KR20100086674A - Digital image processing apparatus and method - Google Patents

Abstract

PURPOSE: A digital image processing apparatus for expressing color close to a subject color in an image process of an LCD by supplying adobe RGB color is provided to supply color space by compensating color the loss of a green and blue group. CONSTITUTION: A raw data generator(410) converts an image of optical signal into electrical signal. An sRGB(Standard Red, Green, Blue) converter(420) converts the converted image into the sRGB color space. An adobe RGB converter(430) converts the converted phase into the adobe RGB color space. An sRGB image storage unit(450) and adobe RGB image storage unit(460) store the converted image into a jpg file format or a tif file format.

Description

Digital image processing apparatus and method

The present invention relates to a digital image processing apparatus and method, and more particularly, to a digital image processing apparatus and method for providing a color space extension that can compensate for color loss of a specific color system of the image processing apparatus.

The digital image processing apparatus includes any device that processes an image of a digital camera, a personal digital assistant (PDA), a phone camera, a PC camera, or uses an image recognition sensor.

1 is a diagram illustrating an exemplary structure of a digital image processing apparatus.

The digital photographing apparatus 100 that can implement the present invention includes an optical unit 110, an optical driver 111, an imaging device 115, an imaging device controller 116, an operation unit 120, a program storage unit 130, The buffer storage unit 140, the data storage unit 150, the touch screen display 160, and the digital signal processing unit DSP may be included.

The optical unit 110 provides an optical signal input from a subject to the imaging device 115. The optical unit 110 may include at least one lens, such as a zoom lens for controlling the angle of view to be narrowed or widened according to a focal length, and a focus lens for focusing a subject. In addition, the optical unit 110 may further include an aperture for adjusting the amount of light.

The optical driver 111 adjusts the position of the lens, opening and closing of the iris, and the like. You can focus by shifting the position of the lens. In addition, the amount of light may be adjusted by adjusting the opening and closing of the iris. The optical driver 111 may control the optical unit 110 according to a control signal automatically generated by an image signal input in real time or a control signal manually input by a user's manipulation.

The optical signal transmitted through the optical unit 110 reaches the light receiving surface of the imaging device 115 to form an image of the subject. The imaging device 115 may use a Charge Coupled Device (CCD) or a Complementary Metal Oxide Semiconductor Image Sensor (CMOS) or the like that converts an optical signal into an electrical signal.

Such an image pickup device 115 may be controlled by the image pickup device control unit 116 sensitivity and the like. The imaging device controller 116 may control the imaging device 115 according to a control signal automatically generated by an image signal input in real time or a control signal manually input by a user's operation.

The operation unit 120 is a place that can input a control signal from the outside such as a user. The operation unit 120 exposes the imaging device 115 to light for a predetermined time, and releases a shutter-release button for inputting a shutter-release signal for taking a picture, a power button for supplying power, and a wide angle of view according to the input. There are a wide-angle zoom button and a tele-zoom button for increasing or narrowing the angle of view, and various function buttons for selecting a mode such as a text input or shooting mode, a playback mode, a white balance setting function, and an exposure setting function.

The operation unit 120 may have various types of buttons as described above, but is not limited thereto, and may be implemented in any form that a user can input, such as a keyboard, a touch pad, a touch screen, a remote controller, and the like.

In addition, the digital photographing apparatus 100 may include a program storage unit 130 for storing a program such as an operating system or an application system for driving the digital camera, and a buffer storage unit for temporarily storing data or result data necessary for performing an operation ( 140, a data storage unit 150 storing various information necessary for the program, including an image file including an image signal.

In addition, the digital photographing apparatus 100 includes a touch screen display 160 to display its operating state or image information photographed by the digital photographing apparatus 100. The touch screen display 160 may provide visual and / or audio information to the user. At the same time, the touch screen display 160 is provided to receive an input through a user's touch. Accordingly, the touch screen display 160 operates as a user input interface with the operation unit 120.

In addition, the digital photographing apparatus 100 includes a digital signal processor 170 that processes an input image signal and controls each component in accordance with the external input signal.

In general, the method of displaying color on an LCD (Liquid-crystal display) mounted on a mobile phone or a camera / camcorder uses a pixel data RGB 18 bit (RGB666) or RGB 16 bit (RGB565). In other words, each pixel data R, G, and B color elements are represented by 6 bits (2 ^ 6), each of which can be represented by 64 values, and only G (Green) is represented by 6 bits and R (Red) and B (Blue). Uses 5bit (2 ^ 5) which can be expressed as 32 numbers. In other words, the expression 65,000 colors refers to the RGB 16-bit (2 ^ 16) representation, and the 260,000 colors refers to the RGB 18-bit representation. Recently, RGB 24-bit (RGB888) representation has been developed.

As above standard RGB (sRGB: standard Red.Green.Blue) expression method, the color space has a lot of color loss of green and blue system, so the image is not clear or the subject during printing or image processing on LCD (Liquid-crystal display) There is a problem that can not properly express the color of.

The technical problem to be solved by the present invention is to expand the color space that can compensate for the color loss of a specific color system of the image processing apparatus represented by the color space of the standard RGB (sRGB: standard Red. Green. Blue) to solve the above problems The present invention relates to a digital image processing apparatus and method.

One embodiment of a digital image processing apparatus according to the present invention for solving the above technical problem, raw data generating unit for converting an image (image) input as an optical signal into an electrical signal; A first color space converter for converting an image converted into the electrical signal into a first color space; And a second color space converter configured to compensate for color loss of the image converted into the first color space. Characterized in that it comprises a.

Preferably, the raw data generation unit comprises a solid state imaging device (CCD: Charged Coupled Device) or a complementary metal oxide semiconductor sensor (CMOS).

Preferably, the first color space is characterized in that the standard R. G. ratio (sRGB).

Preferably, the second color space is Adobe RGB (Adobe RGB: Adobe Red. Green. Blue).

The raw data storage unit may further include a raw data storage configured to store an image converted into the electrical signal.

In accordance with another aspect of the present invention, there is provided a digital image processing method, comprising: generating raw data converting an image image input as an optical signal into an electrical signal; A first color space conversion step of converting an image converted into the electrical signal into a first color space; And a second color space conversion step of compensating for color loss of the image converted into the first color space.

Preferably, the raw data generation step may include a charged coupled device (CCD) or a complementary metal oxide semiconductor sensor (CMOS).

Preferably, the first color space is characterized in that the standard R. G. ratio (sRGB: Standard Red. Green. Blue).

Preferably, the second color space is Adobe RGB (Adobe RGB: Adobe Red. Green. Blue).

Preferably, the raw data storage step of storing the converted image (image) to the electrical signal; characterized in that it further comprises.

According to the digital image processing apparatus and method according to the present invention, Adobe RGB (Adobe RGB: Adobe Red. Green. Blue) color space expansion can be obtained, and standard RGB (sRGB: Standard Red. Green. Compared with Blue, color loss can be compensated for.

According to the digital image processing apparatus and method according to the present invention, by providing Adobe RGB: Adobe Red. Green. (Liquid-crystal display) has the effect of expressing the color closer to the subject color when processing the image.

According to the digital image processing apparatus and method according to the present invention, an expert such as a designer by providing an Adobe RGB color space capable of compensating for green and blue color loss. It can be extended to support various image processing tasks.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view for explaining the color space expansion of the digital image processing apparatus according to the present invention.

Many kinds of image processing devices reproduce colors using a device-dependent color system called RGB. Although these image processing apparatuses express all colors by additive mixing of red, green, and blue, the area capable of expressing colors differs depending on the characteristics of the device-dependent color space. This is called color gamut, and when color gamut is different for each device, color reproduction is different, which may cause various problems in the transmission of color information.

In order to deliver accurate color information, it is necessary to consider and apply a profile according to each device, which is a burdensome and cumbersome process for both the person who develops the device and the user. Therefore, we have created some color spaces that can be standard to overcome the problem of compatibility of digital device color reproduction, such as sRGB, Adobe RGB, Apple RGB, Color RGB, Match RGB.

FIG. 2 compares sRGB, Adobe RGB, Apple RGB, Color RGB, and Match RGB color spaces in an XY chromaticity diagram.

sRGB (210) is a standard RGB color space created in November 1996 by HP and Microsoft, with the idea that most CRT monitors show similar color characteristics.

Not only do most monitors have similar template colors and CRT gamma values, but the average of these devices defines the color space of standard monitors based on the fact that monitors, scanners, and digital cameras all use the RGB color space. .

This is a small color space that covers most of the device's color space, and is the standard color space for windows.

When working with images using the sRGB color space, you can achieve the same color reproduction on the web without the burden of including and transferring profiles in the image.

The sRGB color space is a typical color space that can be used throughout most digital color devices, but has a disadvantage of severe color loss in colors such as green and blue.

 The color space of the digital image processing apparatus according to the present invention can be extended to the Adobe RGB color space by supplementing the disadvantages of the green and blue color loss of the sRGB color space.

Adobe RGB 220 has been defined by Adobe as a color space that sRGB has been re-created to have a wider area around damaged colors during printing in order to overcome the problem of loss on green and blue sides when printing.

Adobe RGB is more similar to the color representation of typical printing equipment when compared to sRGB and includes almost all common CYMK (Cyan, Magenta, Yellow, and Black) color spaces. Represents an expressive area.

In particular, the color reproduction of the green and cyan areas or the orange highlight area shows much better results than the sRGB color space.

3 is a view comparing an image photographed in the sRGB color space 310 and an image photographed in the Adobe RGB color space 320 of the digital image processing apparatus according to the present invention.

Images captured in the sRGB color space 310 may be more severe in green area loss than images captured in the Adobe RGB color space 320.

Image processing designers often work with the Adobe RGB color space, which is rich in color spaces, in solid-state imaging devices (CCDs) or complementary metal-oxide semiconductor sensors (CMOSs). In the absence of raw image data obtained, an image captured in the sRGB color space cannot be converted to an image in the Adobe RGB color space.

It is possible to switch from an image captured in the Adobe RGB color space to an image in the sRGB color space, but from an image captured in the sRGB color space to an image in the Adobe RGB color space. Is impossible.

Therefore, in an image processing apparatus that does not support raw image data storage, it is necessary to further store an image captured in the Adobe RGB color space.

4 is a diagram illustrating a structure of a digital image processing apparatus having an extended color space according to the present invention.

The digital image processing apparatus having an extended color space according to the present invention includes a raw data generator 410, a storage unit 420, an sRGB converter 430, an Adobe RGB 440, and an sRGB image storage unit 450. ) And an Adobe RGB image storage unit 460.

 The raw data generating unit 410 is an optical image image formed on a solid-state image pickup device (CCD) or a complementary metal oxide semiconductor sensor (CMOS) of an image processing apparatus. Convert the signal to an electrical signal.

The raw data storage unit 420 stores an image converted into an electrical signal.

The standard red.green.blue (sRGB) converter 420 converts an image converted into an electrical signal into an sRGB color space.

The Adobe RGB converter 430 converts an image converted into an electrical signal into an Adobe RGB color space. The image obtained by the Adobe RGB converter compensates for the color loss of the green and blue series of the image converted into the sRGB color space.

The sRGB image storage unit 450 and the Adobe RGB image storage unit 460 respectively convert an image converted to an sRGB color space and an image converted to an Adobe RGB color space into a jpg file format or a TIF file format. Save it.

5 is a flowchart illustrating a digital imaging method supporting color space extension according to the present invention.

The raw data generation step may be performed by performing an electrical signal on an optical image formed on a charged coupled device (CCD) or a complementary metal oxide semiconductor sensor (CMOS) of an image processing apparatus. Convert to (s510).

The raw data storage step stores an image converted into an electrical signal (S520).

The standard red.green.blue (sRGB) conversion step converts an image converted into an electrical signal into an sRGB color space (s530).

The Adobe RGB conversion step converts an image converted into an electrical signal into the Adobe RGB color space. The image converted to the Adobe RGB color space compensates for the color loss of the green and blue series of the image converted to the sRGB color space (s540).

The sRGB image storage step and the Adobe RGB image storage step respectively store an image converted to an sRGB color space and an image converted to an Adobe RGB color space in a jpg file format or a TIF file format (s550).

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it is merely an example, and those skilled in the art may realize various modifications and equivalent other embodiments therefrom. I can understand. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

1 is a diagram illustrating an exemplary structure of a digital image processing apparatus.

2 is a view for explaining the color space expansion of the digital image processing apparatus according to the present invention.

3 is a view comparing an image photographed in the sRGB color space 310 and an image photographed in the Adobe RGB color space 320 of the digital image processing apparatus according to the present invention.

4 is a diagram illustrating a structure of a digital image processing apparatus having an extended color space according to the present invention.

5 is a flowchart illustrating a digital imaging method supporting color space extension according to the present invention.

Claims (10)

A raw data generation unit for converting an image image input as an optical signal into an electrical signal; A first color space converter for converting an image converted into the electrical signal into a first color space; And And a second color space converter configured to compensate for color loss of the image converted into the first color space. According to claim 1, The raw data generation unit A digital image processing apparatus comprising a solid state image pickup device (CCD) or a complementary metal oxide semiconductor sensor (CMOS). The method of claim 1, wherein the first color space is Digital image processing apparatus, characterized in that the standard R. G. ratio (sRGB). The method of claim 1, wherein the second color space is Digital RGB image processing apparatus characterized in that the Adobe RGB (Adobe RGB: Adobe Red. Green. Blue). The method of claim 1, And a raw data storage configured to store an image converted into the electrical signal. A raw data generation step of converting an image image input as an optical signal into an electrical signal; A first color space conversion step of converting an image converted into the electrical signal into a first color space; And And a second color space conversion step of compensating for color loss of the image converted into the first color space. The method of claim 6, wherein the raw data generation step A digital image processing method comprising a solid state imaging device (CCD: Charged Coupled Device) or a complementary metal oxide semiconductor sensor (CMOS). The method of claim 6, wherein the first color space is Digital image processing method characterized in that the standard R. G. ratio (sRGB). The method of claim 6, wherein the second color space is Digital RGB image processing method characterized in that the Adobe RGB (Adobe RGB: Adobe Red. Green. Blue). The method of claim 6, And a raw data storage step of storing an image converted into the electrical signal.

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