KR20060044047A - Image save method of a digital image equipment - Google Patents

Abstract

The present invention relates to an image storage method of a digital imaging apparatus, and an object of the present invention is to store an original image input through a CCD so that an image improvement algorithm developed later can be applied to an image of a digital imaging apparatus. It is to provide a storage method.

To this end, the present invention is characterized in that, when taking an image with a digital imaging device, the original image entered through the charge coupling device is stored as it is without undergoing an image processing process.

In addition, when the original image is stored, additional data in which information about the original image is recorded is stored together.

Description

Image save method of a digital image equipment

1 is a block diagram illustrating components of a digital imaging apparatus according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating a configuration of image data stored in the digital imaging apparatus shown in FIG. 1.

3 is a flowchart illustrating an image storing method of the digital imaging apparatus shown in FIG. 1.

Explanation of symbols on the main parts of the drawings

102: CCD

103: preprocessor

104: image processing unit

105: CPU

107: SDRAM

201: HEADER

202: LOW DATA

The present invention relates to an image storing method of a digital imaging apparatus, and more particularly, to an image storing method of a digital imaging apparatus capable of storing an original image as it is without processing a photographed image.

In general, a digital imaging apparatus such as a DVD player, a camcorder, a digital camera, etc., captures an image through a photo detector such as a charge coupled device (CCD), and then uses various image processing techniques. Will be processed and stored. In this case, the shape of the processed image is determined by how the image processing technique is applied.

The image storage method of the digital imaging device is as follows. A signal input through an optical device such as a lens is converted into an electrical signal while passing through the CCD, and a preprocessing process is performed to remove noise of the signal passing through the CCD and adjust the level of the signal. The preprocessed signal is separated into Y and C signals after correcting the color, brightness, and white balance. The separated signal is adjusted to fit the size of the image and then stored in a storage medium such as SDRAM.

On the other hand, when a new video improvement algorithm is applied to a previously stored video signal, the video signal is reconstructed using the video signal stored in the storage medium.

However, since the image stored in the storage medium is already processed through the CCD and then processed, there is a limit to reprocessing, and there is a problem that even if an improved image processing technique is developed after the image is processed and stored once, it cannot be applied.

The present invention is to solve the above-mentioned problems, an object of the present invention is to store the original image (CC) through the CCD image storage method that can be applied to the image improvement algorithm that is developed later In providing.

The present invention for achieving the above object is characterized in that when taking an image with a digital imaging device, the original image entered through the charge coupling device is stored as it is without undergoing an image processing process.

In addition, when the original image is stored, additional data in which information about the original image is recorded is stored together.

In addition, when the quality of the image is to be increased using the image improvement algorithm, the image improvement algorithm is applied to the stored original image.

The method may further include applying the image improvement algorithm after transferring the stored original image to another medium through a removable storage medium.

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

1 illustrates a digital imaging apparatus according to an embodiment of the present invention, which includes a lens 101, a CCD 102, a preprocessor 103, an image processor 104, a CPU 105, a scaler ( 108, a formatter 109, an LCD control unit 110, a display driver 111, a display unit 112, a ROM 106, an SDRAM 107, and a data bus 113.

The central processing unit (CPU) 105 controls the overall operation of the digital imaging apparatus. The CPU 105 includes a read only memory (ROM) 106 that stores a control program, and a synchronous dynamic random number (SDRAM). An Access Memory (107), a Charge Coupled Device (CCD) 102, and a Scaler 108 are connected. The CPU 105 performs various control processes in accordance with the control program stored in the ROM 106.

 The lens 101 is composed of several lens groups in order to optically project the subject image onto the CCD 102. The CCD 102 is a charge coupled device that converts a captured image projected by the lens 101 into an analog electric signal. The preprocessor 103 includes a circuit for removing noise of the CCD 102 output signal, processing a signal level, and an A / D converter circuit for converting an analog signal into a digital signal. It is included.

The image processor 104 separates the signal output from the preprocessor 103 into Y and C signals through a process of color and luminance and performs signal correction such as white balance. It is responsible for the image improvement algorithm.

The scaler 108 adjusts the resolution to fit the size of the image. The scaler 108 adjusts the resolution to suit each device depending on whether the device on which the image is displayed is a TV or a PC. It is also called Digital Zoom Processor.

The SDRAM 107 not only receives and stores the video signal output from the scaler 108 through the CPU 105 but also stores the original video signal passed through the CCD 102 and the preprocessor 103 and the image processor ( 104, may be directly received and stored through the CPU 105 without passing through the scaler 108.

The formatter 109 follows the format of ITU.R-656 and is responsible for converting the video signal to match the signal format of the digital video device. The LCD control unit 110 receives the Y, C format video signal transmitted from the formatter 109, converts the image signal into an RGB digital signal, and outputs the RGB signal to the display driver 111. The display driver 111 controls the driving of the display unit 112. The display unit 112 is an apparatus for displaying an image and is implemented as an LCD or a TFT LCD.

In the SDRAM 107, data of a captured image signal is stored. Unlike in the related art, a circle passed through the CCD 102 as well as an image processed through the preprocessor 103, the image processing unit 104, the scaler 108, and the like, are stored. The image will be saved. FIG. 2 illustrates a data configuration of a video signal stored in the SDRAM 107. In addition to the low data 202 having data information on the video signal, the white balance, resolution, exposure, etc. of the video signal are shown. The header portion 201 including additional information of the is stored in the form included.

Hereinafter, an image storing method of a digital imaging apparatus according to an embodiment of the present invention will be described with reference to FIG. 3.                     

When the photographing mode of the digital imaging apparatus is started, the CCD module including the CCD 102, the preprocessor 103, and the like are set in an operable state and photographing is started.

When shooting starts and the image enters through the lens 101, the image is converted into an electrical signal while passing through the CCD 102. This signal takes the form of an analog signal (S110). The user selects whether to store the original image passed through the CCD 102 as it is, depending on whether or not the current captured image is an important image. Accordingly, the CPU 105 determines whether the user has selected to save the original image (S120).

If it is determined that the original image is to be stored, the original image passing through the CCD 102 is input to the CPU 105 as it is, and the CPU 105 inputs the input image to the SDRAM 107 via the data bus 113. Control to be delivered. In the SDRAM 107, an input original image is stored. As shown in FIG. 2, a header including not only data LOW DATA 202 related to the original image but also various additional information of the original image is included. A portion 201 is included. The additional data is included to provide more complete image processing by providing information on the original image when the original image is subsequently processed or reconstructed (S130).

If the original image stored in the SDRAM 107 is to be reconstructed later by applying an improved image processing algorithm, the CPU 105 may convert the original image stored in the SDRAM 107 between the rear ends 102 and 103 of the CCD. (S140) Accordingly, the original image stored in the SDRAM 107 is input to the preprocessor 103. Meanwhile, even when the user inputs a signal not to store the original image in operation 120, the original image passing through the CCD 102 is input to the preprocessor 103 as it is.

When the original image is directly input to the preprocessor 103 by passing through the CCD 102 or the original image stored in the SDRAM 107 is input to the preprocessor 103, the preprocessor 103 makes noise of the original image. The signal processing is performed such as to remove the signal, convert the level of the signal, and the like.

The image of which signal processing is completed by the preprocessor 103 is output to the image processor 104. The image processing unit 104 applies an image processing algorithm to adjust the white balance, focus, brightness, color, etc. of the video signal to an optimal state, and separates the video signal into a Y signal and a C signal (S210). The processing algorithm is not always the same, but when a more advanced algorithm is developed, the current algorithm is updated and used. Accordingly, the video signal can be processed by applying an improved algorithm to the image processing algorithm at the time of capturing the original image stored in the SDRAM 107.

If image processing is completed in the image processing unit 104, the processed image is input to the scaler 108. The scaler 108 adjusts the size of the resolution according to the image medium. Since the required level of resolution varies depending on whether the medium on which the image is to be displayed is a TV, a PC, or a portable terminal, the control is performed.

The image having completed signal processing up to the size of the resolution is stored in the SDRAM 107 via the data bus 113 (S230). The image is also input to the formatter 109 of ITU.R-656. In this case, the format of the video signal is converted according to the signal of the digital video apparatus. (S240) When the conversion is completed, the LCD control unit 110 converts the video signal in the form of the Y signal and the C signal into the form of the RGB signal. The display driver 111 receives the RGB signal and controls the image to be displayed on the display unit 112 (S260).

In this way, the original image passing through the CCD can be directly processed and stored in the SDRAM as well as stored in the SDRAM as it is before being processed.

As described in detail above, in the present invention, in storing an image taken by a digital imaging apparatus, before processing an image considered to be important, it is stored in the form of an original image so that an error occurs in the processing step or other image processing parameters are applied. If you want to be able to reconstruct using the original image.

In addition, when the image processing algorithm is further improved after capturing the original image, it is possible to apply the improved algorithm to the stored original image, so that there is no restriction in applying the algorithm unlike the application to the already processed image.

Claims (4)

An image storage method of a digital imaging apparatus, wherein when the image is captured by the digital imaging apparatus, the original image, which is input through the charge coupling device, is stored without undergoing an image processing process. The method of claim 1, And storing the additional data in which the information on the original image is recorded when the original image is stored. The method of claim 1, If the quality of the image is to be increased by using an image improvement algorithm, the image storage method of claim 1, wherein the image improvement algorithm is applied to the stored original image. The method of claim 3, wherein And moving the stored original image to another medium through a removable storage medium and applying the image improvement algorithm.

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