JP2011242587A - Display unit and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To unify brightness and color balance among a plurality of displays easily without a user being aware of the unification.SOLUTION: In this display unit, when a style detection part detects a housing being closed, a processing part maximizes backlight output luminance by maximizing an LED current of each backlight, measures the maximum luminance of red, green and blue in each of the liquid crystal displays 1, 2 by color photosensors 6, 7 and corrects the maximum luminance of the liquid crystal displays 1, 2 by reducing the LED current so that target luminance is achieved. The processing part measures brightness of an image for adjustment, in which red, green and blue is changed by the processing part from the maximum to an intermediate value to the minimum, by the color photosensors 6, 7 and creates a gamma correction table so that a target gamma curve is achieved.

Description

  The present invention relates to a foldable display device including a plurality of displays, and a program.

  2. Description of the Related Art Conventionally, in a display device including a display, the brightness and color balance of the display are deteriorated due to secular change. Therefore, a technique for measuring and correcting the brightness and color balance of the display is known.

  For example, in a foldable display device equipped with a display and a keyboard, when the power switch is turned on with the display panel on the display side closed, the transmission amount of the display is measured by a luminance sensor arranged on the keyboard side, A technique for automatically adjusting the display so that the contrast of the display is maximized is known (see, for example, Patent Document 1).

  Also, in a foldable display device, a technique for displaying a test pattern, photographing it with a camera, measuring the chromaticity and luminance, and correcting the display including the backlight based on the measured value Is known (see, for example, Patent Document 2).

  By the way, in recent years, a foldable multi-display device having a plurality of displays has been known in order to display a large amount of information without impairing portability (see, for example, Patent Document 3). The multi-display device includes a first display device and a second display device that are rotatably mounted by an angle adjustment mechanism, and can display independent images on each of them.

Japanese Patent Application Laid-Open No. 07-333581 JP 2001-350428 A JP 2005-037747 A

  In the foldable multi-display device having a plurality of displays described above, especially when the frequency of use is different among the plurality of displays, the luminance and color balance of the display may differ among the displays due to secular changes, and different characteristics. When using this display, or when replacing the display, there is a problem that the brightness and color balance of the display differ between the displays. As described above, when the luminance and color balance are different between the displays, there is a problem that the user is uncomfortable.

  However, in the prior arts disclosed in Patent Documents 1 and 2 described above, correction of the contrast, chromaticity, and luminance of a single display is considered, but luminance and color balance are adjusted among a plurality of displays. There was no.

  In particular, in the prior art according to Patent Document 2, it is necessary to display a test pattern on a display device, measure the chromaticity and luminance by photographing the test pattern with a camera, and troublesome preparation and measurement for correction, There was a problem of making the user aware of the adjustment being made, such as by showing the screen for adjustment that was annoying to the user.

  SUMMARY An advantage of some aspects of the invention is that it provides a display device and a program capable of easily aligning luminance and color balance among a plurality of displays without making the user aware of it.

  In order to achieve the above-mentioned object, the invention according to claim 1 is a hinge that pivots between the first housing in which the first display is disposed and the second housing in which the second display is disposed. Whether or not the first casing and the second casing are folded with the first display and the second display facing each other. A style detecting means for detecting, and the first display and the second display are folded so as to face each other, and arranged to face at least a part of the second display. First detection means for measuring one or both of luminance and color balance, and the first display in a state where the first display and the second display are folded facing each other. A second detector that is arranged to face at least a portion and that measures one or both of luminance and color balance of the first display; and the first casing by the style detector When it is detected that the second casing is folded, either or both of the luminance and color balance of the first display measured by the second detection means and the first One or both of the maximum brightness and color balance of the first display and the one or both so that either or both of the brightness and color balance of the second display measured by the detecting means match. A display comprising correction means for correcting one or both of the maximum brightness and color balance of the second display A b devices.

  Moreover, as a preferable aspect, for example, as in claim 2, in the display device according to claim 1, the correction unit is configured such that the first case and the second case are detected by the style detection unit. When the folding is detected, the brightness of the first display measured by the second detection means is set to a target with the first display and the second display at the maximum brightness. The maximum brightness of the first display is reduced to match the brightness, and the second display brightness so that the brightness of the second display measured by the first detection means matches the target brightness. Alternatively, the maximum luminance may be reduced.

  Further, as a preferred aspect, for example, as in claim 3, in the display device according to claim 1, the correction unit is configured such that the first case and the second case are detected by the style detection unit. When it is detected that the first display is folded, the brightness of the first display measured by the second detection means and the first display in a state where the first display and the second display are set to the maximum brightness. The brightness of the second display measured by one detection means may be compared, and the maximum brightness of the higher brightness display may be reduced so as to match the brightness of the lower brightness display.

  Further, as a preferable aspect, for example, as in claim 4, in the display device according to any one of claims 1 to 3, the correction means causes the luminance of the first display and the luminance of the second display to be correct. When the above is corrected, the display unit for setting the display on the side where the luminance is further reduced is set as the display to be used, and the first casing and the second casing are developed by the style detection unit. If it is detected, the display set as the use display by the use display setting means is used for display, and the control means for not using the display not set as the use display is further provided. Good.

  Further, as a preferred aspect, for example, as in claim 5, in the display device according to any one of claims 1 to 4, the color balance of the second display measured by the first detection means and the Color balance correction means for correcting the color balance of the first display measured by the second detection means so as to match the target color balance may be further provided.

  In order to achieve the above object, the invention described in claim 6 includes: a first casing in which a first display having a first backlight is disposed; and a second display having a second backlight. A foldable display device in which a second housing arranged is connected by a hinge so as to be pivotable, wherein the first housing and the second display are opposed to each other. Style detecting means for detecting whether or not the body and the second casing are folded; and the first casing and the second casing with the first display and the second display facing each other. In a state where the housing is folded, the first detection means is disposed so as to face at least a part of the second display, and measures the luminance of the second display; the first display; and the first display With two displays The first housing and the second housing are folded so as to face each other and face the at least part of the first display, and measure the luminance of the first display. When the first detection unit and the style detection unit detect that the first casing and the second casing are folded, the first detection unit measures the first detection unit. The drive current to the first backlight and the drive current to the second backlight so that the brightness of the display and the brightness of the second display measured by the first detection means match. And a correction means for correcting the display.

  Moreover, as a preferable aspect, for example, as in claim 7, in the display device according to claim 6, the correction unit is configured such that the first case and the second case are detected by the style detection unit. When it is detected that the first and second backlights are folded, the brightness of the first display measured by the second detection means in a state where the first backlight and the second backlight are set to the maximum brightness. The drive current to the first backlight is reduced so as to match the target brightness, and the brightness of the second display measured by the first detection means matches the target brightness. You may make it reduce the drive current of a 2nd display.

  Further, as a preferred aspect, for example, as in claim 8, in the display device according to claim 6, the correction unit is configured such that the first case and the second case are detected by the style detection unit. When the folding is detected, the brightness of the first display measured by the second detection means in a state where the first backlight and the second backlight are set to the maximum brightness. The brightness of the second display measured by the first detection means is compared, and the drive current to the backlight corresponding to the higher brightness display is adjusted so as to match the brightness of the lower brightness display. You may make it reduce.

  Further, as a preferable aspect, for example, as in claim 9, in the display device according to any one of claims 6 to 8, the correction means drives the first backlight drive current and the backlight drive. When the current is corrected, the display for correcting the driving current so as to reduce the luminance is set to the display to be used, the display setting means to be used, and the style detection means to detect the first casing and the second case. And the display set to the display used by the use display setting means and the corresponding backlight, and the display not set to the use display is detected. Control means for disabling the corresponding backlight may be further provided.

  Further, as a preferred aspect, for example, as in claim 10, in the display device according to any one of claims 6 to 9, it is obtained from the brightness of the second display measured by the first detection means. Color balance correction means for correcting the color balance and the color balance obtained from the luminance of the first display measured by the second detection means so as to match the target color balance may be further provided. Good.

  In order to achieve the above object, the invention according to claim 11 is capable of rotating the first housing in which the first display is disposed and the second housing in which the second display is disposed. Whether the first casing and the second casing are folded with the first display and the second display facing each other on a computer of a foldable display device connected to the computer with a hinge A style detecting hand function for detecting whether or not the first display and the second display are opposed to each other and folded to face at least a part of the second display; A first detection function for measuring one or both of luminance and color balance of the display; in the state where the first display and the second display are folded facing each other, the first A second detection function which is arranged to face at least a part of the display and measures one or both of luminance and color balance of the first display; and the first casing by the style detection means When it is detected that the second casing is folded, the brightness or color balance of the first display measured by the second detection means and the first detection means are measured. One or both of the maximum brightness and color balance of the first display and the maximum brightness of the second display so that either or both of the brightness and color balance of the second display match. And a color balance. A program for executing a correction function for correcting one or both of color balance and color balance.

  In order to achieve the above object, a twelfth aspect of the invention is that a first casing having a first display having a first backlight and a second display having a second backlight are provided. A computer of a foldable display device in which a second housing arranged is hingedly connected to a computer, and the first display and the second display are opposed to each other so that the first housing is opposed to the computer. A style detection function for detecting whether or not the body and the second casing are folded, and the first casing and the second casing with the first display and the second display facing each other. A first detection function for measuring the brightness of the second display, the first detection function being arranged to face at least a part of the second display in a state where the body is folded, the first display and the second display Display The first housing and the second housing are folded in a state of facing each other and arranged to face at least a part of the first display, and the brightness of the first display is measured. When the second detection function detects that the first casing and the second casing are folded by the style detection means, the first measurement measured by the second detection means Drive current to the first backlight and drive current to the second backlight so that the brightness of the display matches the brightness of the second display measured by the first detecting means. This is a program that executes a correction function for correcting.

  According to the present invention, there is an advantage that brightness and color balance can be easily aligned among a plurality of displays without making the user conscious.

It is a schematic diagram which shows the external appearance and use condition of the display apparatus by 1st Embodiment of this invention. It is a block diagram which shows the structure of the display apparatus by this 1st Embodiment. It is a flowchart for demonstrating operation | movement of the display apparatus by this 1st Embodiment. It is a conceptual diagram for demonstrating operation | movement of the display apparatus by this 1st Embodiment. It is a flowchart for demonstrating operation | movement of the display apparatus by this 2nd Embodiment. It is a schematic diagram which shows the other structural example of the display apparatus of this invention.

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

A. First embodiment A-1. Configuration of First Embodiment FIGS. 1A to 1D are schematic views showing an appearance and a usage state of a display device according to a first embodiment of the present invention. In the figure, the display device includes two liquid crystal displays 1 and 2, and the liquid crystal displays 1 and 2 are disposed in a first housing 4 and a second housing 5 via a hinge 3, respectively. The hinge 3 can be rotated 360 °. As shown in FIG. 1A, the hinge 3 is folded to 0 ° so that the liquid crystal displays 1 and 2 are inside. It is in use. In use, as shown in FIG. 1B, from the “closed” state, the hinge 3 is “opened” at 180 °, and both the liquid crystal displays 1 and 2 are used simultaneously. As shown in FIG. 1 (c), the hinge 3 is further opened at 360 ° so that the liquid crystal display 1 is on the outside, and only one liquid crystal display 1 can be used. ing.

  Next to the liquid crystal displays 1 and 2, color photosensors 6 and 7 are arranged at positions facing a part of the opposed liquid crystal displays 1 and 2 in a “closed” state in which the hinge 3 is folded at 0 °. Has been. That is, as shown in FIG. 1D, in the “closed” state in which the hinge 3 of the display device is 0 °, the liquid crystal display 1 and the liquid crystal display 2 face each other while being shifted laterally. The color photosensor 6 on the first housing 4 side faces the shifted portion of the liquid crystal display 2, and the color photosensor 7 on the second housing 5 side faces the shifted portion of the liquid crystal display 1. It has become. In other words, the liquid crystal display 1 and the liquid crystal display 2 are arranged slightly shifted in the lateral direction from the centers of the respective housings 4 and 5. In the “closed” state of the display device, a structure is adopted in which light from the liquid crystal displays 1 and 2 does not leak to the outside and light from the outside does not enter the color photosensors 6 and 7.

  FIG. 2 is a block diagram showing the configuration of the display device according to the first embodiment. In the figure, the first housing 4 includes a liquid crystal display 1, a backlight 8, a display control unit 9, a memory 10, a style detection unit 11, a processing unit 12, and a color photosensor 6. The second housing 5 includes a liquid crystal display 2, a backlight 13, a display control unit 14, a memory 15, and a color photosensor 7.

  The liquid crystal displays 1 and 2 are displays of the same system or different systems, respectively. Each of the backlights 8 and 13 is disposed on the back side of the corresponding liquid crystal display 1 or 2 and uses a white LED as a light source so that the light source including a lighting circuit can be easily and small-sized. The display control units 9 and 14 drive the liquid crystal displays 1 and 2 and the backlights 8 and 13 in accordance with the control from the processing unit 12.

  The display controllers 9 and 14 perform gamma correction in accordance with the contents of the gamma correction tables stored in the memories 10 and 15, respectively, and perform display control on the liquid crystal displays 1 and 2. The display control units 9 and 14 also control the luminance of the backlights 8 and 13, respectively. When the backlight luminance is designated from the processing unit 12, the backlight luminances stored in the memories 10 and 15 are specified. Adjust the LED current supplied to the backlights 8 and 13 according to the LED current table.

  As described above, the memories 10 and 15 each have a gamma correction table for performing gamma correction on the display of the liquid crystal displays 1 and 2 and a backlight luminance for controlling the luminance of the backlights 8 and 13. An LED current table is stored.

  The style detection unit 11 detects an “open” state in which the hinge 3 is other than 0 °, or a “closed” state in which the hinge 3 is 0 °. The color photosensors 6 and 7 face each other when the hinge 3 is “open” other than 0 ° and the hinge 3 is “closed” at 0 °, that is, when the liquid crystal displays 1 and 2 face each other. Measure the red, green, and blue brightness of the liquid crystal displays 1 and 2. That is, when the hinge 3 is in a “closed” state of 0 °, the color photosensor 6 measures the red, green, and blue luminances of the liquid crystal display 2 disposed on the second housing 5 side. The color photosensor 7 measures the red, green, and blue brightness of the liquid crystal display 1 disposed on the first housing 4 side. At this time, the backlights 8 and 13 are turned on, and the transmittance of the liquid crystal displays 1 and 2 is maximized.

  The processing unit 12 supplies data to be displayed on the liquid crystal displays 1 and 2 to the respective display control units 9 and 14 when the hinge 3 is in the “open” state other than 0 °. At this time, the display control units 9 and 14 supply the LED current to the backlights 8 and 13 and store them in the memories 10 and 15 in accordance with the backlight luminance-LED current table stored in the memories 10 and 15, respectively. The gamma correction is performed according to the contents of the gamma correction table, and the display data subjected to the gamma correction is transmitted to the liquid crystal displays 1 and 2.

  Further, when the hinge 3 is in a “closed” state of 0 °, the processing unit 12 turns on the backlights 8 and 13 and displays a correction image that maximizes the transmittance of the liquid crystal displays 1 and 2. Of the liquid crystal displays 1 and 2 measured by the color photosensors 6 and 7 based on the correction images displayed on the liquid crystal displays 1 and 2 by the display controllers 9 and 14. According to the red, green, and blue luminances, the luminance (LED current) of the two backlights 8 and 13 is adjusted to create the backlight luminance-LED current table. In addition, after the processing of the backlight brightness-LED current table, the processing unit 12 changes adjustment images for changing the red, green, and blue of the liquid crystal displays 1 and 2 from maximum to intermediate to minimum (255 to 0). The liquid crystal displays 1 and 2 measured by the color photosensors 6 and 7 on the basis of the correction images supplied to the respective display controllers 9 and 14 and displayed on the liquid crystal displays 1 and 2 by the display controllers 9 and 14. A gamma correction table for performing gamma correction according to the brightness of red, green, and blue is created.

  The white LED used for the backlights 8 and 13 has a large secular change, and the luminance / color balance changes with use time. If only one of the liquid crystal displays is used frequently, the difference in usage time between the two liquid crystal displays 1 and 2 becomes large. As a result, the difference in brightness and color balance between the two liquid crystal displays 1 and 2 are increased. The difference will also increase.

  Therefore, in the first embodiment, in the display device including the liquid crystal displays 1 and 2, the color photosensors 6 and 7 are arranged so as to face the liquid crystal displays 1 and 2 when the casing is folded. When the image is folded, an image for correction is displayed for each of the liquid crystal displays 1 and 2, and the brightness of red, green, and blue is measured by the color photosensors 6 and 7 facing each other. The backlight luminance-LED current table and the gamma correction table stored in the memories 10 and 15 are updated so that the color balance is uniform.

  Thus, by performing correction when folded, the brightness and color balance of the liquid crystal displays 1 and 2 can be made uniform without showing the correction image to the user and without being noticed at all times. Further, even when one continuous display data is displayed across the liquid crystal displays 1 and 2, it can be displayed with substantially the same luminance and color balance. Further, not only the luminance of the backlights 8 and 13 but also the characteristics of the panel transmittance and color filter of the liquid crystal displays 1 and 2 are corrected together, so that even different types of displays can be corrected.

  In the configuration of the present invention described above, the liquid crystal displays 1 and 2 that require the backlights 8 and 13 are used. However, the present invention is not limited to this. For example, a display that emits light, such as an organic EL display. There may be. In this case, the control signal for controlling the luminance of the display itself may be corrected instead of correcting the backlight driving current.

A-2. Operation of First Embodiment Next, the operation of the first embodiment described above will be described.
FIG. 3 is a flowchart for explaining the operation of the display apparatus according to the first embodiment. First, the style detection unit 11 detects the style of the display device from the state (angle) of the hinge 3 (step S10), and the processing unit 12 determines that the hinge 3 is other than 0 ° based on the detection result by the style detection unit 11. It is determined whether or not the “open” state is changed to the “closed” state of 0 °, that is, whether or not the housing is folded (step S12).

  If the casing is not folded (NO in step S12), whether or not the hinge 3 is in the “closed” state of 0 ° based on the detection result by the style detection unit 11, that is, folded. It is determined whether or not it is in the state (step S14). Here, when the hinge 3 is not in the “closed” state of 0 °, that is, when the casing is unfolded (NO in step S14), the display control units 9 and 14 are stored in the memories 10 and 15, respectively. In accordance with the contents of the backlight brightness-LED current table, the LED current is supplied to the backlight 8 to be lit (step S16), gamma correction is performed according to the contents of the gamma correction table (step S18), and the display data is liquid crystal. Displayed on the displays 1 and 2 (step S20). Thereafter, when the housing is “opened”, the above-described steps S10 to S20 are repeatedly executed.

  On the other hand, when the hinge 3 is changed from an “open” state other than 0 ° to a “closed” state of 0 °, that is, when the casing is folded (YES in step S12), the display control unit 9 , 14 is stopped, and the processing unit 12 maximizes the LED current of each of the backlights 8 and 13 to maximize the backlight output luminance (step S22). The maximum blue brightness is measured by the color photosensors 6 and 7 (step S24). In the measurement result, the liquid crystal is reduced by reducing the LED current so that the color having the lowest luminance (closest to the target value) as compared with the target color balance matches the corresponding color of the target color balance. The maximum brightness of the displays 1 and 2 is corrected (step S26).

  For example, on the liquid crystal display 1 side, among the measured values of red (R), green (G), and blue (B), as shown on the left side of FIG. Since it is lower than the other colors (red: R, blue: B) (closest to the target value), green (G) having the lowest luminance is the target luminance as shown on the left side of FIG. The brightness of the backlight 8 is corrected by reducing the LED current so as to match.

  Similarly, on the liquid crystal display 2 side, among the measured values of red (R), green (G), and blue (B), as shown on the right side of FIG. 4A, the luminance of blue (B) Is lower than other colors (red: R, green: G) (closest to the target luminance), blue (B) having the lowest luminance is the target as shown on the right side of FIG. The luminance of the backlight 13 is corrected by reducing the LED current so as to match the luminance.

  Note that the maximum brightness of each color in the target color balance must always be lower than the brightness of each color of the liquid crystal displays 1 and 2 measured by the color photosensors 6 and 7, and thus gradually increases as the usage time elapses. It is preferable to change so that it may become low.

  Then, the display control units 9 and 14 store the respective LED currents corrected in step S24 in the respective memories 10 and 15 as a backlight luminance-current table (step S28).

  Since the color balance of the liquid crystal displays 1 and 2 cannot be corrected simply by adjusting the LED currents of the backlights 8 and 13, the red, green, and blue as the adjustment images are then set to the maximum, medium, and minimum (255 The brightness is measured by the color photosensors 6 and 7 while changing to 0), and a gamma correction table is created so as to match the target gamma curve (while maintaining the color balance) (step S30). The adjustment image follows the color space handled by the processing unit 12. As a typical example, in the case of the RGB 24-bit color space, red (R, 0, 0), green (0, G, 0), blue ( 0, 0, B).

  For example, in the case of the liquid crystal display 1, as shown on the left side of FIG. 4C, the LCD characteristic after the LED luminance correction is the LCD characteristic of the color with the lowest luminance (green (G) in the illustrated example). As a reference, the gamma correction table for the liquid crystal display 1 with the target color balance maintained is created by correcting the target gamma curve. Similarly, in the case of the liquid crystal display 2, as shown on the right side of FIG. 4C, the LCD characteristics after the LED brightness correction is the LCD with the lowest brightness (blue (B) in the illustrated example). A gamma correction table for the liquid crystal display 2 maintaining the target color balance is created by correcting the target gamma curve based on the characteristics.

  In this way, the brightness of the white LEDs of the backlights 8 and 13 is corrected by reducing the LED current in accordance with the color with the lowest brightness compared with the target color balance, and the LCD characteristics after the LED brightness correction are corrected. The luminance and color balance between the liquid crystal displays 1 and 2 can be made uniform by correcting to the target gamma curve based on the LCD characteristic of the color with the lowest luminance.

  Then, each gamma correction table created in step S28 is stored in the respective memories 10 and 15 (step S32). The target color balance and gamma curve are corrected separately for the two liquid crystal displays 1 and 2 for each predetermined resolution (for example, five levels) of the luminance of the backlights 8 and 13. Through the series of correction processes described above, the backlight luminance-LED current table and the gamma correction table are finally updated. When the correction is completed, the processing unit 12 and the display control units 9 and 14 shift to the low power consumption mode (step S34). That is, the liquid crystal displays 1 and 2 are turned off.

  Further, when the hinge 3 is in the “closed” state of 0 °, that is, the folded state continues (in the case of YES in step S14), the process proceeds to step S34, and the liquid crystal displays 1 and 2 are turned off. Transition to power mode.

  Next, when the style detection unit 11 detects again the “open” state in which the hinge 3 is other than 0 °, that is, the state in which the housing is unfolded (NO in step S14), the display control units 9 and 14 respectively In step S16 to S20 described above, according to the contents of the updated backlight luminance-LED current table stored in the memories 10 and 15, the backlight 8 is supplied with the LED current to turn on, and the contents of the gamma correction table Therefore, the above correction is reflected.

  Even when the housing is unfolded, if it is not operated for a predetermined time or longer, the process may automatically shift to the low power consumption mode in step S34. And if operation is performed from anything in low power consumption mode, it will progress to step S16-S20 mentioned above.

  According to the first embodiment described above, the brightness and color balance between the liquid crystal displays 1 and 2 can be made uniform without showing the correction image to the user and without being noticed at all times. As a result, even when one continuous display data is displayed across the liquid crystal displays 1 and 2, it is possible to display so that the luminance and color balance are continuous. Furthermore, since not only the white LEDs of the backlights 8 and 13 but also the characteristics such as the panel transmittance and the color filter are corrected together, it is possible to correct even different types of displays.

  In the first embodiment described above, the LED currents of the backlights 8 and 13 are maximized to maximize the backlight output luminance, and the maximum luminances of red, green, and blue are measured by the color photosensors 6 and 7. In the results, the maximum brightness of the liquid crystal displays 1 and 2 was corrected by reducing the LED current in accordance with the color with the lowest brightness compared to the target color balance, but in addition to this, the color photosensor 6 measured. The brightness of the liquid crystal display 2 is compared with the brightness of the liquid crystal display 1 measured by the color photosensor 7 so that the brightness of the liquid crystal display on the high brightness side matches the brightness of the liquid crystal display on the low brightness side. Even if the maximum luminance of the liquid crystal displays 1 and 2 is corrected by reducing the LED current to the backlight corresponding to the liquid crystal display on the luminance side There.

B. Second Embodiment Next, a second embodiment of the present invention will be described. Since the configuration and structure of the display device are the same as those in the first embodiment, description thereof is omitted. In the second embodiment, in a display device including two liquid crystal displays 1 and 2, the casing and component arrangement are symmetric in the left and right and up and down directions, and the operation feeling does not change regardless of which of the liquid crystal displays 1 and 2 is used. Like that. Further, the display data of the liquid crystal displays 1 and 2 can be exchanged and inverted, so that the operational feeling does not change even when the casing is inverted.

  Similar to the first embodiment described above, when the casing is folded, the maximum backlight luminance of the two liquid crystal displays 1 and 2 is measured to determine which backlight is less degraded. When an activation factor such as expansion occurs from a low power consumption mode such as when the housing is folded, the display data at startup is displayed using only the liquid crystal display on the side with less backlight deterioration. However, by turning off the other, variation in deterioration of the two backlights 8 and 13 can be suppressed.

B-1. Operation of the Second Embodiment Next, the operation of the second embodiment described above will be described.
FIG. 5 is a flowchart for explaining the operation of the display apparatus according to the second embodiment. First, the style detection unit 11 detects the style of the display device from the state (angle) of the hinge 3 (step S40), and the processing unit 12 determines that the hinge 3 is other than 0 ° based on the detection result by the style detection unit 11. It is determined whether or not the “open” state is changed to the “closed” state of 0 °, that is, whether or not the housing is folded (step S42).

  When the hinge 3 changes from an “open” state other than 0 ° to a “closed” state of 0 °, that is, when the housing is folded (YES in step S42), the first described above is performed. Steps S52 to S66 are executed in the same manner as steps S22 to S34 of the embodiment. That is, the gamma correction by the display control units 9 and 14 is stopped, and the processing unit 12 maximizes the LED current of each of the backlights 8 and 13 to maximize the backlight output luminance (step S52). 2 are measured by the color photosensors 6 and 7 (step S54).

  Then, among the measurement results, the LEDs of the backlights 8 and 13 are arranged so that the color with the lowest luminance (closest to the target value) as compared with the target color balance matches the corresponding color of the target color balance. The maximum luminance of the liquid crystal displays 1 and 2 is corrected by reducing the current (step S56).

  Note that the maximum brightness of each color in the target color balance must always be lower than the brightness of each color of the liquid crystal displays 1 and 2 measured by the color photosensors 6 and 7 as in the first embodiment. It is preferable to change it so that it gradually becomes lower as the usage time elapses.

  Then, the display controllers 9 and 14 store the respective LED currents corrected in step S56 in the respective memories 10 and 15 as a backlight luminance-current table (step S58).

  Since the color balance of the liquid crystal displays 1 and 2 cannot be corrected simply by adjusting the LED currents of the backlights 8 and 13, the red, green, and blue as the adjustment images are then set to the maximum, medium, and minimum (255 The luminance is measured by the color photosensors 6 and 7 while changing to 0), and a gamma correction table is created so as to match the target gamma curve (while maintaining the color balance) (step S60). The adjustment image follows the color space handled by the processing unit 12. As a typical example, in the case of the RGB 24-bit color space, red (R, 0, 0), green (0, G, 0), blue ( 0, 0, B).

  Then, the respective gamma correction tables created in step S60 are stored in the respective memories 10 and 15 (step S62). The target color balance and gamma curve are corrected separately for the two liquid crystal displays 1 and 2 for each predetermined resolution (for example, five levels) of the luminance of the backlights 8 and 13. Through the series of correction processes described above, the backlight luminance-LED current table and the gamma correction table are finally updated.

  Furthermore, in the second embodiment, when adjusting the LED current of the backlights 8 and 13, the liquid crystal display on which the LED current is further reduced is set as a display display (step S64). In the following description, it is assumed that the liquid crystal display 1 is set as a display display. When the correction is completed, the processing unit 12 and the display control units 9 and 14 turn off the liquid crystal displays 1 and 2 and shift to the low power consumption mode (step S66).

  On the other hand, if the casing is not folded (NO in step S42), whether or not the hinge 3 is in the “closed” state of 0 ° based on the detection result by the style detection unit 11, that is, folded. It is determined whether or not it is in the state (step S44). If the hinge 3 is in the “closed” state of 0 °, that is, the folded state continues (YES in step S44), the process proceeds to step S66, and the low power consumption mode in which the liquid crystal displays 1 and 2 are turned off. Migrate to

  On the other hand, when the style detection unit 11 detects an “open” state in which the hinge 3 is other than 0 °, that is, a state in which the casing is expanded (NO in step S44), the style detection unit 11 corresponds to the liquid crystal display 1 set as the display display. The display controller 9 that supplies the LED current to the corresponding backlight 8 is turned on according to the contents of the backlight luminance-LED current table stored in the memory 10 (step S46).

  Next, the display controller 9 corresponding to the display display performs gamma correction according to the content of the gamma correction table stored in the memory 10 (step S48), and displays the display data on the liquid crystal display 1 set as the display display. (Step S50).

  The display device is in a low power consumption mode when it is not closed for a long time, even when it is “closed” or “open”, and the two liquid crystal displays 1 and 2 are turned off. . When the style detector 11 detects “open”, it starts from the low power consumption mode and displays display data such as a menu on the liquid crystal display. At this time, the display data at the time of activation is displayed only on the liquid crystal display on the side determined that the backlight is hardly deteriorated, and the other liquid crystal display is kept off. In the following operations, the display data displayed on the liquid crystal display set as the display to be used may be changed. However, the display data is not displayed at startup unless the display change to the other liquid crystal display is explicitly requested. The display data is displayed only on the displayed liquid crystal display set as the use display.

  According to the second embodiment described above, the liquid crystal display with less deterioration in the backlight is preferentially used, and the backlight and liquid crystal display with the larger deterioration are not used. Variation in deterioration of the backlights 8 and 13 can be suppressed. In addition, by preferentially using only one liquid crystal display that is determined to have little deterioration of the backlight (white LED), it is necessary to change the orientation of the housing in accordance with the orientation of the display data. However, since the arrangement of parts such as the housing and the display is made symmetrical, the user's operational feeling does not change. In addition, when the display change to the other liquid crystal display is explicitly requested, even if the liquid crystal display to be displayed is changed, the brightness and color balance between the two liquid crystal displays 1 and 2 are aligned. No discomfort to the person.

  In the first and second embodiments described above, in order to measure the luminance of the liquid crystal displays 1 and 2 facing each other by the color photosensors 6 and 7, the liquid crystal displays 1 and 2 are placed horizontally with respect to the respective housings. However, the present invention is not limited to this and may be configured as described below.

  FIGS. 6A to 6D are schematic views showing other configuration examples of the display device of the present invention. The display device includes two liquid crystal displays 1 and 2, and the liquid crystal displays 1 and 2 are respectively disposed in a first housing 4 and a second housing 5 via a hinge 3. The hinge 3 can be rotated 360 °. Also, one housing (second housing 5 in the illustrated example) can be slid along the hinge 3 in the direction of the arrow.

  As shown in FIG. 6A, the second housing 5 is slid in the direction of the arrow with the hinge 3 “closed” at 0 ° and folded so that the liquid crystal displays 1 and 2 are inside. The state is not in use. In use, as shown in FIG. 6B, the hinge 3 is “opened” at 180 ° from the folded state, and the second housing 5 is moved to an arrow as shown in FIG. 6C. The hinge 3 is further expanded to 360 ° so that both the liquid crystal displays 1 and 2 can be used simultaneously by sliding in the direction or the liquid crystal display 1 is on the outside as shown in FIG. In such a state, only one liquid crystal display 1 is used.

  In this case, as shown in FIGS. 6B to 6C, the color photosensors 6 and 7 are arranged above and below the liquid crystal displays 1 and 2, respectively. As shown in FIG. 6A, when the hinge 3 is “closed” at 0 °, folded, and the second housing 5 is slid, that is, when not in use, the hinge 3 is shown in FIG. As shown, the liquid crystal display 1 and the liquid crystal display 2 face each other while being shifted in the vertical direction. The color photosensor 6 on the first housing 4 side faces the shifted portion of the liquid crystal display 2, and the color photosensor 7 on the second housing 5 side faces the shifted portion of the liquid crystal display 1. It has become. By adopting such a structure, the liquid crystal display 1 and the liquid crystal display 2 are positioned substantially at the center of the respective casings 4 and 5 during use, so that the user feels uncomfortable due to the screen being shifted. Never give.

  In the first and second embodiments described above, the brightness and color balance of the liquid crystal displays 1 and 2 are corrected when the casing is folded. However, the correction is not performed every time the case is folded. , When the number of folding reaches a predetermined number of times, when it is folded when a predetermined time has elapsed since the previous correction process, or when the activation time is counted and immediately after the activation time reaches the predetermined time When folded, the brightness of the liquid crystal displays 1 and 2 and the color balance may be corrected. Moreover, when the backlights 8 and 13 and the liquid crystal displays 1 and 2 are folded immediately after being replaced due to a failure or the like, the brightness and color balance of the liquid crystal displays 1 and 2 may be corrected unconditionally.

DESCRIPTION OF SYMBOLS 1, 2 Liquid crystal display 3 Hinge 4 1st housing | casing 5 2nd housing | casing 6, 7 Color photo sensor 8, 13 Backlight 9, 14 Display control part 10, 15 Memory 11 Style detection part 12 Processing part

Claims (12)

A foldable display device in which a first housing in which a first display is disposed and a second housing in which a second display is disposed are pivotably connected by a hinge,
Style detecting means for detecting whether or not the first casing and the second casing are folded with the first display and the second display facing each other;
The first display and the second display are folded so as to face each other, and are arranged to face at least a part of the second display, and any one of the brightness and the color balance of the second display First detecting means for measuring either or both;
The first display and the second display are folded so as to face each other, and are arranged so as to face at least a part of the first display, and any of luminance and color balance of the first display A second detection means for measuring the color balance of one or both;
When the style detection unit detects that the first casing and the second casing are folded, the luminance and color balance of the first display measured by the second detection unit are detected. And the maximum brightness of the first display so that one or both of the brightness and the color balance of the second display measured by the first detection means match. And a correction means for correcting either or both of the maximum brightness and the color balance of the second display. The correction means includes
When it is detected by the style detection means that the first casing and the second casing are folded, the first display and the second display are in the maximum brightness state, The maximum brightness of the first display is reduced so that the brightness of the first display measured by the second detection means matches a target brightness, and the first brightness measured by the first detection means is reduced. The display device according to claim 1, wherein the maximum luminance of the second display is reduced so that the luminance of the second display matches the target luminance. The correction means includes
When it is detected by the style detection means that the first casing and the second casing are folded, the first display and the second display are in the maximum brightness state, The brightness of the first display measured by the second detection means is compared with the brightness of the second display measured by the first detection means and matches the brightness of the lower brightness display. The display device according to claim 1, wherein the maximum luminance of a display with higher luminance is reduced. Use display setting means for setting the display on the side where the brightness is further reduced to the use display when the correction means corrects the brightness of the first display and the brightness of the second display;
When it is detected by the style detection means that the first casing and the second casing are expanded, the display set as the use display by the use display setting means is used for display, The display device according to claim 1, further comprising a control unit that disables a display that has not been set as a display to be used.   The color balance of the second display measured by the first detection means and the color balance of the first display measured by the second detection means are corrected so as to match a target color balance. The display device according to claim 1, further comprising a color balance correction unit configured to perform the correction. A hinge that pivots between a first housing in which a first display having a first backlight is disposed and a second housing in which a second display having a second backlight is disposed. A foldable display device connected at
Style detecting means for detecting whether or not the first casing and the second casing are folded with the first display and the second display facing each other;
Arranged to face at least a part of the second display in a state where the first housing and the second housing are folded with the first display and the second display facing each other. First detecting means for measuring the brightness of the second display;
Arranged to face at least a part of the first display in a state where the first housing and the second housing are folded with the first display and the second display facing each other. Second detection means for measuring the luminance of the first display;
When the style detecting means detects that the first casing and the second casing are folded, the brightness of the first display measured by the second detecting means is described. Correction means for correcting the drive current to the first backlight and the drive current to the second backlight so that the brightness of the second display measured by one detection means matches. A display device comprising: The correction means includes
When it is detected by the style detection means that the first casing and the second casing are folded, the first backlight and the second backlight are in a maximum brightness state The drive current to the first backlight is reduced so that the brightness of the first display measured by the second detection means matches the target brightness, and the measurement is performed by the first detection means. The display device according to claim 6, wherein the driving current of the second display is reduced so that the luminance of the second display that is set matches the target luminance. The correction means includes
When it is detected by the style detection means that the first casing and the second casing are folded, the first backlight and the second backlight are in a maximum brightness state And comparing the brightness of the first display measured by the second detection means with the brightness of the second display measured by the first detection means to obtain a lower brightness display brightness. The display device according to claim 6, wherein a drive current to a backlight corresponding to a display with higher brightness is reduced so as to match. Use of setting the display on the side where the drive current is corrected so as to further reduce the brightness when the correction means corrects the drive current of the first backlight and the drive current of the backlight. Display setting means;
When it is detected by the style detection means that the first casing and the second casing have been deployed, a display corresponding to the display set as the use display by the use display setting means and a corresponding backlight The display device according to claim 6, further comprising: a control unit that is used for display and that does not use a backlight that is not set as the display to be used and a corresponding backlight.   A color balance obtained from the brightness of the second display measured by the first detection means and a color balance obtained from the brightness of the first display measured by the second detection means The display device according to claim 6, further comprising color balance correction means for correcting the color balance so as to match the color balance. A computer of a foldable display device in which a first casing provided with a first display and a second casing provided with a second display are hingedly connected to each other.
A style detecting hand function for detecting whether or not the first casing and the second casing are folded with the first display and the second display facing each other;
The first display and the second display are folded so as to face each other, and are arranged to face at least a part of the second display, and any one of the brightness and the color balance of the second display A first detection function for measuring either or both,
The first display and the second display are folded so as to face each other, and are arranged so as to face at least a part of the first display, and any of luminance and color balance of the first display A second detection function for measuring either or both,
When the style detection unit detects that the first casing and the second casing are folded, the luminance and color balance of the first display measured by the second detection unit are detected. And the maximum brightness of the first display so that one or both of the brightness and the color balance of the second display measured by the first detection means match. And a color balance, and a correction function for correcting either or both of the maximum brightness and color balance of the second display. A hinge that pivots between a first housing in which a first display having a first backlight is disposed and a second housing in which a second display having a second backlight is disposed. To the computer of the folding display device connected with
A style detection function for detecting whether or not the first casing and the second casing are folded with the first display and the second display facing each other;
Arranged to face at least a part of the second display in a state where the first housing and the second housing are folded with the first display and the second display facing each other. A first detection function for measuring the brightness of the second display;
Arranged to face at least a part of the first display in a state where the first housing and the second housing are folded with the first display and the second display facing each other. A second detection function for measuring the brightness of the first display;
When the style detecting means detects that the first casing and the second casing are folded, the brightness of the first display measured by the second detecting means is described. A correction function that corrects the drive current to the first backlight and the drive current to the second backlight so that the brightness of the second display measured by the first detection unit matches. A program characterized by being executed.

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