JP2003058125A - Electronic equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide electronic equipment which is provided with a display section capable of reproducing a desired color of an image at a low cost even though LEDs are used as a light source such as back light, front light. SOLUTION: A digital still camera 100 which is an example of electronic equipment, has a back light section 154 which utilizes white color LEDs 154b to illuminate a display section 150, a driving circuit 154f which drives the LEDs 154b, an incorporated memory of a CPU110, which stores characteristic data relative to the individual variation of the LEDs 154b and the CPU110 which is used to control the circuit 154f based on the stored data. Thus, the data corresponding to the fluctuation of the light emitting characteristics of the LEDs 154b are obtained and stored, the data are used to finely adjust the power being applied to the LEDs 154b when an image is displayed on the section 150 and a desired color is reproduced using the above illumination.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device having a display unit, and more particularly to an electronic device having a display unit having a transmissive light source unit and a reflective light source unit such as a liquid crystal display.

[0002]

2. Description of the Related Art Electronic equipment such as a digital still camera is provided with a liquid crystal display for displaying photographed images. Here, a liquid crystal display is used as a display device for various electronic devices such as a digital camera because it has advantages of a thin structure and a small electric power required for driving unlike a CRT.

Generally, in a liquid crystal display,
Since the liquid crystal panel itself does not emit light, light from a light source such as a fluorescent tube is radiated through the light guide plate from the back surface as a backlight in the case of transmissive liquid crystal and from the front surface as a front light in the case of reflective liquid crystal. The image formed on the liquid crystal panel is made visible to the observer. However, the fluorescent tube has a problem that the luminous efficiency is poor. Especially, in a small and portable electronic device, when the fluorescent tube of the liquid crystal display is turned on by the power from the built-in battery, it is necessary to obtain the necessary illuminance. Then, there is a problem that the battery is consumed much. Further, since the fluorescent tube has a short life and is relatively bulky, there is a problem that a space for installing the fluorescent tube must be secured.

[0004]

On the other hand, conventionally,
Efficient blue LED (Light Emitting)
ing diode, also called light emitting diode), it was difficult to form a white light source because it was difficult to manufacture, but due to advances in manufacturing technology, it is possible to supply blue LEDs that are compact and have high efficiency and long life. Instead of, it is starting to be used as an illumination light source. In particular, white LEDs developed in recent years have the advantage that, unlike colored LEDs, they can be used independently to reproduce the colors of the displayed color image, so that they can be used as fluorescent light sources for liquid crystal illumination. It is being replaced.

However, one of the problems when the LED is used as a light source for the backlight part is that the illuminance and the spectral characteristics of the emitted light are not uniform, and the individual emission characteristics vary. In particular, the white LED has a problem that the white point variation due to the fluorescent material is large because white light is obtained by wavelength-converting the light from a light source having a blue wavelength with the fluorescent material. If LEDs with variations are used as they are as an illumination light source such as a backlight of a liquid crystal display, the color of the image displayed on the liquid crystal display is different, and the image is likely to be out of color balance as a whole. Therefore, the value of the electronic device provided with the product as a product is reduced. On the other hand, if it is attempted to control the light emission characteristics in a narrow range in order to obtain a desired color of an image, the yield of LEDs deteriorates and the unit price thereof rises sharply.

The present invention has been made in view of the above-mentioned problems of the prior art, and it is an LED with low cost.
It is an object of the present invention to provide an electronic device including a display unit capable of reproducing a desired color of an image even when is used as an illumination light source such as a backlight or a front light.

[0007]

An electronic device according to a first aspect of the present invention is an illumination light source section using a white LED for illuminating a display section, an illumination light source for color temperature correction, the white LED and color temperature. Driving means for correcting illumination light source and the white LED
Since the characteristic data storage means stores the characteristic of the white LED and the control means for controlling the driving means based on the characteristic data stored in the characteristic data storage means, the white LED
Even when there is a variation in the light emission characteristics, by storing the characteristic data corresponding to it in advance in the characteristic data storage means, when displaying an image on the display unit, based on the characteristic data, By appropriately controlling the driving unit that drives the white LED and the color temperature correction illumination light source, a desired color can be reproduced in an image observed using the illumination. Therefore, even if a white LED, which is inexpensive but highly likely to have variations in light emission characteristics, is used, it is possible to suppress variations in the image on the display section of the electronic device, thereby increasing the value of the electronic device as a product. it can. The white LED is an LED that emits light having a wavelength corresponding to a white region in chromaticity coordinates. or,
It is preferable that the “characteristic data” include a value representing the color, such as the wavelength of the light emitted from the LED.

Further, it is preferable that the characteristic data include data relating to characteristic variations of LEDs. Here, the “characteristic variation” is, for example, the color temperature of the white LED,
White LE when corrected by an illumination light source for color temperature correction
D is the brightness characteristic of the entire illumination light source for color temperature correction.

Further, it is preferable that the characteristic data include average characteristic data of white LEDs when not adjusted.

Further, the illumination light source section is preferably a backlight for liquid crystal display.

Further, it is preferable that the illumination light source section is a front light for liquid crystal display.

Further, the electronic device is preferably a camera.

The electronic device of the second aspect of the present invention performs image data storage means for storing image data, and processing for displaying an image on the display unit based on the image data output from the image data storage means. And a characteristic data storage unit that stores characteristic data of the white LED, the processing unit performing the characteristic data. Since the image data processed for display is corrected based on the characteristic data stored in the storage means, even if the white LEDs have variations such as light emission characteristics, the characteristic data corresponding to that is obtained in advance. When the image is displayed on the display unit, for example, the processing unit stores the characteristic data in the characteristic data storage unit based on the characteristic data.
By further correcting the processed image data for display, a desired color can be reproduced in the image displayed on the display unit. Therefore, even if a white LED, which is inexpensive but highly likely to have variations in light emission characteristics, is used, it is possible to suppress variations in the image on the display section of the electronic device, thereby increasing the value of the electronic device as a product. it can.

An electronic apparatus according to a third aspect of the present invention includes an image pickup section for picking up a subject image and taking out image data as an electric signal, and image data storage means for storing the image data.
Based on the image data output from the image pickup unit or the image data output from the image data storage unit,
A processing unit that performs processing for displaying an image on the display unit;
An illumination light source unit that uses a white LED to illuminate the display unit, and a characteristic data storage unit that stores characteristic data of the white LED are provided, and the processing unit is stored in the characteristic data storage unit. Since the image data output from the image pickup unit or the image data output from the image storage unit processed for display is corrected based on the existing characteristic data, the white LED has variations such as emission characteristics. Even in the case where the characteristic data corresponding to the characteristic data is obtained and stored in the storage unit in advance, when the image is displayed on the display unit, for example, the processing unit displays the image based on the characteristic data. By further correcting the processed image data, a desired color can be reproduced in the image displayed on the display unit. Therefore, even if a white LED, which is inexpensive but highly likely to have variations in light emission characteristics, is used, it is possible to suppress variations in the image on the display section of the electronic device, thereby increasing the value of the electronic device as a product. it can.

Further, the electronic device is preferably a camera.

An electronic apparatus according to a fourth aspect of the present invention is an illumination light source section using a white LED for illuminating a display section, a color temperature correction illumination light source, and driving of the white LED and the color temperature correction illumination light source. Drive means for performing, a setting means for setting an illumination adjustment mode, a characteristic storage means for describing the characteristic data of the white LED, and a characteristic stored by the characteristic data storage means when the illumination adjustment mode is set. A control means for controlling the driving means based on the data, wherein the control means has a predetermined combination characteristic of the illumination light source and the color temperature correction illumination light source driven in the illumination adjustment mode. The characteristic data is changed based on the driving state in the predetermined characteristic so that even if there is a variation in the light emitting characteristic of the white LED, Therefore, by obtaining characteristic data corresponding to the characteristic data and storing the characteristic data in the characteristic data storage means, when displaying an image on the display unit, the white LED and the color temperature correction illumination light source are set based on the characteristic data. By appropriately controlling the driving means for driving, the composite characteristic becomes a predetermined characteristic (for example, approaches a reference white point), and a desired color can be reproduced in an image observed using the illumination. Therefore, even if a white LED, which is inexpensive but highly likely to have variations in light emission characteristics, is used, it is possible to suppress variations in the image on the display section of the electronic device, thereby increasing the value of the electronic device as a product. it can.

Further, it is preferable that the synthesizing characteristics include illuminance of the light source and color temperature characteristics.

The electronic device is preferably a camera.

An electronic apparatus according to a fifth aspect of the present invention performs image data storage means for storing image data, and processing for displaying an image on a display unit based on the image data output from the image data storage means. And a processing unit for performing, an illumination light source unit using a white LED for illuminating the display unit, a characteristic data storage unit for storing characteristic data of the white LED, and a setting unit for setting a correction mode. The processing unit includes a correction unit that corrects the image data processed for display based on the characteristic data stored in the characteristic data storage unit when the correction mode is set. Therefore, even if there are variations in the light emitting characteristics of the white LEDs, by obtaining the characteristic data corresponding thereto in advance and storing it in the characteristic data storage means,
When an image is displayed on the display unit, for example, the correction unit further corrects the processed image data for display based on the characteristic data, so that the image displayed on the display unit is desired. Can reproduce the color of. Therefore, the white LE, which is inexpensive but highly likely to have variations in light emission characteristics, etc.
Even if D is used, it is possible to suppress variations in the image on the display unit of the electronic device, and thereby increase the value of the electronic device as a product.

An electronic apparatus according to a sixth aspect of the present invention is an image pickup section for picking up a subject image and taking out image data as an electric signal, and image data storage means for storing the image data.
Based on the image data output from the image pickup unit or the image data output from the image data storage unit,
A processing unit that performs processing for displaying an image on the display unit;
The processing unit includes an illumination light source unit that uses a white LED to illuminate the display unit, a characteristic data storage unit that stores characteristic data of the white LED, and a setting unit that sets a correction mode. When the correction mode is set, a white LED is provided because a correction unit is provided to correct the image data processed for display based on the characteristic data stored in the characteristic data storage means. Even when there are variations in the light emission characteristics, by storing the characteristic data corresponding to the characteristic data in advance and storing the characteristic data in the characteristic data storage unit, when displaying an image on the display unit, based on the characteristic data, for example, The correction unit further corrects the processed image data for display, so that a desired color can be reproduced in the image displayed on the display unit. Therefore, even if a white LED, which is inexpensive but highly likely to have variations in light emission characteristics, is used, it is possible to suppress variations in the image on the display section of the electronic device, thereby increasing the value of the electronic device as a product. it can.

Further, the electronic device is preferably a camera.

The electronic apparatus according to the seventh aspect of the present invention is capable of emitting light with different spectral characteristics for illuminating the display portion, and a plurality of LEDs which become a substantially white light source by the combined light emission.
An illumination light source unit using the above, a driving unit that individually drives the plurality of LEDs, a characteristic data storage unit that stores individual characteristic data of the plurality of LEDs, and a characteristic stored in the characteristic data storage unit. Since there is a control means for controlling the driving means based on the data, even if there is a variation in the light emission characteristics of the LEDs, the characteristic data corresponding to that is obtained in advance and stored in the characteristic data storage means. When an image is displayed on the display unit, the image is observed using the illumination by controlling the drive unit, for example, by finely adjusting the power applied to each LED, based on the characteristic data thereof. The desired color can be reproduced in. Therefore, even if an LED that is inexpensive but highly likely to have variations in light emission characteristics is used, it is possible to suppress variations in the image on the display unit of the electronic device, thereby increasing the value of the electronic device as a product. .

Further, the electronic device is preferably a camera.

Further, it is preferable that the different spectral characteristics of the LEDs correspond to red, green and blue.

An electronic device according to an eighth aspect of the present invention performs image data storage means for storing image data, and processing for displaying an image on a display unit based on the image data output from the image data storage means. A processing unit to perform, an illumination light source unit using a plurality of LEDs having different spectral characteristics for illuminating the display unit, and which becomes a substantially white light source by the combined light emission, and driving of the plurality of LEDs individually. Drive means for performing, and characteristic data storage means for storing individual characteristic data of the plurality of LEDs, the processing unit,
Since the previous image data processed for display is corrected based on the characteristic data stored in the characteristic data storage means, even if the LEDs have variations such as light emission characteristics, the characteristic data corresponding to them are previously stored. When the image is displayed on the display unit, the processing unit further corrects the processed image data for display based on the characteristic data when the image is displayed on the display unit. As a result, a desired color can be reproduced in the image displayed on the display unit. Therefore, even if an LED that is inexpensive but highly likely to have variations in light emission characteristics is used, it is possible to suppress variations in the image on the display unit of the electronic device, thereby increasing the value of the electronic device as a product. .

An electronic apparatus according to a ninth aspect of the present invention is an image pickup section for picking up a subject image and taking out image data as an electric signal, and image data storage means for storing the image data.
Based on the image data output from the image pickup unit or the image data output from the image data storage unit,
A processing unit that performs processing for displaying an image on the display screen,
An illumination light source unit having a plurality of LEDs that have different spectral characteristics for illuminating the display unit and that become a substantially white light source by the combined light emission, and a driving unit that individually drives the plurality of LEDs, A characteristic data storage unit that stores individual characteristic data of the plurality of LEDs, wherein the processing unit processes the display data based on the characteristic data stored in the characteristic data storage unit. Since the image data is corrected, even when there are variations in the light emitting characteristics of the LEDs, the characteristic data corresponding thereto is obtained in advance and stored in the characteristic data storage means, thereby displaying an image on the display unit. , Based on the characteristic data, for example, the processing unit further corrects the processed image data for display, so that the desired image is displayed on the display unit. It can reproduce the color. Therefore, even if an LED that is inexpensive but highly likely to have variations in light emission characteristics is used, it is possible to suppress variations in the image on the display unit of the electronic device, thereby increasing the value of the electronic device as a product. .

Further, the electronic device is preferably a camera.

It is preferable that the different spectral characteristics of the LEDs correspond to red, green and blue.

The electronic apparatus according to the tenth aspect of the present invention is capable of emitting light with different spectral characteristics for illuminating the display portion, and a plurality of LEs which become a substantially white light source by the combined light emission.
An illumination light source unit using D, a driving unit that individually drives the plurality of LEDs, a setting unit that sets an illumination adjustment mode, and a characteristic data storage unit that stores individual characteristic data of the plurality of LEDs. When the lighting adjustment mode is set, the control means controls the driving means based on the characteristic data stored in the characteristic data storage means in the previous period, and the control means is in the lighting adjustment mode. Since the driving means is controlled so that the combined characteristic of the driven illumination light source becomes a predetermined characteristic and the characteristic data is changed based on the driving state in the predetermined characteristic, there are variations in the light emitting characteristic of the LED. Even when the characteristic data corresponding to the characteristic data is obtained in advance and stored in the characteristic data storage means, when the image is displayed on the display unit, the characteristic data is based on the characteristic data. There are, for example, by the power applied to each LED for controlling the said drive means such as a fine adjustment,
The composite characteristic becomes a predetermined characteristic (for example, approaches a reference white point), and a desired color can be reproduced in an image observed using the illumination. Therefore, even if an LED that is inexpensive but highly likely to have variations in light emission characteristics is used, it is possible to suppress variations in the image on the display unit of the electronic device, thereby increasing the value of the electronic device as a product. .

Furthermore, it is preferable that the synthesizing characteristics include the illuminance of the light source and the color temperature characteristics.

The electronic device is preferably a camera.

Furthermore, the different spectral characteristics of the LEDs are
Those corresponding to red, green and blue are preferable.

An electronic apparatus according to the eleventh aspect of the present invention performs image data storage means for storing image data, and processing for displaying an image on a display unit based on the image data output from the image data storage means. A processing unit to perform, an illumination light source unit using a plurality of LEDs having different spectral characteristics for illuminating the display unit, and which becomes a substantially white light source by the combined light emission, and driving of the plurality of LEDs individually. And a driving means for performing, a characteristic data storage means for storing the characteristic data of each of the plurality of LEDs, and a setting means for setting a correction mode, the processing section, when the correction mode is set, In the case where the LEDs have variations such as emission characteristics, since the previous term image data processed for display is corrected based on the characteristic data stored in the characteristic data storage means. Also, by previously obtaining characteristic data corresponding to the characteristic data and storing the characteristic data in the characteristic data storage means, when displaying an image on the display unit, based on the characteristic data, for example, the processing unit displays By further correcting the processed image data, a desired color can be reproduced in the image displayed on the display unit. Therefore, although the LE is inexpensive, there is a high possibility that the light emission characteristics will vary.
Even if D is used, it is possible to suppress variations in the image on the display unit of the electronic device, and thereby increase the value of the electronic device as a product.

Further, the electronic device is preferably a camera.

Further, it is preferable that the different spectral characteristics of the LEDs correspond to red, green and blue.

[0036]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below with reference to the embodiments. FIG. 1 is a diagram showing a schematic configuration of a digital still camera 10 as an example of an electronic device according to the present embodiment. FIG. 2 is a perspective view of the digital still camera 10 as viewed from the back.

In FIG. 1, a digital still camera 10 is shown.
0 is a CC that is an imaging unit that converts an optical image into image data
D120 and image processing (A / D
(Including conversion), and a memory 14 that is an image data storage unit that stores the processed image data.
0, a display unit 150 that displays an image, a correction unit 160 that corrects image data, and a CPU 110 that is a control unit that controls these. In addition to the above, a power switch 111 that supplies power to the digital still camera 100 in response to an on operation, a release switch 112 that causes the digital still camera 100 to perform shooting in response to an on operation, and a display mode of the display unit 150. And a mode switch 113 for changing the.

As shown in FIG. 2, the power switch 111 and the release switch 112 are arranged on the upper surface of the body 101 of the digital still camera 100, and the liquid crystal panel 151 of the display unit 150 and the setting means are provided on the rear surface of the body 101. A mode switch 113 is arranged. The mode switch may be a software switch that can be switched by a menu displayed on the screen.

FIG. 3 is an example of an exploded view of the display section 150. FIG. 4 is a sectional view of the display unit 150. Display unit 15
As shown in FIG. 3, reference numeral 0 includes a liquid crystal panel 151 including a liquid crystal panel drive signal wiring 151a using a flexible substrate, a light guide plate 152, a diffusion plate 153, a backlight unit 154, and the like. . As shown in FIG. 4, the backlight unit 154 has a rectangular frame 154.
a, an LED 154b mounted on a substrate (not shown) disposed at one end of the frame 154a (only one is shown in FIG. 4 due to a sectional view), and a reflection sheet 154c disposed on the bottom surface of the frame 154a. And a cord 154d for supplying power to the LED 154b, and a connector 154e for connecting the cord 154d to a power supply unit. Although a flexible substrate for driving signal wiring is connected to the liquid crystal plate 151, it is not shown here. Further, although the case where the transmissive liquid crystal with a backlight is used is shown here, the structure using a reflective liquid crystal with a front light only changes the structure and does not depend on the content of the present invention.

FIG. 5 is a diagram showing an electric circuit configuration for lighting the backlight LED. A white LED (illumination light source section) 160a for emitting white light, and a blue L for correcting the white point (that constitutes an illumination light source for color temperature correction)
The ED 160b and the red LED 160c are driven by a circuit (driving unit) 154f that drives them independently. FIG. 6 shows a circuit 154 for driving the LED emission of each color.
It is an example showing the internal configuration of f. Specifically, for example, in the case of driving the white LED 160a, the A output terminal of the drive circuit shown in FIG. 6 is the anode terminal W of the white LED of FIG.
The K output terminal of the drive circuit shown in FIG. 6 is connected to the + terminal, and the K output terminal of the drive circuit shown in FIG.
It is designed to be connected to. Each LED 160a, 1
In order to control the light emission amounts of 60b and 160c, as shown in FIG. 6, DA corresponding to the digital signal value from the CPU side
The current supplied to each LED can be variably set based on the control of the feedback level of the booster circuit according to the converter output voltage.

FIG. 12 is a diagram showing an actual arrangement of LEDs. As shown in FIG. 12, each LED 160a, 160
b and 160c are arranged on the circuit board PC, and in this example, the blue LEDs 160b are provided on both sides of the white LED 160a in the figure.
And the red LED 160c are arranged. here,
In order to correct the white LED 160a, the white LED 160
Although the same number of blue LEDs 160b and red LEDs 160c as a are arranged, if the correction amount is small, the blue LEDs 16b
0b and the number of red LEDs 160c may be reduced, or blue L may be used to reduce the board area.
An element in which the ED 160b and the red LED 160c are combined may be used.

Next, the operation of this embodiment will be described. First, when the digital still camera 100 is manufactured, the camera is set to the adjustment mode by, for example, adjusting special software or a hidden operation of software (an operation method not described in the manual). In adjustment mode,
For example, since gray or white having a specific value is displayed, the current backlight emission characteristics (spectral emission characteristics, brightness, etc.) are measured colorimetrically. White LE based on the measured emission characteristics
After adjusting the emission brightness of D160a by changing the drive current, the LED for color temperature correction (160b, 160b
The drive current in c) is changed to adjust to a predetermined illumination color temperature. Specifically, when the color temperature is high, blue L
The red LED 160 reduces the driving current of the ED 160b.
Increase the drive current of c. Alternatively, when the color temperature is low, the drive current of the red LED 160c is reduced and the drive current of the blue LED 160b is increased. In this way, when the predetermined illumination characteristic is obtained (also referred to as the combined characteristic is also the predetermined characteristic), characteristic data is acquired and C
It is stored in an internal memory of the PU 110 (such as an EEPROM, which is a characteristic data storage unit (not shown)). Here, the correction characteristic data is the white LED 16 after the illumination characteristic is adjusted.
0a drive current value, blue LED 160b drive current value,
This is the drive current value of the red LED 160c.

Here, although colorimetric adjustment was performed for color temperature correction, for example, a plurality of grays in the vicinity of an achromatic color point are displayed, and the displayed image is displayed on a chart as a process reference. It is possible to simply select the closest one, and it is desirable considering the productivity of the process.

After the digital still camera 100 is provided to the user and the user operates the release switch 112 to take a picture, the image data obtained via the CCD 120 is subjected to a predetermined process by the preprocessing unit 130. Are stored in the memory 140. Here, when displaying an image on the display unit 150 based on the stored image data, the digital still camera 100 performs the following control.

FIG. 7 is a flowchart relating to display control of the digital still camera 100. First, in step S101, the CPU 110, which is the control unit, causes the memory 1
Image data is read from 40. Next, the CPU 110
In step S102, the correction characteristic data (driving current value of each LED) is read from the built-in memory, and in step S103, the DA converter output voltage value for setting the current value is output to each LED control circuit. The illumination characteristics of the backlight are changed, and the image of the appropriate color is displayed on the display unit 150 in step S106.

For the sake of convenience of explanation, the description is limited to the image display from the memory, but it is clear that the above contents are effective even when the image is directly displayed after the processing of the CCD signal.

Next, a second embodiment of the present invention will be described. FIG. 13 is a diagram showing an electric circuit configuration for lighting the backlight LED, and here, the white LED 160a for white light emission alone is used for illumination. The circuit 154f for driving the white LED 160a is shown in FIG.
The description is omitted because it is represented by the one shown in FIG. FIG. 8 is a diagram schematically showing chromaticity coordinates of CIE1931. In FIG. 8, the emission color gamut of the white LED 160a varies within the range indicated by the area W. Generally, the range of color temperature variation is about 15000K to 4800K on the black dot locus, which is a very large range. For example, the white point at daylight source of D65 is point C (x, y)
= (0.312,0,3290), if this light source varies up to the point A of 15000K, the image becomes a very bluish color, while the light source is the point B. If there are variations up to 4800K, the image will be reddish. Therefore, even if the LED having the white point of A is used for the backlight and the LED having the white point of B is used for the backlight, even if the images are the same, the images have different shades. Will be judged. Therefore, in the embodiment of the present invention, the color of the displayed image is made appropriate as follows.

First, when the digital still camera 100 is manufactured, the camera is set to the adjustment mode by, for example, adjusting special software or hidden operation of the software. In the adjustment mode, for example, the maximum white is displayed, so
The illumination brightness of the white LED 160a is measured. Based on the measured emission characteristics, the emission brightness of the white LED is adjusted by changing the drive current, then the chromaticity point (x, y) of the white point is measured, and Y = 1 is set to the tristimulus value (X, Y). , Z) values are shown in FIG.
It is calculated by the formula shown in FIG. Furthermore, sRGB (Ref: A
Standard Default Color S
space for the Internet-sRG
R using the equation shown in FIG. 10 using the conversion factor of B).
sRGB, GsRGB, BsRGB are calculated, Kr, Kg, Kb are calculated using the formula shown in FIG. 11, and the minimum value is set to 1, and the other two values are recalculated proportionally to obtain K.
r ', Kg', Kb 'are obtained. This Kr ', Kg', K
The data b ′ is stored as correction characteristic data in the internal memory (not shown) of the CPU 110. As an example, when the R, G, and B values are 255 in the adjustment mode, the correction data is calculated when the illumination color temperature is 12000K on the black dot locus. Since the chromaticity point of 12000K on the black dot locus is about (x, y) = (0.272, 0.278), (RsRGB, GsRGB, BsRGB)
= (0.8266, 0.9951, 1.5614). Next, using the formula of FIG. 11, (Kr, Kg, K
b) = (0.920, 0.998, 1.215) is derived. Here, since Kr is the minimum value, this value is reset to 1, and (Kr ′, Kg ′, Kb ′) = 1.
000, 1.085, 1.697).

Here, the ideal value calculation for control is shown to the last, but in some cases, the color temperature of the display is divided into layers, and the center temperature of 6500K is 5500K to 9000K.
No correction up to 55 for below 5500K
Correction for 00K, 900 for over 9000K
A process called correction to 0K is also possible. Further, although the value corresponding to the ratio of the actual display level to the output data is stored, the reciprocal thereof, the value of the measured chromaticity point of the white point or the tristimulus value thereof, and the original white point D65.
May be the difference from the white point.

After the digital still camera 100 is provided to the user and the user operates the release switch 112 to take a picture, the image data obtained via the CCD 120 is subjected to a predetermined process by the preprocessing unit 130. Are stored in the memory 140. Here, when displaying an image on the display unit 150 based on the stored image data, the digital still camera 100 performs the following control.

FIG. 9 is a flow chart showing the display control of the digital still camera 100. First, in step S201, the CPU 110, which is the control unit, reads image data from the memory 140, and then in step S202.
Then, depending on the state of the mode switch 113, "normal mode"
And "correction mode" are set. If you determine that the "normal mode" is set,
In step S205, the image is displayed on the display unit 150 without correction. The image at this time will be reproduced in a good color depending on the color temperature of the illumination, but it can be displayed at high speed because the processing time of the correction calculation described later is not required.

On the other hand, if it is determined in step S202 that the "correction mode" is set, the CPU 110
Reads the above-mentioned characteristic data Kr, Kg, Kb from the built-in memory in step S203, and in step S204,
The correction unit 160 is driven to perform the following correction calculation on the R, G, and B values of each pixel. Ro = R / Kr '(1) Go = G / Kg' (2) Bo = B / Kb '(3) Note that since this operation requires a decimal point operation, the correction unit 160 performs the above operation. L corresponding to the result
It is desirable to prepare a UT so that the above calculation result can be uniquely obtained for the image data generated for display. After that, the CPU 110 is configured to display the appropriately processed image on the display unit 150 in step S106 based on the corrected image data. still,
The pre-processing unit 130 and the correction unit 160 constitute the processing unit of the present invention.

Here, the white LEDs can be replaced with LEDs of three primary colors (red, green, blue). This is because white light can be obtained by mixing the lights of the three primary colors. Therefore, in the digital still camera according to the third embodiment, the white LEDs are replaced with LEDs of three primary colors. The other points are similar to those of the above-described embodiment, and thus detailed description thereof will be omitted. In addition, LED of three primary colors
The drive circuits of 254R, 254G, and 254B are as shown in FIG.

One advantage of using the LEDs of the three primary colors is that the chromaticity coordinates shown in FIG. It may be possible to set the white point at any of the above points. That is, the correction range of the LED for color temperature correction is R-
It is limited to the B-axis, and there is a restriction that image processing is required for a white LED alone, but in the case of three primary color LEDs, by changing the LED emission amount of any color relatively, the composite characteristics of the light source Is set to a predetermined characteristic (for example, close to a reference white point), it is possible to set finer chromaticity points even when white light of the backlight unit 150 is produced. On the other hand, in order to uniformly mix the three independent primary colors, it is necessary to more strongly diffuse the diffuser plate. Such processing may be performed by the CPU, which is the control means, only when the “lighting adjustment mode” is set by operating a mode button (not shown).

Although the present invention has been described above with reference to the embodiments, the present invention should not be construed as being limited to the above embodiments, and it goes without saying that appropriate modifications and improvements are possible. is there. For example, white LED or three primary color LED
The light emission characteristic of is not limited to the time of manufacturing the digital still camera, and may be calculated after the manufacturing. This is because it is possible to cope with changes in the emission color of the LED over time.
Further, the three primary colors are not limited to red, green and blue, but may be magenta, cyan and yellow. Furthermore, the electronic device of the present invention is not limited to a digital still camera.

[0056]

According to the present invention, there is provided an electronic device which is low in cost and has a display section capable of reproducing a desired color of an image even when an LED is used as an illumination light source such as a backlight or a front light. Can be provided.

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic configuration of a digital still camera 10 as an example of an electronic device according to an embodiment.

FIG. 2 is a perspective view of the digital still camera 10 seen from the back side.

FIG. 3 is an exploded view of a display unit 150.

FIG. 4 is a cross-sectional view of a display unit 150.

FIG. 5 is a diagram showing a drive circuit for driving an LED.

FIG. 6 is a diagram showing an internal configuration of a drive circuit.

7 is a flowchart showing display control of the digital still camera 100. FIG.

FIG. 8 is a diagram schematically showing chromaticity coordinates of CIE1931.

9 is another flowchart of the display control of the digital still camera 100. FIG.

FIG. 10 is a diagram showing equations for calculating RsRGB, GsRGB, and BsRGB.

FIG. 11 is a diagram showing equations for calculating Kr, Kg, and Kb.

FIG. 12 is a diagram showing an actual LED array.

FIG. 13 is a diagram showing an electrical circuit configuration for lighting a backlight LED.

FIG. 14 is a diagram showing an equation for calculating a tristimulus value (X, Y, Z).

FIG. 15: LEDs of three primary colors 254R, 254G, 254
It is a figure which shows the drive circuit of B.

[Explanation of symbols]

100 digital still camera 110 CPU 120 CCD 130 processing unit 140 memory 150 display unit 154b, 160a white LED 160b, 160c correction LED 160 correction unit 254R, 254G, 254B red, green, blue L
ED

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H01L 33/00 H01L 33/00 L 5C022 H04N 5/225 H04N 5/225 B 5C058 5/66 102 5/66 102A 5C080 102B 5F041 H05B 37/02 H05B 37/02 L F-term (reference) 2H091 FA45 FD22 LA15 LA16 MA10 2H093 NC42 NC50 ND24 ND54 NG20 2H102 BA00 BA01 BA19 BA21 BA27 BB00 BB03 BB05 BB08 3K073 AA02 AA16 AA48 AA52 AA67 AA82 AA83 CF22 CG06 CG16 CG41 CH03 CH07 CH14 CH15 CH22 CH43 CH44 CJ17 5C006 AA21 AF13 AF46 BB11 BF02 EA01 FA22 FA52 5C022 AA13 AC03 AC69 5C058 AA06 AB03 BA06 BA29 BB11 5C080 AA10 BB05 CC03 DD05 EE28 GG12 JJ02 JJ03 JJ05 JJ06 JJ07 KK43 5F041 AA11 AA12 BB31 DA14 FF01 FF16

Claims (29)

[Claims] 1. An illumination light source unit using a white LED for illuminating a display unit, a color temperature correction illumination light source, driving means for the white LED and the color temperature correction illumination light source, and characteristics of the white LED. An electronic device, comprising: a characteristic data storage unit that stores the characteristic value; and a control unit that controls the driving unit based on the characteristic data stored in the characteristic data storage unit. 2. The electronic device according to claim 1, wherein the characteristic data includes data regarding characteristic variations of LEDs. 3. The electronic device according to claim 1, wherein the characteristic data includes average characteristic data of white LEDs when not adjusted. 4. The electronic device according to claim 1, wherein the illumination light source unit is a backlight for liquid crystal display. 5. The electronic device according to claim 1, wherein the illumination light source unit is a front light for liquid crystal display. 6. The electronic device according to claim 1, wherein the electronic device is a camera. 7. An image data storage unit for storing image data, a processing unit for performing processing for displaying an image on a display unit based on the image data output from the image data storage unit, and the display unit. And a characteristic data storage unit that stores characteristic data of the white LED, wherein the processing unit has a characteristic stored in the characteristic data storage unit. An electronic device that corrects the image data processed for display based on the data. 8. An image pickup section for taking a subject image and taking out image data as an electric signal, an image data storage section for storing the image data, and image data output from the image pickup section or the image data storage section. Based on the output image data,
A processing unit that performs processing for displaying an image on the display unit; an illumination light source unit that uses a white LED to illuminate the display unit; and a characteristic data storage unit that stores characteristic data of the white LED. The processing unit has, based on the characteristic data stored in the characteristic data storage unit, image data output from the image capturing unit processed for display or an image output from the image storage unit. An electronic device characterized by correcting data. 9. The electronic device according to claim 7, wherein the electronic device is a camera. 10. An illumination light source unit using a white LED for illuminating a display unit, a color temperature correction illumination light source, a driving means for driving the white LED and the color temperature correction illumination light source, and an illumination adjustment. Setting means for setting a mode; characteristic storing means for storing characteristic data of the white LED; and, when the illumination adjustment mode is set, the driving means based on the characteristic data stored by the characteristic data storing means. Controlling means for controlling the driving means such that a combined characteristic of the illumination light source driven in the illumination adjustment mode and the color temperature correction illumination light source has a predetermined characteristic. Then, the electronic device is characterized in that the characteristic data is changed based on a driving state in the predetermined characteristic. 11. The electronic device according to claim 10, wherein the composite characteristic includes an illuminance of a light source and a color temperature characteristic. 12. The electronic device according to claim 10, wherein the electronic device is a camera. 13. An image data storage unit for storing image data, a processing unit for performing processing for displaying an image on a display unit based on the image data output from the image data storage unit, and the display unit. An illumination light source unit using a white LED for illuminating the white LED, a characteristic data storage unit that stores characteristic data of the white LED, and a setting unit that sets a correction mode, and the processing unit includes the correction unit. An electronic apparatus comprising: a correction unit that corrects the image data processed for display based on the characteristic data stored in the characteristic data storage unit when the mode is set. 14. An image pickup section for taking a subject image and taking out image data as an electric signal, an image data storage section for storing the image data, and image data output from the image pickup section or the image data storage section. Based on the output image data,
A processing unit that performs processing for displaying an image on a display unit; an illumination light source unit that uses a white LED to illuminate the display unit; a characteristic data storage unit that stores characteristic data of the white LED; A setting unit configured to set a mode, wherein the processing unit is processed for display based on characteristic data stored in the characteristic data storage unit when the correction mode is set. An electronic device comprising a correction unit that corrects image data. 15. The electronic device according to claim 13, wherein the electronic device is a camera. 16. An illumination light source unit that uses a plurality of LEDs that can emit light with different spectral characteristics to illuminate a display unit and that becomes a substantially white light source by the combined light emission, and drive the plurality of LEDs individually. Drive means for performing the above, a characteristic data storage means for storing individual characteristic data of the plurality of LEDs, and a control means for controlling the drive means based on the characteristic data stored in the characteristic data storage means. An electronic device characterized by the above. 17. The electronic device according to claim 16, wherein the electronic device is a camera. 18. The electronic device according to claim 16, wherein the different spectral characteristics of the LEDs correspond to red, green, and blue. 19. An image data storage unit for storing image data, a processing unit for performing processing for displaying an image on a display unit based on the image data output from the image data storage unit, and the display unit. An illumination light source unit having a plurality of LEDs having different spectral characteristics for illuminating a plurality of LEDs and becoming a substantially white light source by the combined light emission thereof; a driving unit that individually drives the plurality of LEDs; Characteristic data storage means for storing individual characteristic data of the LED, wherein the processing unit is configured to display the previous period image data processed for display based on the characteristic data stored in the characteristic data storage means. An electronic device characterized by correction. 20. An image pickup section for taking a subject image and taking out image data as an electric signal, an image data storage section for storing the image data, and image data output from the image pickup section or the image data storage section. Based on the output image data,
A processing unit that performs processing for displaying an image on a display screen, and an illumination light source unit that has a plurality of LEDs that have different spectral characteristics for illuminating the display unit and that become a substantially white light source by the combined light emission. And a drive unit that individually drives the plurality of LEDs, and a characteristic data storage unit that stores individual characteristic data of the plurality of LEDs, wherein the processing unit stores in the characteristic data storage unit. An electronic device, which corrects the previous period image data processed for display, based on the obtained characteristic data. 21. The electronic device according to claim 19, wherein the electronic device is a camera. 22. The electronic device according to claim 19, wherein the different spectral characteristics of the LEDs correspond to red, green, and blue. 23. An illumination light source unit using a plurality of LEDs that can emit light with different spectral characteristics for illuminating a display unit and that becomes a substantially white light source by the combined light emission, and drive the plurality of LEDs individually. Driving means, a setting means for setting an illumination adjustment mode, a characteristic data storage means for storing individual characteristic data of the plurality of LEDs, and a previous period characteristic data storage means when the illumination adjustment mode is set. Control means for controlling the driving means based on the stored characteristic data, and the control means is configured such that the combined characteristic of the illumination light sources driven in the illumination adjustment mode becomes a predetermined characteristic. An electronic device characterized by controlling the driving means and changing the characteristic data based on a driving state in the predetermined characteristic. 24. The electronic device according to claim 23, wherein the composite characteristic includes an illuminance of a light source and a color temperature characteristic. 25. The electronic device according to claim 23, wherein the electronic device is a camera. 26. The electronic device according to claim 23, wherein the different spectral characteristics of the LEDs correspond to red, green, and blue. 27. An image data storage unit for storing image data, a processing unit for performing processing for displaying an image on a display unit based on the image data output from the image data storage unit, and the display unit. An illumination light source unit having a plurality of LEDs having different spectral characteristics for illuminating a plurality of LEDs and becoming a substantially white light source by the combined light emission thereof; a driving unit that individually drives the plurality of LEDs; It has a characteristic data storage means for storing individual characteristic data of the LED and a setting means for setting a correction mode, and the processing section is stored in the characteristic data storage means when the correction mode is set. An electronic device that corrects the previous period image data processed for display based on the characteristic data. 28. The electronic device according to claim 27, wherein the electronic device is a camera. 29. The electronic device according to claim 27, wherein the different spectral characteristics of the LEDs correspond to red, green, and blue.