is sent to 32. The infrared transmitter 32 transmits the infrared light modulated based on the operation command signal S <b> 1 to the receiver body 20.

  The calibration timing determination unit 35 determines whether or not the operation command signal S1 generated by the operation command generation unit 34 is for a predetermined operation command that is determined in advance, and for the predetermined operation command. When it is determined, the operation command generation unit 34 is caused to generate a command signal (hereinafter referred to as “calibration timing command signal”) S2 indicating that the timing for executing calibration has been reached. The predetermined operation command is, for example, an operation command to turn on the power by pressing the power button of the receiver body 20, or an operation command to switch the broadcast channel by pressing the broadcast channel switching button. When any one of these operation commands is input, a calibration timing command signal S2 is output from the operation command generation unit 34, and the infrared transmission unit 32 receives the infrared light modulated based on the calibration timing command signal S2. It transmits to the main body 20.

  On the other hand, the receiver body 20 includes a receiving unit 23, a video processing unit 24, a calibration image data output unit 25, a reference chromaticity storage unit 26, and a color difference calculation unit 27 in addition to the infrared receiving unit 21 and the display unit 22 described above. Prepare. Note that each function of the video processing unit 24, the calibration image data output unit 25, and the color difference calculation unit 27 is a memory (not shown) that is built in the receiver body 20 and is also a memory ( This is realized by various processes executed by exchanging data with an unillustrated). The reference chromaticity storage unit 26 is a memory. The receiving unit 23 is a discrete electronic circuit.

  The video signal received by the antenna 40 is received by the receiving unit 23 and transmitted to the video processing unit 24. The video processing unit 24 displays video based on the video signal on the display unit 22. Various operation command signals S1 indicated by infrared rays received by the infrared reception unit 21 are sent to the reception unit 23 and the video processing unit 24, and channel switching or the like is performed according to the operation command signal S1. Various processes are executed.

  Further, the infrared ray reception unit 21 of the receiver body 20 receives infrared rays indicating the calibration timing command signal S <b> 2 transmitted from the remote control device 30. The calibration timing command signal S2 represented by the infrared rays received by the infrared receiving unit 21 is sent to the calibration image data output unit 25, and the calibration image data output unit 25 sends the calibration image data to the video processing unit 24. Output. As a result, a calibration image is displayed on the display unit 22. Each unit required to display the calibration image corresponds to the calibration image display means in the present invention.

  In this embodiment, four types of tone correction calibration images of the highest gradations of R (red), G (green), B (blue), and W (white) are sequentially displayed as calibration images one by one. Calibration to correct the hue. In this embodiment, as the calibration image, two types of gradation correction calibration images of the first gradation and the second gradation in the low gradation region of W (white) are sequentially displayed one by one. Thus, calibration for correcting gradation is performed. In this way, by using the highest gradation color for hue correction, the reproducible color gamut can be maximized. Further, by using a low gradation color for gradation correction, it is easy to grasp a change in brightness due to a change in ambient light. This is because the low gradation region is more susceptible to environmental light than the high gradation region. The chromaticity stored in the reference chromaticity storage unit 26 corresponds to the calibration image. Each display of the calibration image and reading of the reference chromaticity from the reference chromaticity storage unit 26 are performed. Are configured to synchronize.

  The image sensor 33 provided in the remote control device 30 captures the calibration image displayed on the display unit 22. A display area detection unit 38 provided in the remote control device 30 detects a portion corresponding to the display surface of the display unit 22 of the receiver body 20 from the imaging information (R, G, B values) obtained by the image sensor 33. The chromaticity calculation unit 36 performs processing for obtaining the chromaticity of the detected portion. The R, G, and B values are device-dependent color signals, but the chromaticity calculation unit 36 converts the device-dependent color signals into device-independent color signals (tristimulus values XYZ) to obtain XYZ values. Is chromaticity. Note that the above conversion is a well-known one that is calculated by a predetermined linear conversion in consideration of the color characteristics of the image sensor 33, and the description thereof is omitted here. The chromaticity calculation unit 36 corresponds to the imaging color calculation means in the present invention.

  Thereafter, the compression unit 37 compresses the chromaticity information indicated by the XYZ values, and the compressed chromaticity information S3 is sent to the infrared transmission unit 32. The infrared transmitter 32 transmits infrared light modulated based on the chromaticity information S3. In other words, the chromaticity information S3 is converted into a transmission signal exchanged with the receiver body 20, in this case infrared, and transmitted.

The receiver body 20 that has received the chromaticity information S3 by the infrared receiver 21 sends the chromaticity information S3 to the color difference calculator 27. The chrominance calculation unit 27 is based on the reference chromaticity stored in advance in the reference chromaticity storage unit 26 and the chromaticity represented by the chromaticity information S3 sent from the infrared receiving unit 21, and the color difference ΔEa ^* b ^*. Is calculated. Specifically, first, the chromaticity (X, Y, Z) is converted into the CIELAB color space by a predetermined known method to obtain values (L ^* ₁ , a ^* ₁ , b ^* ₁ ), and the reference color A value (L ^* ₂ , a ^* ₂ , b ^* ₂ ) on the CIELAB color space indicating the reference chromaticity stored in advance in the degree storage unit 26 and the above values (L ^* ₁ , a ^* ₁ , b ^* ₁ ) Is used to obtain the color difference ΔEa ^* b ^* by the following equation (1).

^{ΔEa * b * = [(L} * 2 -L * 1) 2 + (a * 2 -a * 1) 2 + (b * 2 -b * 1) 2] 1/2 ... (1)

The color difference ΔEa ^* b ^* obtained by the color difference calculation unit 27 is sent to the color correction unit 24a included in the video processing unit 24. The color correction unit 24a is preliminarily provided with a color conversion table CTL as “color conversion data” of the present invention. The color correction unit 24a updates the color conversion table CTL based on the color difference ΔEa ^* b ^* . The color correction unit 24a performs color correction based on the color conversion table CTL for the video signal received by the reception unit 23. Since the color conversion table CTL is based on the color difference ΔEa ^* b ^* , the color of the image displayed on the display unit 22 is calculated by calculating the color difference ΔEa ^* b ^* by performing color correction based on the color conversion table CTL. The reference chromaticity can be adjusted to the base color. The function of updating the color conversion table CTL by the color correction unit 24a and the color difference calculation unit 27 constitute color conversion data generation means in the present invention. The color correction unit 24a corresponds to the color correction unit 24a in the present invention.

C. Process flow:
Next, the flow of processing executed by the receiver body and the remote control device 30 respectively in the calibration mode for performing calibration will be described. The processing on the receiver body 20 side is executed by the CPU built in the receiver body 20 in accordance with a computer program stored in the memory similarly built in the receiver body 20, and is on the remote control device 30 side. This process is executed by a CPU built in the remote control device 30 in accordance with a computer program stored in a memory built in the remote control device 30. Each computer program can be provided as a configuration stored in another portable recording medium (portable recording medium) such as a CD-ROM, flexible disk, magneto-optical disk, or IC card. . The computer program can also be provided via a network from a specific server connected to an external network.

  FIG. 4 is a flowchart showing processing in the calibration mode executed by the remote control device 30. This calibration process is repeatedly executed by the CPU every predetermined time. When the process is started, the CPU first determines whether or not there is an operation command input from the remote control device 30 (step S100). If it is determined that there is no input, the process returns to “RETURN” and the execution of this processing routine is temporarily terminated. On the other hand, if it is determined that there is an input, it is determined whether or not the input operation command is to turn on the power by pressing the power button (step S110). It is determined whether or not the operation command is to switch the broadcast channel by pressing the broadcast channel switching button (step S120).

  If the determination in both step S110 and step S120 is negative, that is, if it is determined that the input is neither a power-on operation nor a channel switching operation, the CPU exits to “RETURN” and temporarily ends the execution of this processing routine. .

  On the other hand, when an affirmative determination is made in either step S110 or step S120, that is, when the input is determined to be a power-on operation or a channel switching operation, the process proceeds to step S130, and the calibration timing command signal S2 is set. A transmission process is performed (step S130). Specifically, processing is performed to realize the functions of the calibration timing determination unit 35, the operation command generation unit 34, and the infrared transmission unit 32 described above. As a result of this processing, infrared light that has been modulated based on the calibration timing command signal S2 is transmitted from the infrared transmitter 32.

  FIG. 5 is a flowchart showing processing in the calibration mode executed by the receiver body 20. This process is repeatedly executed at predetermined time intervals by the CPU of the receiver body 20. When the process is started, the CPU first determines whether or not the calibration timing command signal S2 has been received from the remote control device 30 (step S200). The process in the calibration mode is temporarily terminated.

  On the other hand, when it is determined in step S200 that the calibration timing command signal S2 has been received, the CPU displays the first calibration image, that is, the R hue correction calibration image on the display unit 22 (step S210). Specifically, processing is performed to realize the functions of the calibration image data output unit 25 and the video processing unit 24 described above.

  Returning to FIG. 4, on the remote control device 30 side, the CPU uses the image sensor 33 to capture the R hue correction calibration image displayed on the display unit 22 of the receiver body 20, and Processing for storing the obtained imaging information is performed (step S140). Thereafter, the CPU performs processing for obtaining the chromaticity of the portion corresponding to the display surface of the display unit 22 of the receiver body 20 from the imaging information stored in step S140. Specifically, processing is performed so as to realize the function of the chromaticity calculation unit 36 described above. Subsequently, the CPU performs a process of converting the chromaticity information S3 obtained from the chromaticity obtained in step S150 into a transmission signal (infrared ray) exchanged with the receiver body 20 and transmitting it (step S160). . Specifically, processing is performed to realize the functions of the compression unit 37 and the infrared transmission unit 32 described above.

  After executing step S160, the CPU proceeds with the process to step S170 to determine whether or not chromaticity information S3 has been acquired for all calibration images, and has determined that all have not yet been acquired. In that case, the processing is returned to step S140, and the processing of steps S140 to S170 regarding the next calibration image is repeatedly executed. On the other hand, if it is determined in step S170 that all the information has been acquired, the process returns to “RETURN” and the process in the calibration mode is temporarily terminated. That is, since the calibration image has six colors for hue correction and gradation correction as described above, the processes in steps S140 to S170 are performed six times.

  Moving to FIG. 5, the CPU on the receiver body 20 side receives the infrared rays sent from the remote control device 30 after executing step S210 (step S220), and the information represented by the infrared rays is the chromaticity information S3. Is determined (step S230). If it is determined that the chromaticity information is not S3, the process of step S220 is repeated to wait for the chromaticity information S3 to be sent.

  On the other hand, if it is determined in step S230 that the information is chromaticity information, the CPU proceeds to step S240 to perform a process of calculating a color difference. Specifically, processing is performed to realize the functions of the reference chromaticity storage unit 26 and the color difference calculation unit 27 described above. Thereafter, the CPU determines whether or not the chromaticity has been acquired for all the calibration images (step S250). If it is determined that all the chromaticities have not yet been acquired, the process returns to step S210. Thus, the processes of steps S210 to S250 relating to the next calibration image are repeatedly executed. On the other hand, if it is determined in step S250 that all information has been acquired, the CPU advances the process to step S260. Since there are a total of six calibration images for hue correction and gradation correction as described above, the processes in steps S220 to S250 are performed six times.

  In step S260, the CPU performs a process of updating the color conversion table CTL based on the six color difference information acquired in step S240. Specifically, processing is performed to realize the function of the color correction unit 24a described above. After execution of step S260, the process returns to “RETURN” to end the processing routine.

  The processing routines in the calibration mode shown in FIG. 4 and FIG. 5 are described as sequential processing for convenience of explanation. However, in practice, each processing step is parallelized as necessary by pipeline processing. Processing is in progress.

  Although not included in each processing routine in the calibration mode shown in FIG. 4 and FIG. 5, it is input by the remote control device 30 including a power-on operation command and a channel switching operation command by another routine. All the operation commands are sent from the remote control device 30 to the receiver main body 20, and the receiver main body 20 is subjected to an operation process corresponding to the operation commands. That is, if the operation command is to turn on the power of the receiver body 20, the process of turning on the power of the receiver body 20 is performed. If the operation command is to switch the channel, the process of switching the reception channel of the receiver body 20 is If it is an operation command, processing corresponding to the operation command is executed.

D. Action / Effect:
The remote control device 30 is always used toward the display surface of the receiver body 20 during operation, and the position where the remote control device 30 is used substantially coincides with the position where the viewer views the television image. According to the television receiver 10 having the above-described configuration, the image sensor 33 that captures the calibration image is provided in the remote control device 30. Therefore, the color received by the viewer who operates the remote control device 30 is determined by the image sensor 33 and the chromaticity calculation unit. 36. For this reason, it is possible to generate a color conversion table CTL for converting the chromaticity viewed by the viewer into the reference chromaticity. Therefore, it is possible to perform optimal color correction that matches the color viewed by the viewer. In addition, the viewer can easily perform color correction since no special work for calibration is required.

  In this embodiment, when the remote control device 30 is operated and the broadcast channel is switched, a calibration timing command signal S2 is sent from the remote control device 30 to the receiver body 20 to perform calibration. is doing. For this reason, since the calibration image is displayed on the receiver main body 20 at the moment when the broadcast channel is switched, the viewer visually feels uncomfortable even when looking at the display surface of the receiver main body 20. There is little to feel. Therefore, calibration can be performed without making the viewer feel uncomfortable during the daily operation of switching broadcast channels.

  In the present embodiment, calibration can also be performed when the power of the receiver body 20 is turned on by the remote control device 30.

  Furthermore, in this embodiment, the chromaticity obtained by the chromaticity calculation unit 36 is compressed by the compression unit 37 and sent to the infrared transmission unit 32. For this reason, since the amount of data communicated from the remote control device 30 to the receiver body 20 can be reduced, it is possible to sufficiently cope with communication using a relatively narrow transmission band such as infrared rays.

E. Other embodiments:
The present invention is not limited to the above-described embodiments and modifications, and can be implemented in various modes without departing from the scope of the invention.

(1) In the above-described embodiment, the calibration image uses four hue conversion calibration images and two tone correction calibration images. However, the calibration images need not be limited to these, Any calibration image that defines a color may be used. For example, a standard chart representing various colors may be used. Alternatively, the calibration image may be configured to perform only color temperature correction assuming only white.

(2) In the configuration of the above embodiment, a camera shake correction unit may be added to the remote control device 30. As the camera shake correction means, the image obtained by the image sensor 33 is subjected to image processing to correct the camera shake, or the direction and amount of the shake are detected by the gyro sensor, and the image is optically corrected to cancel the shake. Any configuration such as a configuration for displacing the system may be used. With this configuration, measurement abnormality due to camera shake of the remote control device 30 can be prevented.

(3) In the above-described embodiment, the calibration is performed when the remote control device 30 is operated and the broadcast channel is switched or the power is turned on. Instead, the input video is displayed. A configuration may be adopted in which calibration is performed when the input destination is switched, such as when switching between television broadcasting and the output of a video recorder. Furthermore, it is not necessary to be limited to when the broadcast channel is switched, when the power is turned on, and when the input destination is switched. Instead, the calibration may be performed when another operation is performed on the remote control device. Further, it is not necessary to be limited to when the remote control device is operated, and it may be configured to determine the timing for performing calibration on the receiver body 20 side.

(4) In the above embodiment, the timing for performing calibration is determined on the remote control device 30 side and notified to the receiver main body 20 in the form of a calibration timing command signal S2. The machine body 20 may be configured to determine whether or not the operation command sent from the remote control device 30 is a predetermined operation command. According to this configuration, communication of the calibration timing command signal S2 becomes unnecessary.

(5) In the above embodiment, the remote control device 30 side obtains the chromaticity, compresses the chromaticity and sends it to the receiver body 20, and the receiver body 20 side obtains the color difference. Thus, the configuration for obtaining the color difference may be shifted to the receiver body 20 side to communicate the color difference information. That is, a configuration may be adopted in which a reference color storage unit is provided on the remote control device 30 side to perform a certain amount of calculation, and the correction parameter is converted into infrared rays and transmitted to the receiver body 20 side. Furthermore, a configuration for obtaining the chromaticity may be provided on the receiver body 20 side, and the imaging result obtained by the image sensor 33 may be converted into infrared light as it is and transmitted to the receiver body 20 side.

(6) In the above-described embodiment, the transmission signal exchanged between the remote control device 30 and the receiver body 20 is infrared. However, instead of this, communication may be performed by wire, ultrasonic waves, radio waves, or the like. . For example, even when the remote control device is a wireless network, it can be handled. In this case, it is easy to transmit the imaging result obtained by the image sensor 33 shown in (5) as it is without being processed.

(7) In the above-described embodiments, RGB signal values are used. However, the present invention can also be applied to the case where CMY values or CMYK values are used. Further, as the image pickup means, a color light sensor that performs colorimetry may be used instead of the image sensor 33.

(8) The receiver body 20 of the above embodiment may be of any type, such as a liquid crystal television, a plasma television, a cathode ray tube television, or a PTV (projection television). Furthermore, it is not always necessary to be a television, and any other image display device that displays images may be used. The image here may be a still image as well as a video (moving image).

(9) In the above embodiment, the remote control device is attached to the television, but it is not always necessary to be a remote control device attached to the television. It may be configured as follows. For example, it may be a mobile phone equipped with a TV remote control function.

It is a schematic block diagram of the television receiver 10 which comprises the image display system of one Example of this invention. 3 is a front view of a remote control device 30. FIG. 3 is a block diagram illustrating functions implemented in the receiver body 20 and the remote control device 30. FIG. 4 is a flowchart showing processing in a calibration mode executed by a remote control device 30. 4 is a flowchart showing processing in a calibration mode executed by the receiver body 20.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Television receiver 20 ... Receiver main body 21 ... Infrared receiving part 22 ... Display part 23 ... Receiving part 24 ... Video processing part 24a ... Color correction part 25 ... Calibration image data output part 26 ... Reference chromaticity storage part 27 ... Color difference calculation unit 30 ... Remote control device 30a ... Front 31 ... Control panel 32 ... Infrared transmission unit 33 ... Image sensor 33a ... Light receiving unit 34 ... Operation command generation unit 35 ... Calibration timing determination unit 36 ... Chromaticity calculation unit 37 ... Compression unit 40 ... Antenna S1 ... Operation command signal S2 ... Calibration timing command signal S3 ... Chromaticity information CTL ... Color conversion table

Claims (10)

An image display device for displaying an input image; and
An image display system comprising: a remote control device for remotely operating the image display device main body;
A calibration image display means provided in the image display device body for displaying a calibration image;
An image pickup means provided in the remote control device for picking up a calibration image displayed on the image display device main body;
Based on imaging information from the imaging means, imaging color calculation means for obtaining an imaging color for a calibration image displayed on the image display device main body,
Color conversion data generating means for generating color conversion data for converting the captured color into a reference color;
An image display system comprising: a color correction unit that is provided in the image display device body and performs color correction of the input image based on the color conversion data. The image display system according to claim 1,
Determining means for determining whether or not an input to the remote control device by the operator is a predetermined operation command determined in advance;
The calibration image display means displays the calibration image when the determination means determines that the predetermined operation command is present,
The image pickup system picks up the calibration image when the image pickup unit determines that the predetermined operation command is determined by the determination unit. The image display system according to claim 2,
The image display device main body is a television receiver main body,
The image display system, wherein the predetermined operation command is a command for switching a broadcast channel. The image display system according to claim 2 or 3,
The predetermined operation command is a command to turn on a power source of the image display device main body. A receiver that receives television broadcasts;
A television receiver comprising: a remote control device for remotely operating the receiver body;
The receiver body is
A calibration image display means for displaying a calibration image when a predetermined operation command is input in advance from the remote control device body;
The remote controller is
Imaging means for capturing a calibration image displayed on the receiver body;
Based on imaging information from the imaging means, imaging color calculation means for obtaining an imaging color for a calibration image displayed on the receiver body;
Imaging color information indicating the obtained imaging color is converted into a transmission signal exchanged with the receiver main body and transmitted to the receiver main body, and is provided with imaging color information transmitting means.
further,
The receiver body is
Imaging color information receiving means for receiving the signal transmitted by the imaging color information transmitting means and obtaining the imaging color information;
Color conversion data generating means for generating color conversion data for converting the captured color indicated by the captured color information into a reference color;
A television receiver comprising: color correction means for performing color correction on the television broadcast video based on the color conversion data. The television receiver according to claim 5,
Before the remote control device
A television receiver comprising: means for compressing image color information indicating an image color obtained by the image color calculation means and converting the compressed video color information for the conversion. A television receiver according to claim 5 or 6,
The remote control device includes determination means for determining whether or not an input by an operator is a predetermined operation command determined in advance.
The calibration image display means displays the calibration image when the determination means determines that the predetermined operation command is present,
The television receiver that captures the calibration image when the determination unit determines that the predetermined operation command is received by the determination unit. A television receiver according to claim 7,
The predetermined operation command is a command to switch broadcast channels. A television receiver according to claim 7 or 8,
The predetermined operation command is a command to turn on the power source of the image display device main body. An image display method for remotely operating an image display device body using a remote control device and displaying an image on the image display device body,
Determining whether an input by an operator to the remote control device is a predetermined operation command determined in advance;
When it is determined that it is the predetermined operation command, a command signal indicating that it is time to execute calibration is transmitted to the image display device body,
In the image display device main body, a calibration image is displayed,
The imaging means provided in the remote control device captures a calibration image displayed on the image display device body,
Based on the imaging information from the imaging means, obtain the imaging color for the calibration image displayed on the image display device body,
Generating color conversion data for converting the captured color into a reference color;
The image display apparatus main body performs color correction of the input image based on the color conversion data.

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