JP2004045865A - Display device and mobile telephone set equipped with same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device such that the display quality of its image data is improved and a mobile telephone set equipped with the display device. <P>SOLUTION: Image data which are picked up by a camera part 13 and inputted from a video signal processing system DSP15 are so horizontally divided by an area division part 24 into n sections as to correspond to partial display areas of subpanels P1 to Pn. A luminance comparison part 26 calculates the luminance mean value Lx of the whole image data and luminance mean values Li (i=1 to n) of the respective pieces of partial image data. A luminance correction part 27 corrects a driving voltage value according to differences between the luminance mean values Li and luminance mean value Lx. A luminance adjustment part 25 determines optimum driving voltage values applied to the subpanels P1 to Pn according to inputs from the luminance comparison part 26 and luminance correction part 27 and outputs the values to adjustment electronic variable resistors R1 to Rn in driving drivers D1 to Dn corresponding to the respective subpanels P1 to Pn. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a display device that displays image data, and further relates to a mobile phone including the display device.
[0002]
[Prior art]
FIG. 3 is a perspective view showing an external appearance of the foldable mobile phone 100. FIG. 3A shows a state in which the mobile phone 100 is open, and FIG. 3B shows a state in which the mobile phone 100 is folded.
[0003]
As shown in FIG. 3A, an LCD (Liquid Crystal) on which character data, image data, and the like are displayed at the time of operation, standby, or the like, is provided inside the mobile phone 100.
(Display) 101 and an input unit 102 operated by a user when making or receiving a telephone call. As shown in FIG. 3B, an image input device (hereinafter, referred to as a camera unit) 103 is arranged outside the mobile phone 100, and an image is taken through a lens attached to the camera unit 103. The image data of the subject is displayed on the LCD 101.
[0004]
The LCD 101 is a display device using a liquid crystal as a display medium. The liquid crystal has a characteristic that the direction of the crystal changes according to the applied voltage, and the LCD 101 displays an image using this characteristic. Specifically, for example, a pair of substrates on which strip electrodes are respectively arranged are attached so that the strip electrodes cross each other, and liquid crystal is sandwiched between the substrates. By changing the voltage, the transmittance of light emitted from the backlight is changed to display the image as an image.
[0005]
FIG. 4 is a block diagram showing a configuration related to image display in mobile phone 100. As a configuration related to image display, there are an LCD 101, an input unit 102, a camera unit 103, a microcomputer 104, and a video signal processing system DSP (Digital Signal Processor) 105.
[0006]
The amount of information displayed on the LCD of a mobile phone tends to increase. Accordingly, the number of display pixels of a panel included in the LCD (a part of the LCD where an image is actually displayed) is also increasing. Therefore, the load on the entire LCD increases due to the increase in the number of electrodes accompanying the increase in the number of display pixels, and the drive voltage that can be applied by one drive driver is insufficient, and sufficient brightness cannot be obtained. Therefore, it is necessary to supply a driving voltage to one LCD by a plurality of driving drivers.
[0007]
In the case of the configuration shown in FIG. 4, the panel 107 is divided, for example, in the horizontal direction, and a drive driver 106 is arranged for each section (referred to as a sub-panel 107a). Can be applied. Here, the panel 107 is divided into n parts from first to n-th sub-panels. Each drive driver 106 is provided with an adjustment electronic volume 108.
[0008]
The camera unit 103 converts the light incident through the lens into an electric signal by the photoelectric conversion unit 109. The converted electric signal is amplified by an AGC (Auto Gain Control) 110, and is converted from an analog signal to a digital signal (image data) by an A / D (Analog / Digital) converter 111. Next, the digital signal is sent to the video signal processing system DSP 105.
[0009]
The video signal processing system DSP 105 includes an image conversion unit 112 and an RGB conversion processing unit 113. The image conversion unit 112 processes a digital signal read from the camera unit 103 based on a command from the microcomputer 104, and outputs a luminance (Y) signal and a color difference (CR, CB) signal to an RGB conversion processing unit 113. I do. The RGB conversion processing unit 113 converts the luminance (Y) signal and the color difference (CR, CB) signal into an RGB signal. The video signal processing system DSP 105 is controlled by the microcomputer 104 and adjusts white balance.
[0010]
The input unit 102 is operated by a user or the like when performing various settings of the camera unit 103 and the LCD 101 of the mobile phone 100, and outputs a signal corresponding to the operation to the microcomputer 104.
[0011]
The microcomputer 104 controls the video processing signal system DSP 105, and instructs recording and reproduction of image data on a recording medium (not shown), and adjusts white balance for removing redness and blueness of the entire image. Further, the microcomputer 104 has an area dividing unit 114 and a brightness adjusting unit 115.
[0012]
FIG. 5 is a diagram for describing image data displayed on panel 107. The image data is input to the area dividing unit 114 of the microcomputer 104 via the video signal processing system DSP 105. The area dividing unit 114 divides the image data in the horizontal direction so as to correspond to the first to n-th sub-panels 107a. Each of the divided image data is called partial image data. The partial image data is divided into first to n-th partial image data corresponding to the first to n-th sub-panels 107a, respectively.
[0013]
This partial image data is displayed as a display image on the first to n-th sub-panels 107a via the respective driver drivers 106. The user views one image data by combining the display images displayed on the first to n-th sub-panels 107a.
[0014]
The brightness adjustment unit 115 outputs the same drive signal for adjusting the image signal from the area division unit 114 to a drive voltage value suitable for the drive driver 106 to each drive driver 106. The drive driver 106 receives the drive signal from the luminance adjustment unit 115, adjusts the drive voltage value by the adjustment electronic volume 108, and generates a signal for displaying an image on the sub-panel 107a based on the drive voltage value and the image data. Supply. The sub panel 107a receives a signal input from the drive driver 106 and displays an image corresponding to the signal.
[0015]
The adjustment electronic volume 108 included in the drive driver 106 has an electrically erasable and programmable read only memory (EEPROM). When the sub panel is driven, the drive voltage value of the LCD stored therein is read by the drive driver 106. The stored drive voltage value is set to the same value in each drive driver 106.
[0016]
As another conventional technique, Japanese Patent Application Laid-Open No. 2000-308098 describes a liquid crystal display device that performs screen adjustment. In this liquid crystal display device, the microcomputer performs white balance adjustment using image data of the adjustment screen captured by the LCD panel photographing camera, and performs adjustment electronic adjustment using the RGB conversion and digital conversion adjustment screen signals. The volume is adjusted.
[0017]
[Problems to be solved by the invention]
When displaying the image data or the like captured by the camera unit 103 on the LCD 101, if the same partial image data is displayed on each sub-panel 107a, the load capacity of the sub-panel 107a becomes the same. However, such cases are few, and in most cases, the partial image data displayed on the sub-panel 107a is different, so that the load capacity of each sub-panel 107a is different.
[0018]
As described above, in the conventional display device, the driving voltage values set in the respective driving drivers 106 for driving the respective sub-panels 107a are the same, and the sub-panels 107a having different load capacities are driven based on the same driving voltage values. It has a configuration. In such a configuration, when the partial image data displayed on the sub-panel 107a is different from each other, a difference occurs in the current flowing through each sub-panel 107a. The displayed image looks as if there is.
[0019]
An object of the present invention is to provide a display device having improved display quality of image data and a mobile phone provided with the display device.
[0020]
[Means for Solving the Problems]
The present invention provides a display unit in which a display area for displaying image data is divided into a plurality of partial display areas,
A dividing unit that divides the image data into a plurality of partial image data corresponding to the partial display area,
Calculating means for calculating first brightness value information based on the brightness value of the image data and second brightness value information based on the brightness value of the partial image data for each of the partial image data;
A display device comprising: an adjustment unit that adjusts luminance for each partial display area based on a difference between the first luminance value information and the second luminance value information.
[0021]
According to the present invention, when displaying image data in a display area divided into a plurality of partial display areas, first, the dividing means converts the image data into a plurality of partial image data so as to correspond to the partial display areas. Divided into The calculating means calculates first brightness value information based on the brightness value of the entire image data, and calculates second brightness value information for each partial image data based on the brightness value of the partial image data.
[0022]
The brightness adjusting means adjusts the brightness for each partial display area based on the difference between the calculated first brightness value information and the second brightness value information. For example, when the first luminance value information relating to the entire image data is larger than the second luminance value information relating to the partial image data, the first luminance value information relating to the entire image data is adjusted so as to increase the luminance of the partial display area. Is smaller than the second luminance value information relating to the partial image data, the luminance is adjusted so that the luminance of the partial display area becomes low.
[0023]
Thus, the brightness of each partial display area can be adjusted to the entire display area. Therefore, the difference in brightness between the adjacent partial display areas is reduced, and the boundary between the partial display areas becomes inconspicuous, so that the display quality can be improved.
[0024]
Further, the invention is characterized in that the first luminance value information is an average luminance value of image data, and the second luminance value information is an average luminance value of partial image data.
[0025]
According to the present invention, the first luminance value information is an average luminance value of the entire image data, and the second luminance value information is an average luminance value of the partial image data.
[0026]
Thus, it is possible to easily calculate the difference between the first luminance value information and the second luminance value information by using the average value that is the representative value.
[0027]
Further, the invention is characterized in that the first luminance value information is an average luminance value of image data, and the second luminance value information is an average luminance value of partial image data.
[0028]
According to the invention, the display means includes at least a pair of substrates each having an electrode formed on the surface, and a liquid crystal layer sandwiched between the substrates. At this time, the brightness adjusting means adjusts a voltage value applied between the electrodes based on a difference between the first brightness value information and the second brightness value information.
[0029]
Thereby, the display quality of a liquid crystal display device using a liquid crystal as a display medium can be improved.
[0030]
The present invention also provides a display unit in which a display area formed by arranging a large number of pixels capable of displaying different gray levels is divided into a plurality of partial display areas,
Image data which is an aggregate of a large number of pixel data indicating a gradation level to be displayed at each pixel of the display area is provided, and this image data is divided into pixel data corresponding to each pixel of the plurality of partial display areas. Dividing means for dividing and outputting a plurality of partial image data as an aggregate,
Provided in correspondence with the plurality of partial display areas, and provided with partial image data output from the dividing means, generating a drive signal for determining a gradation level displayed by a pixel in each partial display area, A plurality of driving means for supplying a pixel with a driving signal for driving the pixel based on the pixel data, the driving signal corresponding to a gradation level indicated by the pixel data based on a preset reference value Driving means for determining the level of the drive signal and supplying the drive signal of the determined level to the pixel to be driven;
The image data and a plurality of partial image data from the dividing unit are provided, and the overall brightness which is an average value of the gradation levels indicated by a large number of pixel data constituting the image data is calculated. Average value calculation means for calculating a partial luminance that is an average value of the gradation levels indicated by the pixel data constituting the partial image data for each of
The total luminance of the image data and the partial luminance of each of the partial image data calculated by the luminance average value calculating means are provided, and the difference between the partial luminance of the partial image data and the total luminance of the image data is provided for each of the partial display regions. And a brightness adjusting means for setting the reference value in each of the driving means based on the obtained difference.
[0031]
According to the present invention, for each of a plurality of partial display areas constituting the display area of the display means, the luminance level can be adjusted according to the luminance level (gradation level) of the image displayed in the partial display area. This adjustment operation is performed as follows.
[0032]
First, when image data, which is an aggregate of a large number of pixel data indicating a gradation level to be displayed at each pixel in the display area, is given as image data of an image to be displayed on the display means, the image data is divided by the dividing means. And an average value calculating means. The dividing unit divides the given image data into a plurality of partial image data which is an aggregate of pixel data corresponding to each pixel of the plurality of partial display areas. The obtained partial image data is provided to the average value calculating means. The average value calculating means calculates, for the given image data, the overall brightness which is the average value of the gradation levels indicated by a large number of pixel data constituting the image data, and also calculates the partial image data for each given partial image data. Is calculated, which is the average value of the gradation levels indicated by the pixel data constituting. The calculated overall luminance of the image data and the partial luminance of each of the partial image data are provided to the luminance adjusting means.
[0033]
In the brightness adjusting means, a difference between the partial brightness of the partial image data and the entire brightness of the image data is obtained for each partial display area. The brightness adjusting means sets a reference value to the driving means for driving each partial display area based on the obtained difference. For example, for a driving unit that drives a partial display area where the partial luminance is higher than the entire luminance, a reference value lower than that of the other driving units is set, and the partial display area where the partial luminance is lower than the entire luminance is driven. A higher reference value is set for the driving means than for the other driving means.
[0034]
When generating a drive signal for driving the pixel based on the pixel data, the drive unit determines the level of the drive signal corresponding to the gradation level indicated by the pixel data based on the set reference value. For example, when the reference value is a value corresponding to the level of the drive signal when the gradation level is the maximum, the level of the drive signal corresponding to each gradation level lower than the maximum gradation level is lower than the reference value. The level is determined by sequentially subtracting only the value obtained by dividing according to the tone number. For example, when “10” is set as the reference value and the maximum gradation level is “5”, the driving signal level of gradation level “5” is 10, the driving signal of gradation level “4” is 8, and The drive signal of the gradation level “3” is determined as 6,.
[0035]
At this time, the set reference values are different in each driving means. For example, when the reference value “10” is a standard value, a reference value “9” lower than the other driving units is set for a driving unit that drives a partial display area where the partial luminance is higher than the entire luminance. The reference value “11” is set higher for the driving unit that drives the partial display area where the partial luminance is lower than the overall luminance than for the other driving units. As a result, in the driving means in which the reference value “9” is set, the driving signal level of the gradation level “5” is 9, the driving signal of the gradation level “4” is 7.2, and the driving signal of the gradation level “3” is The drive signal is determined as 5.4,. On the other hand, in the driving means in which the reference value “11” is set, the driving signal level of the gradation level “5” is 11, the driving signal of the gradation level “4” is 8.8, and the driving level of the gradation level “3” is The signal is determined as 6.6,.
[0036]
Therefore, in the partial display area where the partial luminance is higher than the overall luminance, even if the pixel data has the same gradation level, the gradation level displayed by that pixel is the gradation level displayed by each pixel in another partial display area. Since the level is lower than the level, the gradation level is lowered as the whole partial display area. Conversely, in the partial display area where the partial luminance is lower than the entire luminance, even if the pixel data has the same gradation level, the gradation level displayed by that pixel is the level displayed by each pixel in the other partial display area. Since the gray level is higher than the gray level, the gray level becomes higher for the entire partial display area.
[0037]
Thus, the brightness of each partial display area can be adjusted to the entire display area. Therefore, the difference in brightness between the adjacent partial display areas is reduced, and the boundary between the partial display areas becomes inconspicuous, so that the display quality can be improved.
[0038]
Further, the present invention, a communication means for performing telephone communication with the base station wirelessly,
Imaging means for converting incident light into an electric signal and outputting it as image data,
A mobile phone comprising the display device described above.
[0039]
According to the present invention, there is provided communication means for performing telephone communication with a base station wirelessly, and imaging means for converting incident light into an electric signal and outputting the image data as image data, and displaying the image data with the display device described above. .
Thereby, the display quality of the image on the mobile phone can be improved.
[0040]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a block diagram showing a configuration related to image display in a mobile phone 1 according to an embodiment of the present invention. The external appearance of the mobile phone 1 is the same as the external view shown in FIG. An LCD (Liquid Crystal Display) 11 on which character data, image data, and the like are displayed at the time of operation or standby, and an input unit 102 operated by the user at the time of making or receiving a call are arranged inside the mobile phone 1. A camera unit 13 is arranged outside the mobile phone 1, and image data of a subject photographed through a lens attached to the camera unit 13 is displayed on the LCD 11. In the present embodiment, the display device includes the LCD 11 and the microcomputer 14.
[0041]
As a configuration relating to image display, there are an LCD 11, an input unit 12, a camera unit 13, a microcomputer 14, and a video signal processing system DSP 15. Note that the mobile phone 1 includes a communication unit such as an antenna and a communication control unit (not shown), and performs wireless telephone communication with a base station.
[0042]
The LCD 11 is a display unit having a drive driver 16 and a panel 17. In the panel 17, a display area in which a large number of pixels capable of displaying at different grayscale levels are arranged is divided into a plurality of partial display areas. Specifically, the panel 17 is a liquid crystal panel including a pair of substrates having electrodes formed on the surface and a liquid crystal layer sandwiched between the substrates, and is similar to the panel 107 shown in FIG. The first to n-th sub-panels P1 to Pn are horizontally divided into n. By arranging drive drivers D1 to Dn for each of the plurality of divided subpanels P1 to Pn, a driving voltage is applied to each pixel of each of the subpanels P1 to Pn. Each of the drive drivers D1 to Dn is provided with an adjustment electronic volume R1 to Rn for adjusting a drive voltage value. Note that the entire area of the panel 17 where image data is displayed is a display area, and the area where the sub-panels P1 to Pn display image data is a partial display area.
[0043]
The camera section 13 converts incident light into an electric signal and outputs the electric signal as image data. The camera unit 13 converts the incident light passing through the lens into an electric signal by the photoelectric conversion unit 19, amplifies the converted electric signal by the AGC 20, and converts the analog signal into a digital signal by the A / D conversion unit 21. The digital signal is sent to the video signal processing system DSP15.
[0044]
The video signal processing system DSP 15 includes an image conversion unit 22 and an RGB conversion processing unit 23. The image conversion unit 22 processes the digital signal read from the camera unit 13 based on a command from the microcomputer 14 and outputs a luminance (Y) signal and a color difference (CR, CB) signal to an RGB conversion processing unit 23. I do. The RGB conversion processing unit 23 converts the luminance (Y) signal and the color difference (CR, CB) signal into RGB signals (image data). The video signal processing system DSP 15 is controlled by the microcomputer 14 and performs white balance adjustment. The imaging means includes a camera unit 13 and a video signal system DSP 15.
[0045]
The input unit 12 includes operation keys such as numeric keys and various function keys for the user to make and receive telephone calls. The input unit 12 is also operated when various settings of the camera unit 13 and the LCD 11 of the mobile phone 1 are performed. Is output to the microcomputer 14.
[0046]
The microcomputer 14 controls the video processing signal system DSP 15 to perform an instruction to record and reproduce image data on a recording medium (not shown), adjust a white balance for removing redness and blueness of the entire display image, and the like. The microcomputer 14 includes an area dividing unit 24, a luminance adjusting unit 25, a luminance comparing unit 26, and a luminance correcting unit 27.
[0047]
The area dividing unit 24 divides the image data input from the video signal processing system DSP 15 into n parts in the horizontal direction so as to correspond to the partial display areas of the sub-panels P1 to Pn, as in the case described with reference to FIG. It is a dividing means. The image data is an aggregate of a large number of pixel data indicating the gradation level to be displayed by each pixel of the panel 17, and this image data is the pixel data of the pixel corresponding to each pixel of the partial display area of the sub-panels P1 to Pn. The data is divided into n pieces of partial image data, which is an aggregate, and output.
[0048]
The divided image data is sent to the luminance comparing unit 26 as first to n-th partial image data. The luminance comparing unit 26 is a calculating unit that calculates the average luminance value Lx of the entire image data and the average luminance value Li (i = 1 to n) of each partial image data. Note that the average luminance value Lx is the first luminance value information, and the average luminance value Li is the second luminance value information.
[0049]
Specifically, the average luminance value Lx is calculated by dividing the sum of the luminance values, which are the gradation levels of all the pixels in the image data, by the total number of pixels. The average luminance value Li is calculated by dividing the sum of the luminance values of the pixels in each partial image data by the number of pixels.
[0050]
Further, the luminance comparing unit 26 compares the calculated luminance average value Li with the luminance average value Lx. If the difference is larger than a predetermined value, the luminance average value Li and the luminance average value Lx are used to correct the drive voltage value. Is output to the brightness correction unit 27. If the difference is smaller than the predetermined value, a predetermined drive voltage value is output to the luminance adjustment unit 25. The brightness correction unit 27 corrects the drive voltage value based on the difference between the average brightness value Li and the average brightness value Lx, and outputs the corrected drive voltage value to the brightness adjustment unit 25.
[0051]
The brightness adjustment unit 25 outputs a drive voltage value to the drive drivers D1 to Dn according to the partial image data based on the inputs from the brightness comparison unit 26 and the brightness correction unit 27. The adjustment means includes a luminance correction unit 27 and a luminance adjustment unit 25.
[0052]
As described above, the drive voltage values of the respective sub-panels P1 to Pn are determined by the microcomputer 14 and input to the respective drive drivers D1 to Dn. This drive voltage value is, for example, a reference voltage value applied to a pixel when image (gradation) data to be displayed on the sub-panel is the maximum value. The applied voltage value applied to the pixels of the sub-panel is determined from the driving voltage value and the gradation data. For example, when the drive voltage value as the reference value is 5 V and the maximum value of the gradation data is 10, the applied voltage value is 5 V when the gradation data is 10, and the applied voltage is 9 when the gradation data is 9. The value is 4.5 V. When the driving voltage value is 4 V, the applied voltage value is 4 V when the gradation data is 10, and the applied voltage value is 3.6 V when the gradation data is 9.
[0053]
In each of the drive drivers D1 to Dn, the adjustment electronic volumes R1 to Rn adjust the voltage from the power supply unit (not shown) according to the drive voltage value input from the microcomputer 14. At this time, each of the drive drivers D1 to Dn applies an applied voltage to each pixel in accordance with the drive voltage value and the partial image data output from the microcomputer 14.
[0054]
When the partial image data to be displayed on each of the sub-panels P1 to Pn is different, the number of electrodes to be applied is different, so that the capacitance of each sub-panel is different. Therefore, paying attention to the luminance of the pixel, even if the gradation data is the same, the actual applied voltage applied to the pixel is different if the sub-panel is different. Therefore, the difference in luminance between the actual pixels causes a difference in luminance between the sub-panels. On the other hand, in the present embodiment, since the drive voltage value is corrected by the brightness correction unit 27 according to the partial image data to be displayed, the difference in brightness between the sub-panels P1 to Pn is reduced, and the boundary is conspicuous. Eliminating the display improves display quality.
[0055]
FIG. 2 is a flowchart showing the image display processing of the mobile phone 1.
In step S1, the input unit 12 is operated by the user, and the camera unit 13 becomes operable. In step S2, the camera unit 13 converts the incident light that has entered through the lens into an electric signal and outputs it as a digital signal. In step S3, the video signal processing system DSP 15 processes the digital signal from the camera unit 13 and outputs an RGB signal (image data).
[0056]
In step S4, the area dividing unit 24 of the microcomputer 14 divides the image data into n pieces of partial image data. In step S5, the luminance comparing unit 26 determines whether correction is necessary based on the average luminance value.
[0057]
First, the average luminance value Li of the i-th partial image data is calculated, and at the same time, the average luminance value Lx of the image data is calculated and compared. At this time, the error value as the adjustment target is set to L0. When Li is within the range of Lx ± L0, that is, when the average luminance value Li of the partial image data is not significantly deviated from the average luminance value Lx of the entire image data, there is no need to perform correction. Is determined, and the process proceeds to step S6 with the drive voltage value set to Vi. L0 is set to, for example, 3% of the average luminance value Lx of the entire image data.
[0058]
If Li is lower than Lx-L0, that is, if the average luminance value Li of the partial image data has a large deviation from the average luminance value Lx of the entire image data and the deviation is lower, the correction is performed. It is determined that it is necessary, and the process proceeds to step S7. In step S7, the drive voltage value output from the brightness correction unit 27 to the drive driver Di is corrected. Assuming that the drive voltage value before the adjustment is Vi, a value obtained by adding the product of the constant correction value Va and the coefficient α (Vi + α · Va) to the drive voltage value is output to the drive driver Di. Here, the coefficient α is set so as to be proportional to the absolute value of the difference between the average luminance value Li of the partial image data and the average luminance value Lx of the entire image data. Therefore, the larger the difference between the two, the larger the value of the coefficient α, and thus the larger the correction value of the output drive voltage value. As described above, when the average luminance value of the partial image data is lower than the average luminance value of the entire image data, the drive voltage value is increased, and correction is performed so that the difference from the average luminance value of the entire image is reduced.
[0059]
If Li is higher than Lx + L0 in step S5, that is, if the average luminance value Li of the partial image data has a large deviation from the average luminance value Lx of the image data and the deviation is higher, step S8. Proceed to. In step S8, the drive voltage value output from the brightness correction unit 27 to the drive driver Di is corrected. Assuming that the drive voltage value before the adjustment is Vi, the product of the product of the constant correction value Va and the coefficient α (Vi−α · Va) is set as the drive voltage value to be output to the drive driver Di. Here, the coefficient α is set as described above. Therefore, as the difference between the luminance average values increases, the value of the coefficient α increases, and the correction value of the output driving voltage increases. As described above, when the average luminance value of the partial image data is higher than the average luminance value of the entire image data, the drive voltage value is reduced and the difference from the average luminance value of the entire image is corrected to be small.
[0060]
In step S6, the brightness adjustment unit 27 outputs the drive voltage value of the sub-panel Pi determined in steps S5, S7, and S8 to the drive driver Di.
[0061]
In step S9, it is determined whether or not the driving voltage values have been set for all the driving drivers (i = n). If i <n, the process proceeds to step S10, and if i = n, the process proceeds to step S11. move on. In step S10, 1 is added to i (i = i + 1), and the process returns to step S5.
[0062]
In step S11, each of the drive drivers D1 to Dn applies a drive voltage to the sub-panels P1 to Pn to display partial image data. The user can view one image data by combining the partial image data displayed in the partial display areas of the first to nth sub-panels P1 to Pn.
[0063]
As described above, the drive voltage value applied to each of the sub-panels P1 to Pn is adjusted so that the difference between the average luminance value of the entire image data and the average luminance value of each partial image data is reduced. Thereby, when the image data is displayed on the entire panel 17, the boundaries between the sub-panels P1 to Pn become inconspicuous, and the display quality is improved.
[0064]
In the present embodiment, a liquid crystal display device using liquid crystal as a display medium has been described. However, the present invention is not limited to the liquid crystal display device, but uses various display media such as a plasma display and an EL (Electro Luminescence) display. It is applicable to a display device.
[0065]
【The invention's effect】
As described above, according to the present invention, since the brightness of each partial display area can be adjusted to the entire partial display area, the difference in brightness between adjacent partial display areas is reduced, and the boundary between the partial display areas is reduced. Is less noticeable, so that the display quality can be improved.
[0066]
Further, according to the present invention, the difference between the first luminance value information and the second luminance value information can be easily calculated by using the average value that is the representative value.
[0067]
Further, according to the present invention, it is possible to improve the display quality of an image in a liquid crystal display device and a mobile phone using a liquid crystal as a display medium.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration related to image display in a mobile phone 1 according to an embodiment of the present invention.
FIG. 2 is a flowchart illustrating an image display process of the mobile phone 1;
FIG. 3 is a perspective view showing the appearance of the foldable mobile phone 100.
FIG. 4 is a block diagram showing a configuration related to image display in the mobile phone 100.
FIG. 5 is a diagram for describing image data displayed on a panel 107.
[Explanation of symbols]
1,100 mobile phone
11,101 LCD
12,102 input unit
13,103 Camera unit
14,104 Microcomputer
15,105 Video signal processing DSP
17,107 panels
19,109 Photoelectric conversion unit
20,110 AGC
21,111 A / D converter
22,112 Image conversion unit
23,113 RGB conversion processing unit
24,114 area division unit
25,115 brightness adjustment unit
26 Luminance comparison unit
27 Brightness correction unit
D1 to Dn, 106 drive driver
P1 to Pn, 107a Sub panel
R1-Rn, 108 Electronic volume for adjustment

Claims (5)

Display means in which a display area for displaying image data is divided into a plurality of partial display areas,
A dividing unit that divides the image data into a plurality of partial image data corresponding to the partial display area,
Calculating means for calculating first brightness value information based on the brightness value of the image data and second brightness value information based on the brightness value of the partial image data for each of the partial image data;
A display device comprising: an adjustment unit that adjusts luminance for each partial display area based on a difference between the first luminance value information and the second luminance value information. The display device according to claim 1, wherein the first luminance value information is a luminance average value of image data, and the second luminance value information is a luminance average value of partial image data. The display means includes at least a pair of substrates having electrodes formed on a surface thereof, and a liquid crystal layer sandwiched between the substrates,
The display device according to claim 2, wherein the brightness adjustment unit adjusts a voltage value applied between the electrodes based on a difference between the first brightness value information and the second brightness value information. A display unit in which a display area formed by arranging a large number of pixels capable of displaying at different gradation levels is divided into a plurality of partial display areas;
Image data which is an aggregate of a large number of pixel data indicating a gradation level to be displayed at each pixel of the display area is provided, and this image data is divided into pixel data corresponding to each pixel of the plurality of partial display areas. Dividing means for dividing and outputting a plurality of partial image data as an aggregate,
Provided in correspondence with the plurality of partial display areas, and provided with partial image data output from the dividing means, generating a drive signal for determining a gradation level displayed by a pixel in each partial display area, A plurality of driving means for supplying a pixel with a driving signal for driving the pixel based on the pixel data, the driving signal corresponding to a gradation level indicated by the pixel data based on a preset reference value Driving means for determining the level of the drive signal and supplying the drive signal of the determined level to the pixel to be driven;
The image data and a plurality of partial image data from the dividing unit are provided, and the overall brightness which is an average value of the gradation levels indicated by a large number of pixel data constituting the image data is calculated. Average value calculation means for calculating a partial luminance that is an average value of the gradation levels indicated by the pixel data constituting the partial image data for each of
The total luminance of the image data and the partial luminance of each of the partial image data calculated by the luminance average value calculating means are provided, and the difference between the partial luminance of the partial image data and the total luminance of the image data is provided for each of the partial display regions. And an adjusting means for setting the reference value in each of the driving means based on the obtained difference. Communication means for performing telephone communication with the base station wirelessly;
Imaging means for converting incident light into an electric signal and outputting it as image data,
A mobile phone, comprising: the display device according to claim 1.

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