JP2003125209A - Image processor, electronic camera, and image processing program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily realize mode switching between an ordinary compression mode and a RAW compression mode with simple constitution and simple operations. SOLUTION: An image processor for processing RAW data comprising a plurality of kinds of signal components, which are components of a color image and intermingledly arranged on a pixel array, is provided with; a mode setting section for mode-switching between the ordinary compression mode and the RAW compression mode in response to an external instruction entry; a signal processing section for applying interpolation processing to the RAW data to supplement missing signal components in the unit of pixels in the ordinary compression mode and bypassing the interpolation processing in the RAW compression mode; and an image compression processing for compressing an image output of the signal processing section. This image processor bypasses the interpolation processing to easily realize the operation switching of the RAW compression mode.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a normal compression mode /
The present invention relates to an image processing device equipped with a switchable RAW compression mode. The present invention relates to an electronic camera equipped with this image processing device. The present invention relates to an image processing program for realizing this image processing device by a computer.

[0002]

2. Description of the Related Art Conventional electronic cameras are known in which the following two types of compression modes can be selected when recording image data.

(1) Normal compression mode: a mode in which irreversible compression such as JPEG is executed after signal processing such as color interpolation is applied to the output of the image pickup device. Note that the general normal compression mode is often subdivided into finer compression modes depending on the compression size setting (fine, basic, etc.) of lossy compression.

(2) RAW compression mode: Reversible compression such as variable length coding (including pseudo reversible compression that may cause a minute compression distortion) is applied to data before color interpolation (so-called RAW data). The mode to run.

In these two compression modes, the processing procedure and processing contents of the compression processing are greatly different. Therefore, the conventional electronic camera has two types of compression processing units in preparation for these two types of compression modes.

For example, the compression process in the normal compression mode is often left to a JPEG compression IC having a hardware configuration. Further, the compression processing in the RAW compression mode is often left to software compression processing by an MPU (microprocessor unit) inside the electronic camera.

[0007]

As described above, the conventional electronic camera has the dedicated compression mechanism for each of the normal compression mode / RAW compression mode. Therefore, there are problems that the configuration of the electronic camera becomes complicated and that switching of signal paths at the time of mode switching becomes complicated. The present invention has been made in view of such problems, and an object thereof is to provide a configuration for easily switching between the normal compression mode and the RAW compression mode.

[0008]

The present invention will be described below.

<Claim 1> An image processing apparatus according to the invention of claim 1 is an image processing apparatus for processing "RAW data in which a plurality of types of signal components forming a color image are mixedly arranged on a pixel array". In addition, a mode setting unit that switches the mode between the normal compression mode and the RAW compression mode in response to an instruction input from the outside, and complements a signal component missing in pixel units by interpolating the RAW data in the normal compression mode. A signal processing unit that bypasses the interpolation process in the RAW compression mode and an image compression unit that compresses the output of the signal processing unit are provided. In this image processing device, at least the interpolation process is bypassed to realize the operation in the RAW compression mode.

<Claim 2> An image processing apparatus according to a second aspect of the present invention is the image processing apparatus according to the first aspect, wherein the signal processing unit classifies the RAW data according to the type of signal component in the RAW compression mode. And output.

<Claim 3> An image processing apparatus according to a third aspect of the present invention is the image processing apparatus according to any one of the first and second aspects, wherein the signal processing unit is in the normal compression mode. The image signal is output in a state where color coordinate conversion is performed, and this color coordinate conversion is bypassed in the RAW compression mode.

<Claim 4> An image processing apparatus according to a fourth aspect of the present invention is the image processing apparatus according to any one of the first to third aspects, in which the image compression unit is in the RAW compression mode. The compression distortion of image compression is made lower than in the normal compression mode.

<Claim 5> An image processing apparatus according to a fifth aspect of the present invention is the image processing apparatus according to any one of the first to third aspects, wherein the image compression unit is in the normal compression mode. The file size after compression is adjusted within the target range, and the compression distortion is adjusted within the target range in the RAW compression mode.

<Claim 6> An image processing apparatus according to a sixth aspect of the present invention is the image processing apparatus according to any one of the first to fifth aspects, in which the image compression unit is in the RAW compression mode. A code indicating that interpolation processing is not performed is added to the compressed image data.

<Claim 7> An electronic camera according to the invention of claim 7 is an RA in which a plurality of types of signal components forming a color image are mixedly arranged on a pixel array by capturing a subject image.
An imaging unit that generates W data, and claims 1 to 6.
The image processing device according to any one of 1 to 5 above. In this electronic camera, the RAW data generated by the image capturing unit is processed by the image processing device.

<Claim 8> An image processing program according to the invention of claim 8 causes a computer to use a mode setting section, a signal processing section, and an image compression section according to any one of claims 1 to 6. It is characterized by making it function as.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

<< Structure of this Embodiment >> FIG. 1 is a diagram showing an electronic camera 11 (including an image processing apparatus) of this embodiment. In FIG. 1, the electronic camera 11 includes a photographing lens 1
2 is attached. The image pickup surface of the image pickup device 13 is arranged in the image space of the taking lens 12. On the image pickup surface of the image pickup device 13, a Bayer array color filter array is arranged.

From the image pickup device 13, R as shown in FIG.
AW data is output. The RAW data is composed of a plurality of types of signal components (here, RGB) that form a color image.
Are mixedly arranged on the pixel array. Here, since the single plate type image pickup device 13 is used, one kind of signal component is distributed to one pixel in the RAW data. The RAW data output from the image sensor 13 in this way is A / D
It is digitized via the conversion unit 14. The digitized RAW data is processed by the signal processing unit 15 and the image compression unit 16, and then recorded in the recording unit 17 as a compressed file.

Further, the electronic camera 11 is provided with a mode setting section 18. The mode setting unit 18 takes in an instruction input (here, a setting operation from the user) via an operation member (not shown), and switches the mode setting of the compression mode according to the instruction input. Next, the internal data flow of the signal processing unit 15 shown in FIG. 1 will be described. In the signal processing unit 15, a route switching unit 19, an interpolation processing unit 20,
A color coordinate conversion unit 21 and a pixel rearrangement processing unit 22 are provided. Among these, the path switching unit 19 switches the signal path of the RAW data according to the switching of the compression mode of the mode setting unit 18.

That is, in the "normal compression mode",
The RAW data includes the interpolation processing unit 20 and the color coordinate conversion unit 2.
After being processed by 1, it is output to the image compression unit 16. On the other hand, in the “RAW compression mode”, the RAW data is processed by the pixel rearrangement processing unit 22 after bypassing the interpolation processing unit 20 and the color coordinate conversion unit 21. After such processing, the RAW data is output to the image compression unit 16.

<< Correspondence Relationship with Invention >> The correspondence relationship between the invention and this embodiment will be described below. It should be noted that the correspondence relationship here is one interpretation for reference,
The invention is not limited to them. The mode setting unit described in the claims corresponds to the mode setting unit 18. The signal processing unit described in the claims corresponds to the signal processing unit 15. The image compression unit described in the claims corresponds to the image compression unit 16. The image pickup unit described in the claims corresponds to the image pickup device 13.

<< Operation of the Present Embodiment >> Hereinafter, the electronic camera 1 will be described.
The operation of No. 1 will be described. Here, in order to clarify the correspondence with the invention, the operation of the signal processing unit 15 will be described separately for each compression mode. After that, a common processing procedure performed by the image compression unit 16 will be described.

[Signal processing unit 15 in normal compression mode]
Description of Operation] First, the operation of the signal processing unit 15 set to the normal compression mode will be described. The route switching unit 19
The RAW data input to the signal processing unit 15 is transmitted to the interpolation processing unit 20 according to the setting of the normal compression mode. The interpolation processing unit 20 first temporarily stores the transmitted RAW data in a buffer memory (not shown) in the signal processing unit 15. Subsequently, the interpolation processing unit 20 reads R from the buffer memory.
The AW data is read out in appropriate processing units and a known interpolation process is executed.

The interpolation processing here is a method of compensating for the missing signal component with a weighted average value or median value of peripheral pixels. An interpolation method that determines the image structure of the surrounding pixels (direction of edge lines, etc.) and preferentially uses the direction with a small amount of change (similar direction) to calculate the weighted average value or median value. A method of performing color difference conversion of signal components and executing interpolation processing in the color difference space. Many other interpolation methods can be used, such as.

By such interpolation processing, as shown in FIG. 2, the signal component that is missing in pixel units in the RAW data is supplemented. The interpolation processing unit 20 transmits the RGB data after the interpolation processing to the color coordinate conversion unit 21. The color coordinate conversion unit 21 performs color coordinate conversion, such as multiplying the transmitted RGB data by a color conversion matrix.
By this color coordinate conversion, the RGB data is converted into a component for normal compression such as YCbCr (see FIG. 3). At this time, for colors or color differences with low visual sensitivity, data reduction such as pixel thinning may be performed.
The color coordinate conversion unit 21 uses the YC color coordinates converted in this way.
The components of bCr are sequentially output to the image compression unit 16.

[Signal processing unit 1 in RAW compression mode
Description of Operation 5] Next, the operation of the signal processing unit 15 set in the RAW compression mode will be described. Route switching unit 19
According to the setting of the RAW compression mode.
The processing of the color coordinate conversion unit 21 is bypassed, and the RAW data is transmitted to the pixel rearrangement processing unit 22.

The pixel rearrangement processing unit 22 transmits the R
As shown in FIG. 4, the AW data is classified according to the type of signal component. As a result, a plurality of types of signal components that make up the RAW data are classified and organized into the following four components. G1 composed of G signal components in odd columns and rows
component. G2 composed of G signal components of even columns and even rows
component. An R component composed of R signal components. B component composed of B signal components.

Note that G1 and G2 are images in which the sampling positions are slightly shifted by vertical and horizontal one pixel (that is, in the diagonal direction). Therefore, the data correlation between G1 and G2 is generally extremely high except for special image patterns such as diagonal stripes. Therefore, the encoding efficiency may be improved by using “difference between G1 component and G2 component” instead of the G2 component. Alternatively, the G1 component and the G2 component may be woven in a column unit or a row unit like a fabric to form one component. The pixel rearrangement processing unit 22 sequentially outputs the components thus classified and arranged to the image compression unit 16.

[Description of Operation of Image Compressing Unit 16] FIG. 5 is a diagram showing a processing procedure of the image compressing unit 16. The operation of the image compression unit 16 will be described below according to the processing procedure shown in FIG.

(1) The component size is different between the tiled normal compression mode (Y, Cb, Cr) and the RAW compression mode (R, B, G1, G2). Therefore, in order to efficiently share the subsequent processing procedure, the image compression unit 16 divides each component into a predetermined data processing unit and obtains a plurality of tiles (rectangular areas). The tiles thus divided are treated independently in the subsequent processing.

(2) Wavelet Transform First, the image compressing section 16 recursively performs a discrete wavelet transform (frequency decomposition) for each tile to obtain sub-band decomposed transform coefficients.

(3) Quantization Next, the image compression unit 16 quantizes the transform coefficient thus obtained with a predetermined quantization width for each subband. This quantization width determines the best limit of compression distortion. It should be noted that this quantization step width is set to "1" when completely lossless compression is realized in the RAW compression mode.

(4) Entropy coding If the selected area (ROI) to be coded preferentially is defined here, the image compression unit 16 is positioned in the selected area within the quantized transform coefficients. What is done is shifted up by S bits. The S bits are the number of bits determined by the max shift method. RA
This shift-up process is meaningless when completely reversible compression is realized in the W compression mode, and may be omitted if there is no special circumstance. Then, the image compression unit 16 classifies the transform coefficients into bit units to form a plurality of bit planes. At this stage, by cutting off the lower N planes, the quantization step width “2 of N
Quantization of “square” may be performed. The image compression unit 16 executes the following encoding pass on these bit planes in order from the highest plane. Note that these coding passes are defined in JPEG2000. SP pass (Significance propagation pass) MR pass (Magnitude refinement pass) Cleanup pass (Cleanup pass) By passing through such three encoding passes,
The transform coefficients are entropy coded.

(5) Arithmetic Coding Next, the image compression section 16 performs arithmetic coding on the entropy-coded coded data using the MQ coder which is a binary arithmetic code.

(6) Bitstream Generation Subsequently, the image compression section 16 rearranges the arithmetically encoded coded data in accordance with SNR progressive or other priorities to generate a bitstream. Here, in the case of the normal compression mode, the image compression unit 16 cuts off this bit stream midway and adjusts the file size after compression within the target range. On the other hand, in the RAW compression mode, the image compression unit 16 does not cut off the bitstream and suppresses the compression distortion within the target range. (Note that the compression loss is zero with perfect lossless compression.)

(7) The header-added image compression section 16 combines the generated bitstreams into one, adds a file header, and generates a compressed file. In the RAW compression mode, the image compression unit 1
Reference numeral 6 adds a code indicating that interpolation processing is not performed to the compressed file. The compressed file is completed through such processing procedure. The recording unit 17 records the compressed file on a recording medium such as a memory card.

<< Effects of this Embodiment >> As described above, the switching between the normal compression mode and the RAW compression mode is realized by bypassing the interpolation processing section 20. On the other hand, the image compression unit 16 executes a common processing procedure regardless of the compression mode. Therefore, in the present embodiment, there is almost no need to provide a plurality of image compression units for each compression mode or to switch the signal path inside the image compression unit 16 in a complicated manner. As a result, the switching between the normal compression mode and the RAW compression mode is extremely easily realized with a simple configuration and operation.

Further, in this embodiment, in the RAW compression mode, the signal components of the RAW data are classified by type to generate a plurality of components. On the other hand, even in the normal compression mode, a plurality of components are generated through interpolation processing and color coordinate conversion. Thus, even if the compression mode is switched, the output of the signal processing unit 15 is common in that it is a component output. In this way, the signal processing unit 15
By adjusting to the component output in (1), the common processing procedure can be easily implemented on the image compression unit 16 side.

<< Supplementary Items of Embodiment >> In the above-described embodiment, the case where the present invention is applied to the electronic camera 11 is described. However, the present invention is not limited to this. For example, the present invention may be realized as a single image processing device.

The image processing apparatus of the present invention may be realized by a computer. In this case, the operation of the image processing apparatus described above may be program coded to create an image processing program.

In the above embodiment, the Bayer array RAW data is handled. However, the present invention is not limited to this. In general, RAW data is image data before being subjected to interpolation processing, and refers to data in which a plurality of types of signal components (color, luminance, color difference, etc.) are mixedly arranged on a pixel array. Therefore, in the present invention, it is possible to handle RAW data in general, such as RAW data having a complementary color array, RAW data having a color array of a specific color system, and RAW data of a two-plate imaging device.

In the above embodiment, JPEG2
000-compliant image compression method is adopted. However, the present invention is not limited to this. In general, any compression method that can handle lossless compression (including pseudo lossless compression) and lossy compression in a common processing procedure may be used.

In the above-described embodiment, the pixel rearrangement of RAW data is performed in the RAW compression mode (see FIG. 4).
Is running. However, the present invention is not limited to this. For example, the pixel rearrangement in the RAW compression mode may be omitted.

[0045]

According to the present invention, the signal path switching in the normal compression mode / RAW compression mode is almost completed at the processing stage of the signal processing unit. On the other hand, the image compression unit
They are unified regardless of the difference in these compression modes. With such a configuration, it is not necessary to provide a plurality of image compression units for each compression mode or to switch signal paths in the image compression unit in a complicated manner. As a result, it becomes possible to easily switch the compression mode with a simple configuration and operation.

[Brief description of drawings]

FIG. 1 is a diagram showing an electronic camera 11 (including an image processing device) of the present embodiment.

FIG. 2 is a diagram illustrating an interpolation process in a normal compression mode.

FIG. 3 is a diagram illustrating color coordinate conversion in a normal compression mode.

FIG. 4 is a diagram illustrating pixel rearrangement in a RAW compression mode.

5 is a diagram showing a processing procedure of the image compression unit 16. FIG.

[Explanation of symbols]

11 electronic camera 12 Shooting lens 13 Image sensor 14 A / D converter 15 Signal processing unit 16 Image compression unit 17 Recording section 18 Mode setting section 19 Route switching unit 20 Interpolation processing unit 21 Color coordinate converter 22 Pixel rearrangement processing unit

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 5C059 LB15 MA23 MC11 ME11 PP15                       PP16 SS15 UA15                 5C078 BA57 CA02 CA26 DA01 DA22                       DB16                 5J064 AA04 BA16 BB04 BC06 BC08                       BC14 BC16 BC29 BD01

Claims (8)

[Claims] 1. An image processing apparatus which receives RAW data in which a plurality of types of signal components forming a color image are mixedly arranged on a pixel array and which processes the RAW data, and which receives an instruction input from the outside. Depending on the normal compression mode / RAW
A mode setting unit for switching the compression mode, and in the normal compression mode, the RAW data is interpolated to compensate for the signal component missing in pixel units.
In the AW compression mode, a signal processing unit that bypasses the interpolation process and an image compression unit that compresses the output of the signal processing unit are provided, and the RAW compression mode is realized by bypassing at least the interpolation process. Image processing device. 2. The image processing apparatus according to claim 1, wherein the signal processing unit is configured to perform the R conversion in the RAW compression mode.
An image processing apparatus, which classifies AW data according to the type of the signal component and outputs the AW data. 3. The image processing apparatus according to claim 1, wherein the signal processing unit outputs an image signal in a state of color coordinate conversion in the normal compression mode. The image processing apparatus, wherein the color coordinate conversion is bypassed in the RAW compression mode. 4. The image processing apparatus according to claim 1, wherein the image compression unit causes a compression distortion of image compression in the RAW compression mode as compared with that in the normal compression mode. An image processing device characterized by being lowered. 5. The image processing apparatus according to claim 1, wherein the image compression unit adjusts a file size after compression within a target range in the normal compression mode. The image processing apparatus, wherein the compression distortion is adjusted within a target range in the RAW compression mode. 6. The image processing apparatus according to claim 1, wherein the image compression unit does not perform an interpolation process on the image compression data in the RAW compression mode. An image processing apparatus characterized by adding a code indicating that. 7. An image pickup unit for picking up a subject image and generating RAW data in which a plurality of types of signal components forming a color image are mixedly arranged on a pixel array, and the image pickup unit according to claim 1. 2. An electronic camera, comprising: the image processing device according to claim 1; wherein RAW data generated by the imaging unit is processed by the image processing device. 8. An image processing program for causing a computer to function as the mode setting unit, the signal processing unit, and the image compression unit according to claim 1. Description: