This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2007-143116 filed May 30, 2007.
The present invention relates to an image processing apparatus and a computer readable medium storing a program therefor.
According to an aspect of the invention, an image processing apparatus includes a reference-based coding unit that encodes image information for an image partition having a predefined size by referring to image information for another image partition; an independently coding unit that encodes the image information for the image partition independently of any other image partition; and a bounds defining unit that defines bounds of reference to be made by the reference-based coding unit.
An exemplary embodiment of the present invention will be described in detail based on the following figures, wherein:
An overview of an image forming system is described for an exemplary embodiment of the present invention.
As illustrated in
The image processing apparatus 2 is a computer. The image processing apparatus 2 in this example is connected to a network such as LAN. The image processing apparatus 2 performs image processing on image information received from a user terminal 92 or a scanner 94 and sends the processed image information to the printer 3. An example of image processing discussed in this exemplary embodiment is rotating an image input to the processing apparatus (input image) by 180 degrees.
The printer 3 is an example of an image forming apparatus. The printer 3 in this example receives image information from the image processing apparatus 2 via the network such as LAN and prints an image on printing paper based on the received image information.
Alternatively, the image processing apparatus 2 may be provided within the housing of the printer 3.
As illustrated in
As illustrated in
Some or all of the functions of the image coding program 4 and the image editing program 5 are, for example, recorded on a storage medium 20 (
In the image coding program 4, the block segmentation part 40 segments an image of input image information into image partitions (blocks), each partition (block) containing plural pixels.
For example, the block segmentation part 40 segments an input image into rectangular image blocks, each made up of N×M pixels.
The block coding part 42 encodes the values of pixels contained in an image partition to be coded (target block) by referring to another image partition (block) within the bounds of reference defined by the reference count controller 44. More specifically, if reference to another block is permitted by the reference count controller 44, the block coding part 42 compares the values of the pixels contained in the target block with the values of the pixels contained in an image partition (reference block) in a pre-specified position with respect to the target block. When there is a predetermined relation between the respective values of the pixels of both blocks, the block coding part 42 generates a code including information to identify this reference block (information for the block referred to) (coding by a reference-based coding unit). When there is not such a predetermined relation therebetween, the block coding part 42 encodes the values of the pixels contained in the target block independently within the block (coding by an independently coding unit). If reference to another block is inhibited by the reference count controller 44, the block coding part 42 simply encodes the values of the pixels within the target block.
The block coding part 42 in this example, if the reference count controller 44 permits reference in the slow-scanning direction, compares the values of plural pixels contained in the target block with values of plural pixels contained in a block (one upper block) existing upstream of the target block in the slow-scanning direction, as illustrated in
The reference count controller 44 defines the bounds of reference to be made by the block coding part 42. Here, the bounds of reference are the bounds within which an image segment (block) is directly or indirectly referred to. If a segment (block) referred to further makes reference to another image segment, the bounds of reference cover this other image segment. For example, as illustrated in
The reference count controller 44 in this example counts the number of times the target block has referred to another block directly or indirectly (reference count). It permits or inhibits reference for encoding the target block, so that the reference count will be less than an upper limit value C.
The code output part 46 outputs image information encoded by the block coding part 42 to the image editing program 5.
In the image editing program 5, the code editing part 50 manipulates the encoded image information in units of image partitions (blocks). Because the values of plural pixels exist in an image partition, the code editing part 50 manipulates code strings included in code data, wherein each code string corresponds to the values of plural pixels in a block. In the description of the present exemplary embodiment, a set of codes corresponding to the values of all pixels contained in an image partition is termed a code string and a set of codes corresponding to a whole image is termed code data.
The code editing part 50 in this example, when instructed to edit the image, buffers the code strings of blocks into the code storage area 52, as appropriate for edit processing specifics given in the instruction, and performs manipulation such as reordering the code strings buffered, deleting any string(s), or adding a string(s), utilizing the code storage area 52.
The code editing part 50 also interchanges the code strings, as appropriate for the manipulation such as reordering the code strings stored, deleting any string(s), or adding a string(s).
The code storage area 52 is a data buffer for storing code strings that are manipulated by the code editing part 50. Size of the code storage area 52 is large enough to store code strings within the bounds of reference permitted by the reference count controller 44.
The code storage area 52 in this example has a storage space whose size is determined by C (upper limit of reference count)×N (integer).
The decoding part 54 decodes the code data input from the code editing part 50 and outputs decoded image data to the pixel editing part 56. Since the code strings have been interchanged appropriately in the code data manipulated (such as reordering, deletion, etc.) by the code editing part 50, they can be decoded even if the order of the code strings has been changed.
The pixel editing part 56 buffers the image data decoded by the decoding part 54 into the pixel value storage area 58 and manipulates the pixels in the image data buffered, utilizing the pixel value storage area 58.
The pixel editing part 56 in this example reorders the values of the pixels decoded, deletes any pixel value(s), or adds a pixel value (s), as appropriate for the edit processing specifics (such as an angle of rotation, shift amount, and direction).
The pixel value storage area 58 is a data buffer for storing the values of the pixels that are manipulated by the pixel editing part 56.
The pixel value storage area 58 in this example has a storage space whose size is determined by 2×N (pixels on one fast-scan line).
When instructed to rotate the image by 180 degree as an edit operation, the code editing part 50 (
Then, the decoding part 54 decodes the code strings which have been input sequentially from the code editing part 50 and outputs a set of decoded values of pixels to the pixel editing part 56.
The pixel editing part 56 reorders the values of pixels input from the decoding part 54 pixel by pixel in the fast-scanning direction. More specifically, the pixel editing part 56 buffers the values of pixels as many as contained in one image partition (four pixels in this example) input from the decoding part 54 into the pixel value storage area 58 (line buffer) and reads these values from the line buffer in reverse order to the order in which the values have been buffered, as illustrated in
As described above, processing for image rotation by 180 degrees is carried out by combination of rotation by 180 degrees at the level of image partitions (processing on codes) and rotation by 180 degrees at the level of pixels (processing on the values of pixels).
The code strings in
Thus, the code editing part 50 in this example interchanges the code strings, as illustrated in
[Modification 1]
An example of modification to the above-described exemplary embodiment is then described.
As illustrated in
Then, as illustrated in
In the present modification, one fast-scan line is assumed as one block and every whole line is encoded. Alternatively, the code strings of blocks illustrated in
[Modification 2]
In the above-described exemplary embodiment, only if there is a complete match between a block that refers to another block and the block referred to, block coding with a referral code is applied; however, this is not restrictive.
In the second modification, after comparing the target block and the reference block, if differences therebetween meet a predetermined condition, information to identify the block referred to and information to specify the differences are encoded in a referral code.
Given that, for example, as illustrated in
The referral code may be composed of a header indicating the number of mismatched pixels, pixel positions indicating the positions of mismatched pixels, and mismatched pixel values, as illustrated in
[Modification 3]
In the above-described exemplary embodiment, a block is defined to have a one-pixel dimension in the slow-scanning direction; however, this is not restrictive. A block may be defined to have a two-pixel dimension in the slow-scanning direction, for example, as illustrated in
Processing to rotate the image by 180 degrees in this case is such that the code editing part 50 simply reorders these blocks in the slow-scanning direction in the same way as explained in the foregoing exemplary embodiment. Then, the pixel editing part 56 buffers the values of pixels in a block into a block line buffer as illustrated in
[Modification 4]
Sometimes, an input image which is illustrated in
In the fourth modification, processing that is performed at the block level includes at least one of the following: shifting pixels, adding margin portions, and removing out-of-frame portions. Then, processing such as shifting pixels is performed at the pixel level.
In the following, an instance where an image is shifted by five pixels toward a minus direction in the fast-scanning direction is discussed with reference to
The code editing part 50 determines an image range to be deleted, based on the shift amount and the shift direction for requested shift processing. It then determines whether a block referred to (a block referred to by another block) exists in the determined range that needs to be deleted. If a block referred to exists in the range that needs to be deleted, the code editing part 50 interchanges the code (referral code) of the block that refers to with the code (independently encoded code) of the block referred to, as illustrated in
Then, the code editing part 50 performs shift processing at the block level, as illustrated in
Next, the decoding part 54 sequentially decodes the code strings which are input in order from the code editing part 50 and outputs a set of decoded values of pixels to the pixel editing part 56. A marginal code is decoded to values of pixels corresponding to a margin.
Then, the pixel editing part 56 performs a pixel-level shift of the values of pixels input from the decoding part 54 by the remaining amount of shift.
Specifically, for the values of pixels input from the decoding part 54, the pixel editing part 56 cuts the first pixel on each fast-scan line as an out-of-frame pixel and inserts a margin pixel after the last block on each fast-scan line, as illustrated in
As explained above, desired shift processing is accomplished by combination of shift processing at the image partition level (processing on codes) and shift processing at the pixel level (processing on pixels).
While processing for a shift in the minus direction has been discussed for illustrative purposes in this example, processing for a shift in a plus direction can be accomplished in the same way, depending on a reference direction by referral code, symmetry, and the like.
The present invention may be embodied in other specific forms without departing from its spirit or characteristics. The described exemplary embodiments are to be considered in all respects only as illustrated and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
Number | Date | Country | Kind |
---|---|---|---|
2007-143116 | May 2007 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5911008 | Niikura et al. | Jun 1999 | A |
5995080 | Biro et al. | Nov 1999 | A |
6005980 | Eifrig et al. | Dec 1999 | A |
6014181 | Sun | Jan 2000 | A |
Number | Date | Country |
---|---|---|
A 09-074475 | Mar 1997 | JP |
A-11-027664 | Jan 1999 | JP |
A-2005-223538 | Aug 2005 | JP |
Number | Date | Country | |
---|---|---|---|
20080298681 A1 | Dec 2008 | US |