JP2004056648A - Image processor, document management system, program, and storage medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a document management system capable of distributing data storage regions. <P>SOLUTION: A server computer 2 extracts compressed code corresponding to a low resolution image according to arbitrary hierarchy, transmits the compressed code corresponding to the extracted low resolution image to a client computer via a network, and stores compressed code corresponding to a high resolution image, where the compressed code corresponding to the low resolution image according to arbitrary hierarchy is removed from all compressed codes, in a storage section 15. On the other hand, the client computer 4 receives the compressed code corresponding to the low resolution image according to any class, which is transmitted from the server computer 2 via the network, and stores the received compressed code corresponding to the low resolution image in the storage section 15. Thus, the data storage regions can be distributed. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image processing device, a document management system, a program, and a storage medium.
[0002]
[Prior art]
Conventionally, in a file server or a document management system of a server client model, image data is collectively stored on a server computer side, and the client computer accesses the server computer as needed to retrieve and display desired image data. And so on. In this case, the client computer takes the image data stored in the server computer, performs image reduction processing and the like on the client computer, and displays the image data on a display device such as a CRT (Cathode Ray Tube) or an LCD (Liquid Crystal Display). Is a common practice.
[0003]
[Problems to be solved by the invention]
However, in such a case, network traffic occurs due to the receipt of image data from the server computer to the client computer, and processing time is required according to the transfer amount.
[0004]
Therefore, in order to reduce such network traffic, the server computer stores a main image and a display-only image (thumbnail image) obtained by reducing the main image, and transfers the thumbnail image first for list display. is there.
[0005]
However, according to such a method, since the server computer needs to store the thumbnail image separately from the main body image in the storage unit, there is a problem that the use amount of the data storage area of the storage unit increases. .
[0006]
An object of the present invention is to provide an image processing apparatus, a document management system, a program, and a storage medium that can distribute data storage areas.
[0007]
An object of the present invention is to provide an image processing apparatus, a document management system, a program, and a storage medium that can reduce network traffic.
[0008]
[Means for Solving the Problems]
The image processing apparatus according to the first aspect of the present invention provides a compression code for a low-resolution image corresponding to an arbitrary layer from a compression code obtained by performing discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically. A low-resolution image data extracting means for extracting the low-resolution image data extracted by the low-resolution image data extracting means; a low-resolution image data transmitting means for transmitting a compression code relating to the low-resolution image extracted by the low-resolution image data extracting means to another image processing apparatus; High-resolution image data storage means for storing, in a storage unit, a compression code for a high-resolution image obtained by removing a compression code for a low-resolution image corresponding to an arbitrary hierarchy from a code.
[0009]
Therefore, a compression code related to the low-resolution image corresponding to an arbitrary layer is extracted, and the compression code related to the extracted low-resolution image is transmitted to another image processing apparatus. The compression code related to the high-resolution image excluding the compression code related to the low-resolution image corresponding to. Accordingly, if the compression codes related to the low-resolution image are stored in the storage unit of another image processing apparatus, the data storage area can be dispersed.
[0010]
The image processing apparatus according to the second aspect of the present invention provides a low-resolution image corresponding to an arbitrary layer extracted from a compression code obtained by performing discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically. A low-resolution image data receiving unit that receives the compression code from another image processing apparatus; and a low-resolution image data storage unit that stores the compression code of the low-resolution image received by the low-resolution image data reception unit in a storage unit. , Is provided.
[0011]
Therefore, the compression code related to the low-resolution image corresponding to an arbitrary layer transmitted from another image processing apparatus is received, and the compression code related to the received low-resolution image is stored in the storage unit. With this configuration, the storage unit of the other image processing apparatus stores the compression code of the high-resolution image obtained by removing the compression code of the low-resolution image corresponding to an arbitrary hierarchy from all the compression codes, thereby providing a data storage area. Can be dispersed.
[0012]
According to a third aspect of the present invention, there is provided a document management system according to the present invention, wherein a compression code for a low-resolution image corresponding to an arbitrary layer is obtained from a compression code obtained by performing discrete wavelet transform of pixel values for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically. A low-resolution image data extracting means for extracting the low-resolution image data, a low-resolution image data transmitting means for transmitting a compression code relating to the low-resolution image extracted by the low-resolution image data extraction means via a network, A high-resolution image data storage means for storing a compression code related to a high-resolution image in a storage unit excluding a compression code related to a low-resolution image corresponding to a hierarchy, and a server computer having the same via the network. Low-resolution image data connected and receiving a compression code related to the low-resolution image transmitted from the server computer Comprising a signal means, a low-resolution image data storage means for storing compression codes relating to low resolution image received in the storage unit by the low resolution image data receiving means, and a client computer having a a.
[0013]
Therefore, on the server computer side, a compressed code related to the low-resolution image corresponding to an arbitrary layer is extracted, and the compressed code related to the extracted low-resolution image is transmitted to the client computer via the network, A compression code for a high-resolution image obtained by removing a compression code for a low-resolution image corresponding to an arbitrary hierarchy from all the compression codes is stored in the storage unit. On the other hand, on the client computer side, a compression code related to the low-resolution image corresponding to an arbitrary layer transmitted from the server computer via the network is received, and the compression code related to the received low-resolution image is stored in the storage unit. Is done. As a result, the compression code of the high-resolution image obtained by removing the compression code of the low-resolution image corresponding to an arbitrary hierarchy from the entire compression code is stored in the storage unit of the server computer, and the low-resolution image is stored in the storage unit of the client computer. Since such compression codes are stored, the data storage area can be dispersed.
[0014]
According to a fourth aspect of the present invention, in the document management system according to the third aspect, when a low-resolution image is displayed on the client computer side, a compression code relating to the low-resolution image stored in the client computer is used. When decoding and displaying, and displaying a high-resolution image on the client computer side, a compression code for a high-resolution image associated with a compression code for a desired low-resolution image stored in the client computer Is acquired from the server computer, and the compressed code related to the low-resolution image and the compressed code related to the high-resolution image are merged and decoded, and then displayed.
[0015]
Therefore, when a low-resolution display such as a thumbnail display is sufficient, a compression code relating to a desired low-resolution image stored in the client computer is decoded and displayed. On the other hand, when a part is displayed at a high resolution such as an enlarged display, a compression code related to a high resolution image stored in a server computer is obtained, and a compression code related to a desired low resolution image stored in a client computer is obtained. The result of merging with the compression code is decoded and displayed. As a result, when displaying a low-resolution image on the client computer side, the load on the client computer side is reduced, and network traffic when displaying a high-resolution image on the client computer side is reduced.
[0016]
According to a fifth aspect of the present invention, in the document management system according to the third aspect, when a low-resolution image is printed on the client computer side, a compression code relating to the low-resolution image stored in the client computer is used. When decoding and printing, and printing a high-resolution image on the client computer side, the compression code for the high-resolution image associated with the compression code for the desired low-resolution image stored in the client computer Is acquired from the server computer, and the compressed code related to the low-resolution image and the compressed code related to the high-resolution image are merged and decoded, and then printed.
[0017]
Therefore, when low-resolution printing is sufficient, a compression code relating to a desired low-resolution image stored in the client computer is decoded and printed. On the other hand, when printing at high resolution, a compression code related to the high resolution image stored in the server computer is obtained, and the result of merging with the compression code related to the desired low resolution image stored in the client computer is decoded. And printed. As a result, when printing a low-resolution image on the client computer side, the load on the client computer side is reduced, and network traffic when printing a high-resolution image on the client computer side is reduced.
[0018]
According to a sixth aspect of the present invention, in the document management system according to the third aspect, when a high-resolution image is printed on the server computer side according to an instruction from the client computer, the client computer sends the high-resolution image to the server computer. Transmitting the compression code relating to the desired low-resolution image, and storing the compression code relating to the desired low-resolution image obtained from the client computer and the server computer associated with the compression code relating to the low-resolution image. Then, after merging with the compression code related to the high-resolution image and decoding, it is printed.
[0019]
Therefore, when printing a high-resolution image on the server computer side according to an instruction from the client computer, a compression code relating to the low-resolution image is transmitted from the client computer to the server computer, and the high-resolution image stored in the server computer is transmitted. The result of merging with the compression code related to the resolution image is decoded and printed. This enables high-resolution image printing on the server computer in accordance with an instruction from the client computer, and also allows the compression code for the low-resolution image stored in the client computer to have the meaning of a print key. become.
[0020]
According to a seventh aspect of the present invention, in the document management system according to the third aspect, when data conversion processing is performed on the server computer side based on a high-resolution image in accordance with an instruction from the client computer, the data is transmitted from the client computer. A compression code relating to a desired low-resolution image is transmitted to the server computer, and the compression code relating to the desired low-resolution image acquired from the client computer and the server associated with the compression code relating to the low-resolution image The data conversion process is performed after merging and decoding the compressed code related to the high-resolution image stored in the computer.
[0021]
Therefore, when performing data conversion processing based on a high-resolution image on the server computer side according to an instruction from the client computer, a compression code relating to the low-resolution image is transmitted from the client computer to the server computer. Is decoded and the result of the data conversion is executed. This enables the server computer to execute the data conversion processing based on the high-resolution image in accordance with an instruction from the client computer, and also converts the data conversion processing key into the compression code for the low-resolution image stored in the client computer. Can be given the meaning.
[0022]
According to a eighth aspect of the present invention, there is provided a document management system according to the present invention, wherein a compression code for a low-resolution image corresponding to an arbitrary layer is obtained from a compression code obtained by performing discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically. , A low-resolution image data transmitting unit that transmits a compression code relating to the low-resolution image extracted by the low-resolution image data extraction unit via a network, and a storage unit that stores all compression codes. And a low-resolution image data receiving device connected to the server computer via the network and receiving a compression code related to the low-resolution image transmitted from the server computer. Means for storing a compression code relating to the low-resolution image received by the low-resolution image data receiving means. Comprising a low-resolution image data storage means for storing, and a client computer having a, to.
[0023]
Therefore, on the server computer side, a compressed code related to the low-resolution image corresponding to an arbitrary layer is extracted, and the compressed code related to the extracted low-resolution image is transmitted to the client computer via the network, All compression codes are stored in the storage unit. On the other hand, on the client computer side, a compression code related to the low-resolution image corresponding to an arbitrary layer transmitted from the server computer via the network is received, and the compression code related to the received low-resolution image is stored in the storage unit. Is done. As a result, all the compression codes are stored in the storage unit of the server computer, and the compression codes related to the low-resolution image are stored in the storage unit of the client computer. Can be reduced.
[0024]
According to a ninth aspect of the present invention, in the document management system according to the eighth aspect, when a high-resolution image is printed on the server computer side according to an instruction from the client computer, the client computer sends the high-resolution image to the server computer. Transmitting an identification number associated with the compression code relating to the desired low-resolution image, obtaining an identification number associated with the compression code relating to the desired low-resolution image from the client computer, and storing the identification number in the server computer. Is printed after decoding all the compression codes associated with the identification number.
[0025]
Therefore, when printing a high-resolution image on the server computer side according to an instruction from the client computer, an identification number associated with a compression code related to a desired low-resolution image is transmitted from the client computer to the server computer, All the compression codes associated with the identification number stored in the server computer are decoded and printed. Accordingly, high-resolution image printing can be performed on the server computer side in accordance with an instruction from the client computer, and network traffic can be reduced because the image data itself does not flow.
[0026]
According to a tenth aspect of the present invention, in the document management system according to the eighth aspect, when the server computer performs a data conversion process based on a high-resolution image, the client computer requests the server computer to execute the data conversion process. Transmitting an identification number associated with the compression code related to the low-resolution image of the low-resolution image, obtaining an identification number associated with the compression code related to the desired low-resolution image from the client computer, and After decoding all compression codes associated with the identification numbers, data conversion processing is performed.
[0027]
Therefore, when performing data conversion processing based on a high-resolution image on the server computer side according to an instruction from the client computer, the client computer associates the server computer with the compression code associated with the desired low-resolution image. The identification number is transmitted, all the compression codes stored in the server computer and associated with the identification number are decoded, and the data conversion process is performed. This enables the server computer to execute a data conversion process based on a high-resolution image in accordance with an instruction from the client computer, and to reduce network traffic because the image data itself does not flow. Become.
[0028]
The program according to claim 11 extracts a compressed code related to a low-resolution image corresponding to an arbitrary layer from a compressed code obtained by performing discrete wavelet transform of pixel values for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically. And causing the computer to execute a low-resolution image data extracting function for transmitting a compression code relating to the low-resolution image extracted by the low-resolution image data extracting function via a network.
[0029]
Therefore, by causing the computer to read this program, a compression code related to the low-resolution image corresponding to an arbitrary hierarchy is extracted, and the compression code related to the extracted low-resolution image is transmitted to another image processing apparatus. At the same time, a compression code related to a high-resolution image obtained by removing a compression code related to a low-resolution image corresponding to an arbitrary hierarchy from all compression codes is stored in a storage unit. Accordingly, if the compression codes related to the low-resolution image are stored in the storage unit of another image processing apparatus, the data storage area can be dispersed.
[0030]
According to a twelfth aspect of the present invention, there is provided a program for compressing a low-resolution image corresponding to an arbitrary layer extracted from a compression code obtained by performing discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically. A low-resolution image data receiving function of receiving a code via a network, and a low-resolution image data storing function of storing a compressed code related to the low-resolution image received by the low-resolution image data receiving function in a storage unit; Let it run.
[0031]
Therefore, by causing the computer to read this program, a compression code related to a low-resolution image corresponding to an arbitrary layer transmitted from another image processing apparatus is received, and the compression code related to the received low-resolution image is stored. It is stored in the section. With this configuration, the storage unit of the other image processing apparatus stores the compression code of the high-resolution image obtained by removing the compression code of the low-resolution image corresponding to an arbitrary hierarchy from all the compression codes, thereby providing a data storage area. Can be dispersed.
[0032]
A computer-readable storage medium according to claim 13, wherein a low-resolution image corresponding to an arbitrary layer is obtained from a compression code obtained by performing discrete wavelet transform of pixel values for each of tiles obtained by dividing an image and hierarchically encoding the pixel values. A low-resolution image data extraction function for extracting a compression code according to the present invention, and a low-resolution image data transmission function for transmitting a compression code for the low-resolution image extracted by the low-resolution image data extraction function via a network. Is stored.
[0033]
Therefore, by causing a computer to read the program stored in the storage medium, a compression code relating to a low-resolution image corresponding to an arbitrary hierarchy is extracted, and the compression code relating to the extracted low-resolution image is subjected to another image processing. While being transmitted to the device, a compression code related to a high resolution image obtained by removing a compression code related to a low resolution image corresponding to an arbitrary layer from all compression codes is stored in a storage unit. Accordingly, if the compression codes related to the low-resolution image are stored in the storage unit of another image processing apparatus, the data storage area can be dispersed.
[0034]
According to a fourteenth aspect of the present invention, there is provided a computer-readable storage medium according to an arbitrary layer extracted from a compression code obtained by performing a discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and hierarchically encoding the image. A low-resolution image data receiving function for receiving a compression code relating to the low-resolution image via a network, and a low-resolution image data storage for storing the compression code relating to the low-resolution image received by the low-resolution image data receiving function in a storage unit A function and a program for causing a computer to execute the function are stored.
[0035]
Therefore, by causing a computer to read the program stored in the storage medium, a compression code related to a low-resolution image corresponding to an arbitrary layer transmitted from another image processing apparatus is received, and the received low-resolution image Is stored in the storage unit. With this configuration, the storage unit of the other image processing apparatus stores the compression code of the high-resolution image obtained by removing the compression code of the low-resolution image corresponding to an arbitrary hierarchy from all the compression codes, thereby providing a data storage area. Can be dispersed.
[0036]
BEST MODE FOR CARRYING OUT THE INVENTION
First, the outlines of the “hierarchical coding algorithm” and the “JPEG2000 algorithm” which are the premise of the embodiment of the present invention will be described.
[0037]
FIG. 1 is a functional block diagram of a system for realizing a hierarchical coding algorithm which is a basic of the JPEG2000 system. This system includes a color space conversion / inverse transformation unit 101, a two-dimensional wavelet transformation / inverse transformation unit 102, a quantization / inverse quantization unit 103, an entropy coding / decoding unit 104, and a tag processing unit 105. It is configured.
[0038]
One of the biggest differences between this system and the conventional JPEG algorithm is the conversion method. In JPEG, discrete cosine transform (DCT: Discrete Cosine Transform) is used, whereas in this hierarchical encoding algorithm, discrete wavelet transform (DWT: Discrete Wavelet Transform) is used in the two-dimensional wavelet transform / inverse transform unit 102. ing. DWT has an advantage that the image quality in a high compression area is better than DCT, and this is one of the main reasons why DWT was adopted in JPEG2000 which is a successor algorithm of JPEG.
[0039]
Another major difference is that in the hierarchical coding algorithm, a functional block of the tag processing unit 105 is added in order to form a code at the last stage of the system. The tag processing unit 105 generates compressed data as code string data at the time of image compression operation, and interprets code string data required for decompression at the time of decompression operation. The JPEG2000 can realize various convenient functions by using the code string data. For example, the compression / expansion operation of a still image can be freely stopped at an arbitrary layer (decomposition level) corresponding to octave division in a DWT on a block basis (see FIG. 3 described later). Further, a low-resolution image (reduced image) can be extracted from one file, or a part of the image (tiling image) can be extracted.
[0040]
In many cases, a color space conversion / inverse conversion 101 is connected to the input / output portion of the original image. For example, an RGB color system composed of R (red) / G (green) / B (blue) components of a primary color system, and Y (yellow) / M (magenta) / C (cyan) components of a complementary color system The conversion or inverse conversion from the YMC color system to the YUV or YCbCr color system corresponds to this.
[0041]
Next, the JPEG2000 algorithm will be described.
[0042]
Generally, in a color image, as shown in FIG. 2, each component 111 (here, the RGB primary color system) of the original image is divided by a rectangular area. The divided rectangular area is generally called a block or a tile. In JPEG2000, it is generally called a tile. Hereinafter, such a divided rectangular area is referred to as a tile. (In the example of FIG. 2, each component 111 is divided into a total of 16 rectangular tiles 112, 4 × 4 vertically and horizontally.) When such individual tiles 112 (in the example of FIG. 2, R00, R01,..., R15 / G00, G01,..., G15 / B00, B01,. Is the basic unit of Therefore, the compression / decompression operation of the image data is performed independently for each component and for each tile 112.
[0043]
At the time of encoding image data, the data of each tile 112 of each component 111 is input to the color space conversion / inverse conversion unit 101 of FIG. 1 and subjected to color space conversion. A dimensional wavelet transform (forward transform) is performed, and spatial division into frequency bands is performed.
[0044]
FIG. 3 shows subbands at each decomposition level when the number of decomposition levels is three. That is, a two-dimensional wavelet transform is performed on the tile original image (0LL) (decomposition level 0) obtained by dividing the original image into tiles, and the subbands (1LL, 1HL, 1LH) indicated by the decomposition level 1 are obtained. , 1HH). Subsequently, two-dimensional wavelet transform is performed on the low-frequency component 1LL in this layer to separate the subbands (2LL, 2HL, 2LH, 2HH) shown in the decomposition level 2. Similarly, two-dimensional wavelet transform is performed on the low-frequency component 2LL in the same manner to separate the sub-bands (3LL, 3HL, 3LH, 3HH) shown in the decomposition level 3. In FIG. 3, the subbands to be coded at each decomposition level are shaded. For example, when the number of decomposition levels is 3, the subbands (3HL, 3LH, 3HH, 2HL, 2LH, 2HH, 1HL, 1LH, 1HH) indicated by shading are to be encoded, and the 3LL subbands are encoded. Is not converted.
[0045]
Next, bits to be encoded are determined in the designated order of encoding, and the quantization / inverse quantization unit 103 shown in FIG. 1 generates a context from bits around the target bits.
[0046]
The wavelet coefficients after the quantization process are divided into non-overlapping rectangles called “precincts” for each subband. This was introduced to make efficient use of memory in the implementation. As shown in FIG. 4, one precinct is formed of three spatially coincident rectangular areas. Further, each precinct is divided into non-overlapping rectangular "code blocks". This is a basic unit when performing entropy coding.
[0047]
The coefficient value after wavelet transform can be quantized and encoded as it is. However, in JPEG2000, in order to increase the encoding efficiency, the coefficient value is decomposed into “bit plane” units, and each pixel or code block is decomposed. "Bit planes" can be ranked.
[0048]
Here, FIG. 5 is an explanatory diagram showing an example of a procedure for prioritizing bit planes. As shown in FIG. 5, in this example, the original image (32 × 32 pixels) is divided into four 16 × 16 pixel tiles, and the size of the precinct of the decomposition level 1 and the size of the code block are as follows. Each has 8 × 8 pixels and 4 × 4 pixels. The numbers of precincts and code blocks are assigned in raster order. In this example, the precincts are assigned numbers 0 to 3, and the code blocks are assigned numbers 0 to 3. The pixel expansion outside the tile boundary is performed by using a mirroring method, performing a wavelet transform using a reversible (5, 3) filter, and obtaining a wavelet coefficient value of decomposition level 1.
[0049]
FIG. 5 also shows an explanatory diagram showing an example of a typical “layer” configuration concept of tile 0 / precinct 3 / code block 3. The converted code block is divided into subbands (1LL, 1HL, 1LH, 1HH), and each subband is assigned a wavelet coefficient value.
[0050]
The layer structure is easy to understand when the wavelet coefficient value is viewed from the horizontal direction (bit plane direction). One layer is composed of an arbitrary number of bit planes. In this example, layers 0, 1, 2, and 3 are made up of 1, 3, 1, and 3 bit planes, respectively. A layer including a bit plane closer to LSB (Least Significant Bit: Least Significant Bit) is subject to quantization first, and conversely, a layer closer to MSB (Most Significant Bit: Most Significant Bit) is quantized to the end. It will remain without being. A method of discarding from a layer close to the LSB is called truncation, and it is possible to finely control the quantization rate.
[0051]
The entropy encoding / decoding unit 104 shown in FIG. 1 performs encoding on the tile 112 of each component 111 by probability estimation from the context and the target bit. In this way, the encoding process is performed on all the components 111 of the original image in tile 112 units. Finally, the tag processing unit 105 performs a process of combining all the encoded data from the entropy encoding / decoding unit 104 into one piece of code string data and adding a tag thereto.
[0052]
FIG. 6 shows a schematic configuration of one frame of the code string data. At the head of the code string data and the head of the code data (bit stream) of each tile, tag information called a header (main header, tile part header as tile boundary position information, etc.) is provided. This is followed by coded data for each tile. Note that the main header (Main header) describes coding parameters and quantization parameters. Then, a tag (end of codestream) is placed again at the end of the code string data.
[0053]
On the other hand, when the encoded data is decoded, the image data is generated from the code string data of each tile 112 of each component 111, contrary to the encoding of the image data. In this case, the tag processing unit 105 interprets the tag information added to the code string data input from the outside, decomposes the code string data into code string data of each tile 112 of each component 111, and A decoding process (decompression process) is performed for each code string data of each tile 112. At this time, the positions of the bits to be decoded are determined in the order based on the tag information in the code string data, and the quantization / dequantization unit 103 sets the peripheral bits of the target bit position (the A context is generated from the sequence of (finished). The entropy coding / decoding unit 104 performs decoding by probability estimation from the context and the code string data, generates a target bit, and writes it to the position of the target bit. Since the data decoded in this way is spatially divided for each frequency band, the two-dimensional wavelet transform / inverse transform unit 102 performs an inverse two-dimensional wavelet transform on the data to obtain each component of the image data. The tile is restored. The restored data is converted by the color space conversion / inverse conversion unit 101 into the original color system image data.
[0054]
The above is the outline of the “JPEG2000 algorithm”.
[0055]
Hereinafter, a first embodiment of the present invention will be described. The image processing apparatus according to the present embodiment performs image processing by being operation-controlled by an image processing program installed on the computer or interpreted and executed. In the present embodiment, a storage medium that stores such an image processing program is also introduced.
[0056]
FIG. 7 is a schematic diagram illustrating a system configuration example according to the present embodiment.
[0057]
In the document management system according to the present embodiment, a server client system 1 in which a plurality of client computers 4 are connected to a server computer 2 via a network 3 such as a LAN (Local Area Network) is assumed. The server computer 2 and the client computer 4 implement the image processing device of the present embodiment. The server client system 1 is provided with an environment in which an image input device 5 such as a scanner or a digital camera and an image output device 6 such as a printer can be shared on a network 3. Further, an MFP 7 called a multifunction peripheral may be connected to the network 3, and an environment may be constructed such that the MFP 7 functions as the image input device 5 and the image output device 6.
[0058]
Such a server client system 1 is configured to be able to perform data communication with another server client system 1 via, for example, an intranet 8, and is configured to be able to perform data communication with an external environment via an Internet communication network 9.
[0059]
The server computer 2 includes a document management server 2a and a data conversion server 2b. The document management server 2a exhibits a document management function of storing various documents as image data. The data conversion server 2b performs a data conversion function such as performing OCR processing on image data to extract text data.
[0060]
FIG. 8 is a module configuration diagram of the server computer 2 and the client computer 4 as the image processing device according to the present embodiment.
[0061]
The server computer 2 and the client computer 4 include a CPU (Central Processing Unit) 11 for performing information processing, a ROM (Read Only Memory) 12 for storing information, a primary storage device 14 such as a RAM (Random Access Memory) 13, and a compression unit to be described later. A secondary storage device 16 such as an HDD (Hard Disk Drive) 15 as a storage unit for storing codes, and a removable device such as a CD-ROM drive for storing information, distributing information to the outside, and obtaining information from the outside. A disk interface 17, a network interface 18 for transmitting information by communication with another external computer via the network 3, a CRT (Cathode Ray Tube) for displaying the progress of processing, results, and the like to an operator And a display device 19 such as an LCD (Liquid Crystal Display), a keyboard 20 for an operator to input commands and information to the CPU 11, a pointing device 21 such as a mouse, and the like. The bus controller 22 arbitrates the received data and operates.
[0062]
In the server computer 2 and the client computer 4, when the user turns on the power, the CPU 11 activates a program called a loader in the ROM 12, and reads a program for managing the hardware and software of the computer called an operating system from the HDD 15 into the RAM 13. Start this operating system. Such an operating system starts a program, reads information, and saves information in response to a user operation. As typical operating systems, Windows (registered trademark), UNIX (registered trademark), and the like are known. The operation programs running on these operating systems are called application programs.
[0063]
Here, the server computer 2 and the client computer 4 store an image processing program in the HDD 15 as an application program. In this sense, the HDD 15 functions as a storage medium that stores the image processing program.
[0064]
Generally, an operation program installed in the secondary storage device 16 such as the HDD 15 of the server computer 2 and the client computer 4 includes an optical information recording medium such as a CD-ROM and a DVD-ROM, and a magnetic medium such as an FD. And the recorded operation program is installed in the secondary storage device 16 such as the HDD 15. Therefore, a portable storage medium such as an optical information recording medium such as a CD-ROM or a magnetic medium such as an FD can be a storage medium for storing the image processing program. Further, the image processing program may be fetched from outside via, for example, the network interface 18 and installed in the secondary storage device 16 such as the HDD 15.
[0065]
In the server computer 2 and the client computer 4, when the image processing program running on the operating system is started, the CPU 11 executes various arithmetic processes according to the image processing program to centrally control each unit. Among the various types of arithmetic processing executed by the CPU 11 of the server computer 2 or the CPU 11 of the client computer 4, the characteristic processing of the present embodiment will be described below.
[0066]
[Image storage processing]
FIG. 9 is a flowchart illustrating a flow of an image storage process executed by the server computer 2 and the client computer 4 which are image processing apparatuses according to the image processing program.
[0067]
The image storage process in the present embodiment is based on the premise that the server computer 2 has received an original image from the image input device 5 or the MFP 7 via the network interface 18 as shown in FIG. 9, for example. (Y in step S1). In this case, the original image is a digitized color image.
[0068]
Under such a premise, first, the received original image is compression-coded according to the “JPEG2000 algorithm” (step S2). That is, the image data of each of the R, G, and B components of the original image is divided into one or more (usually, a plurality) tiles, and the tiles are compression-encoded hierarchically. For the compression encoding of an image according to the “JPEG2000 algorithm”, the spatial transform / inverse transform unit 101, the two-dimensional wavelet transform / inverse transform unit 102, the quantization / inverse quantize unit 103, the entropy encoding shown in FIG. -Since the description of the decoding unit 104 and the tag processing unit 105 has been described above, the description here is omitted.
[0069]
Next, a compression code associated with the low-resolution image is extracted (step S3: low-resolution image data extraction means). FIG. 10 is an explanatory diagram showing a resolution model of a compression code generated according to the “JPEG2000 algorithm”. As shown in FIG. 10, in a compression code generated according to the “JPEG2000 algorithm”, low-resolution data and high-resolution data are separated in one image file. Therefore, in step S3, only the compression code related to the low-resolution image is extracted from the compression codes generated according to the “JPEG2000 algorithm”. In FIG. 10, only two types of resolutions are shown. However, if all data are set to 1, actually, 1/0 is set according to an arbitrary hierarchy (decomposition level) corresponding to octave division in the DWT. It is possible to extract compression codes related to a plurality of low resolution images, such as 2, 1/4, 1/8, and 1/16.
[0070]
Subsequently, the compression code relating to the low-resolution image thus extracted is transmitted to all the client computers 4 (step S4: low-resolution image data transmission means), and the compression code relating to the remaining high-resolution image is transmitted. Is stored in the HDD 15 of the server computer 2 (step S5: high-resolution image data storage means).
[0071]
In steps S4 and S5, the server computer 2 stores the compression code related to the low-resolution image to be transmitted to the client computer 4 and the HDD 15 of the server computer 2 by the document management function performed by the document management server 2a. An ID, which is an identification number for associating these with the compression codes related to the high-resolution images, is given.
[0072]
On the other hand, when the client computer 4 receives the compression code related to the low-resolution image (Y in step T1: low-resolution image data receiving unit), the client computer 4 stores the received compression code related to the low-resolution image in the HDD 15 of the client computer 4 ( Step T2: low-resolution image data storage means).
[0073]
That is, as shown in FIG. 11, a compression code related to a high-resolution image is stored in the HDD 15 of the server computer 2 and a compression code related to a low-resolution image is stored in the HDD 15 of the client computer 4. Therefore, conventionally, all the image data is stored on the server side, but by distributing and storing the image data in the client computer 4 and the server computer 2, it becomes possible to achieve a distribution of disk usage. I have.
[0074]
[Image Display Processing in Client Computer 4]
Next, the HDD 15 of the server computer 2 stores the compression code related to the high-resolution image, and the HDD 15 of the client computer 4 stores the compression code related to the low-resolution image (see FIG. 11). 4 will be described.
[0075]
FIG. 12 is a flowchart showing a flow of image display processing in the client computer 4 executed by the server computer 2 and the client computer 4 which are image processing apparatuses according to the image processing program.
[0076]
In the image display processing in the client computer 4 of the present embodiment, as shown in FIG. 12, an operator (a user who operates the client computer 4) desires to display a high-resolution image by operating the keyboard 20 or the pointing device 21. In this case (Y in step T11), the server computer 2 is requested to transmit a compression code related to the high-resolution image stored in the HDD 15 of the server computer 2 (step T12).
[0077]
When the server computer 2 receives the request signal for transmitting the compression code related to the high-resolution image (Y in step S11), the server computer 2 sends the compression request related to the high-resolution image stored in the HDD 15 of the server computer 2 to the client computer 4. The code is transmitted (step S12).
[0078]
When the client computer 4 acquires the compression code related to the high-resolution image stored in the HDD 15 of the server computer 2 (step T13), the compression code related to the acquired high-resolution image is stored in the HDD 15 of the client computer 4. The compression codes related to the low-resolution image are merged (step T14), and decompression processing (decoding processing) is executed (step T15). The expansion process (decoding process) of the compression code according to the “JPEG2000 algorithm” is performed by the spatial transform / inverse transform unit 101, the two-dimensional wavelet transform / inverse transform unit 102, and the quantization / inverse quantize unit shown in FIG. 103, the entropy encoding / decoding unit 104, and the tag processing unit 105 have been described above, and thus description thereof will be omitted (the same applies hereinafter).
[0079]
Then, the CPU 11 performs predetermined processing (magnification, cutout, and the like) on the image data of the image generated by the expansion processing (step T16), and displays the image data on the display device 19 (step T19).
[0080]
Therefore, when an operator (a user operating the client computer 4) desires to display a high-resolution image, a compression code related to the high-resolution image stored in the HDD 15 of the server computer 2 is acquired to obtain a low-resolution image. After the compression codes according to (1) and (2) are merged, a decompression process (decoding process) enables display of a high-resolution image equivalent to the original image.
[0081]
On the other hand, when the operator (the user who operates the client computer 4) desires to display a low-resolution image by operating the keyboard 20 or the pointing device 21 (N in step T11), the image is stored in the HDD 15 of the client computer 4. Only the compressed code related to the low-resolution image is acquired (step T17), and the acquired compressed code related to the low-resolution image is decompressed (decoded) (step T18) and displayed on the display device 19 (step T18). T16).
[0082]
Therefore, when performing low-resolution display (for example, thumbnail display) on the client computer 4 side, only the compression code related to the low-low-resolution image managed by the client computer 4 side is obtained and expanded (decoded). Processing) has advantages such as not generating network traffic and eliminating the need for scaling processing for display.
[0083]
[Image Printing Processing from Client Computer 4]
Next, the HDD 15 of the server computer 2 stores the compression code related to the high-resolution image, and the HDD 15 of the client computer 4 stores the compression code related to the low-resolution image (see FIG. 11). 4 will be described.
[0084]
FIG. 13 is a flowchart showing a flow of an image printing process from the client computer 4 executed by the server computer 2 and the client computer 4 which are image processing devices according to the image processing program.
[0085]
As shown in FIG. 13, the image printing process from the client computer 4 according to the present embodiment is performed by the operator (the user who operates the client computer 4) by operating the keyboard 20 or the pointing device 21 on the display device 19. If the user wants to print an image by clicking one of the images, the server computer 2 sends a high-resolution image corresponding to the clicked image (low-resolution image) stored in the HDD 15 of the server computer 2. Is requested (step T21).
[0086]
When the server computer 2 receives a request signal for transmitting a compression code related to a high-resolution image corresponding to the clicked image (low-resolution image) (Y in step S21), the server computer 2 The compression code related to the high-resolution image corresponding to the clicked image (low-resolution image) stored in the HDD 15 is searched based on the ID and transmitted (step S22).
[0087]
When the client computer 4 acquires the compression code related to the high-resolution image corresponding to the clicked image (low-resolution image) stored in the HDD 15 of the server computer 2 (step T22), the compression according to the acquired high-resolution image is performed. The code is merged with the compressed code related to the clicked image (low-resolution image) stored in the HDD 15 of the client computer 4 (step T23), and after the decompression process (decoding process) is executed (step T24), the printer Is output to the image output device 6 and the MFP 7 (step T25).
[0088]
Therefore, when printing an image from the client computer 4 that stores only the compression code for the low-resolution image, the compression code for the high-resolution image is required. After acquiring the compression code for the image and merging the compression code for the low-resolution image, the image is subjected to decompression processing (decoding processing), whereby high-resolution image printing equivalent to the original image can be printed.
[0089]
[Image Printing Process from Server Computer 2 According to Instruction from Client Computer 4]
Next, the HDD 15 of the server computer 2 stores the compression code related to the high-resolution image, and the HDD 15 of the client computer 4 stores the compression code related to the low-resolution image (see FIG. 11). The image printing process from the server computer 2 according to the instruction from the server 4 will be described.
[0090]
FIG. 14 is a flowchart showing a flow of an image printing process from the server computer 2 according to an instruction from the client computer 4 executed by the server computer 2 and the client computer 4 which are image processing devices according to the image processing program.
[0091]
As shown in FIG. 14, the image printing process from the server computer 2 according to the instruction from the client computer 4 according to the present embodiment is performed by first operating the keyboard 20 or the pointing device 21 by the operator (user operating the client computer 4). By clicking one of the thumbnail images displayed on the display device 19, the compression code relating to the desired low-resolution image stored in the HDD 15 of the client computer 4 is transmitted to the server computer 2 (step T31). ).
[0092]
When the server computer 2 acquires the compression code of the clicked image (low-resolution image) stored in the HDD 15 of the client computer 4 (step S31), the server computer 2 converts the compression code of the acquired low-resolution image into the compression code of the server computer 2. A compression code related to the high-resolution image corresponding to the clicked image (low-resolution image) stored in the HDD 15 was searched based on the ID and merged (step T32), and the decompression process (decoding process) was executed. Thereafter (step T33), the image is output to the image output device 6 such as a printer or the MFP 7 (step T34).
[0093]
Therefore, the compression code relating to the clicked image (low-resolution image) stored in the HDD 15 of the client computer 4 is sent to the server computer 2, and the clicked image (low-resolution image) stored in the HDD 15 of the server computer 2 is transmitted. After merging with the compression code related to the high-resolution image corresponding to ()), an expansion process (decoding process) enables high-resolution image printing equivalent to the original image. In this case, the client computer 4 sends the compression code relating to the low-resolution image to the server computer 2, so that network traffic can be minimized.
[0094]
Further, the compression code related to the low resolution image stored in the HDD 15 of the client computer 4 functions as a print key for printing an image from the server computer 2 according to an instruction from the client computer 4.
[0095]
[Data conversion processing in server computer 2 in accordance with instructions from client computer 4]
Next, the HDD 15 of the server computer 2 stores the compression code related to the high-resolution image, and the HDD 15 of the client computer 4 stores the compression code related to the low-resolution image (see FIG. 11). The data conversion process in the server computer 2 according to the instruction from the server 4 will be described.
[0096]
FIG. 15 is a flowchart showing a flow of data conversion processing in the server computer 2 according to an instruction from the client computer 4 executed by the server computer 2 and the client computer 4 which are image processing apparatuses according to the image processing program.
[0097]
In the data conversion processing in the server computer 2 according to the instruction from the client computer 4 according to the present embodiment, first, as shown in FIG. 15, the operation of the keyboard 20 or the pointing device 21 by the operator (user operating the client computer 4) By clicking one of the thumbnail images displayed on the display device 19, the compression code related to the desired low-resolution image stored in the HDD 15 of the client computer 4 is transmitted to the server computer 2 (step T41). ).
[0098]
When the server computer 2 acquires the compression code of the clicked image (low-resolution image) stored in the HDD 15 of the client computer 4 (step S41), the server computer 2 converts the compression code of the acquired low-resolution image into the compression code of the server computer 2. The compression code related to the high-resolution image corresponding to the clicked image (low-resolution image) stored in the HDD 15 was searched and merged based on the ID (step S42), and the decompression process (decoding process) was performed. Thereafter (step S43), a data conversion process is executed (step S44). The data conversion processing in step S44 is executed using the data conversion function of the data conversion server 2b. For example, the image data after the decompression processing (decoding processing) is subjected to OCR processing to extract text data. And perform other processing. In addition, text data may be extracted, and full-text search data may be extracted based on the text data, or a presentation image (PDF or the like) may be created based on the text data.
[0099]
Next, a second embodiment of the present invention will be described. The same parts as those described in the first embodiment are denoted by the same reference numerals, and description thereof is omitted. This embodiment is different from the first embodiment in that the content of the image data stored in the HDD 15 of the server computer 2 is different.
[0100]
[Image storage processing]
FIG. 16 is a flowchart showing a flow of an image storage process executed by the server computer 2 and the client computer 4 which are image processing devices according to the image processing program.
[0101]
The image storage process in the present embodiment is based on the premise that the server computer 2 has received an original image from the image input device 5 or the MFP 7 via the network interface 18 as shown in FIG. 16, for example. (Y in step S51). In this case, the original image is a digitized color image.
[0102]
Under such a premise, first, the received original image is compression-coded according to the "JPEG2000 algorithm" (step S52). That is, the image data of each of the R, G, and B components of the original image is divided into one or more (usually, a plurality) tiles, and the tiles are compression-encoded hierarchically.
[0103]
Next, a compression code related to the low-resolution image is extracted (step S53: low-resolution image data extracting unit), and the compression code related to the extracted low-resolution image is transmitted to all the client computers 4 (step S54: The low-resolution image data transmitting means) and all the compression codes (the compression code for the high-resolution image and the compression code for the low-resolution image) are stored in the HDD 15 of the server computer 2 (step S55: all image data storage means).
[0104]
In steps S54 and S55, the server computer 2 stores the compression code related to the low-resolution image transmitted to the client computer 4 and the HDD 15 of the server computer 2 by the document management function performed by the document management server 2a. IDs, which are identification numbers for associating all the compression codes (compression codes related to high-resolution images and compression codes related to low-resolution images), with each other.
[0105]
On the other hand, when the client computer 4 receives the compressed code related to the low-resolution image (Y in step T51: low-resolution image data receiving unit), the client computer 4 stores the received compressed code related to the low-resolution image in the HDD 15 of the client computer 4 ( Step T52: low-resolution image data storage means).
[0106]
That is, as shown in FIG. 17, the HDD 15 of the server computer 2 stores all compression codes (compression codes for high-resolution images and compression codes for low-resolution images), and the HDD 15 of the client computer 4 stores low-resolution images. Is stored.
[0107]
[Image Printing Process from Server Computer 2 According to Instruction from Client Computer 4]
Next, the HDD 15 of the server computer 2 stores all compression codes (compression codes for high-resolution images and compression codes for low-resolution images), and the HDD 15 of the client computer 4 stores compression codes for low-resolution images. An image printing process from the server computer 2 in accordance with an instruction from the client computer 4 in the state (see FIG. 17) will be described.
[0108]
FIG. 18 is a flowchart showing a flow of an image printing process from the server computer 2 according to an instruction from the client computer 4 executed by the server computer 2 and the client computer 4 which are image processing devices according to the image processing program.
[0109]
As shown in FIG. 18, image printing processing from the server computer 2 according to an instruction from the client computer 4 according to the present embodiment is performed by first operating the keyboard 20 or the pointing device 21 by an operator (user operating the client computer 4). By clicking one of the thumbnail images displayed on the display device 19 by the user, the ID associated with the compression code related to the desired low-resolution image stored in the HDD 15 of the client computer 4 is transmitted to the server computer 2. It transmits (step T61).
[0110]
When the server computer 2 acquires the ID associated with the compression code associated with the clicked image (low-resolution image) stored in the HDD 15 of the client computer 4 (step S61), the server computer 2 associated with the acquired ID Then, all the compression codes stored in the HDD 15 are retrieved and acquired (step S62), decompressed (decoded) (step S63), and output to the image output device 6 such as a printer or the MFP 7. (Step S64).
[0111]
Therefore, the ID associated with the compressed code associated with the clicked image (low-resolution image) stored in the HDD 15 of the client computer 4 is sent to the server computer 2 and transmitted to the HDD 15 of the server computer 2 associated with the acquired ID. After obtaining all the stored compression codes, an expansion process (decoding process) enables high-resolution image printing equivalent to the original image to be printed. In this case, by transmitting the ID associated with the compression code related to the low-resolution image from the client computer 4 to the server computer 2, the image data itself does not flow, so that network traffic can be reduced. .
[0112]
Further, the ID associated with the compression code related to the low-resolution image stored in the HDD 15 of the client computer 4 functions as a print key for printing an image from the server computer 2 according to an instruction from the client computer 4. Become.
[0113]
[Data conversion processing in server computer 2 in accordance with instructions from client computer 4]
Next, the HDD 15 of the server computer 2 stores all compression codes (compression codes for high-resolution images and compression codes for low-resolution images), and the HDD 15 of the client computer 4 stores compression codes for low-resolution images. A data conversion process in the server computer 2 in accordance with an instruction from the client computer 4 in the state (see FIG. 17) will be described.
[0114]
FIG. 19 is a flowchart showing a flow of data conversion processing in the server computer 2 in accordance with an instruction from the client computer 4 executed by the server computer 2 and the client computer 4 which are image processing apparatuses according to the image processing program.
[0115]
In the data conversion process in the server computer 2 according to the instruction from the client computer 4 according to the present embodiment, first, as shown in FIG. 19, the operation of the keyboard 20 or the pointing device 21 by the operator (user operating the client computer 4) By clicking one of the thumbnail images displayed on the display device 19 by the user, the ID associated with the compression code related to the desired low-resolution image stored in the HDD 15 of the client computer 4 is transmitted to the server computer 2. It transmits (step T71).
[0116]
When the server computer 2 acquires the ID associated with the compression code related to the clicked image (low-resolution image) stored in the HDD 15 of the client computer 4 (step S71), the server computer 2 associated with the acquired ID Then, all the compression codes stored in the second HDD 15 are searched and obtained (step S72), and after the decompression process (decoding process) is executed (step S73), the data conversion process is executed (step S74). The data conversion processing of step S74 is executed using the data conversion function of the data conversion server 2b. For example, the image data after the decompression processing (decoding processing) is subjected to OCR processing to extract text data. And perform other processing. In addition, text data may be extracted, and full-text search data may be extracted based on the text data, or a presentation image (PDF or the like) may be created based on the text data.
[0117]
In each embodiment, the compression code relating to the low-resolution image extracted by the server computer 2 is transmitted to all the client computers 4, and the compression code relating to the low-resolution image is transmitted to the HDDs 15 of all the client computers 4. However, the present invention is not limited to this. For example, the compression code relating to the low resolution image extracted by the server computer 2 is transmitted only to the desired client computer 4, and the compression code relating to the low resolution image is stored in the HDD 15 of the desired client computer 4. Is also good. Accordingly, only the client computer 4 that stores the compression code related to the low-resolution image of the specific image can perform high-resolution display, printing, and the like of the specific image, so that confidentiality is guaranteed.
[0118]
Further, in each embodiment, after the server computer 2 compression-encodes the original image received from the image input device 5 or the MFP 7 via the network interface 18 according to the “JPEG2000 algorithm”, the server computer 2 converts the compression code relating to the low-resolution image. The extraction is performed, but the present invention is not limited to this. For example, image data (compression code) already compressed and encoded according to the “JPEG2000 algorithm” is downloaded via the Internet communication network 9 and a compression code relating to a low-resolution image is extracted from the downloaded image data (compression code). You may do it.
[0119]
【The invention's effect】
According to the present invention, a compression code related to a low resolution image corresponding to an arbitrary layer is extracted, and the compression code related to the extracted low resolution image is transmitted to another image processing apparatus. At the same time as transmitting, by storing the compression codes related to the high-resolution images except for the compression codes related to the low-resolution images corresponding to an arbitrary layer from the entire compression codes in the storage unit, the low-resolution images are stored in the storage units of other image processing apparatuses. If the compression codes related to the resolution images are stored, the data storage areas can be dispersed.
[0120]
According to the second, twelfth and fourteenth aspects of the present invention, a compression code related to a low resolution image corresponding to an arbitrary layer transmitted from another image processing apparatus is received, and a compression code related to the received low resolution image is received. Is stored in the storage unit, the data storage area can be distributed.
[0121]
According to the third aspect of the present invention, on the server computer side, a compression code relating to a low-resolution image corresponding to an arbitrary hierarchy is extracted, and the compression code relating to the extracted low-resolution image is transmitted to a client computer via a network. , And stores a compression code for the high-resolution image obtained by removing the compression code for the low-resolution image corresponding to an arbitrary layer from all the compression codes in the storage unit. On the other hand, on the client computer side, a compression code related to a low-resolution image corresponding to an arbitrary layer transmitted from the server computer via the network is received, and the received compression code related to the low-resolution image is stored in the storage unit. By doing so, the storage unit of the server computer stores the compression codes related to the high-resolution images excluding the compression codes related to the low-resolution images corresponding to the arbitrary layers from the entire compression codes, and stores the low-resolution images in the storage unit of the client computer. Therefore, the data storage area can be dispersed.
[0122]
According to the fourth aspect of the present invention, in the document management system according to the third aspect, when a low-resolution display such as a thumbnail display can be used in time, compression of a desired low-resolution image stored in the client computer is performed. Decode the code and display it. On the other hand, when a part is displayed at a high resolution such as an enlarged display, a compression code related to a high-resolution image stored in a server computer is obtained, and a desired low-resolution image stored in a client computer is obtained. By decoding and displaying the result of merging with such a compression code, when displaying a low-resolution image on the client computer side, it is possible to reduce the load on the client computer side and to reduce the load on the client computer side. Network traffic at the time of displaying an image at a resolution can be reduced.
[0123]
According to the fifth aspect of the present invention, in the document management system according to the third aspect, when low-resolution printing is sufficient, a compression code for a desired low-resolution image stored in the client computer is decoded. Print. On the other hand, when printing at a high resolution, a compression code related to a high resolution image stored in a server computer is obtained, and a result of merging with a compression code related to a desired low resolution image stored in a client computer is obtained. By decoding and printing, when a low-resolution image is printed on the client computer side, the load on the client computer side can be reduced, and the network for printing the high-resolution image on the client computer side can be reduced. Traffic can be reduced.
[0124]
According to the sixth aspect of the present invention, in the document management system according to the third aspect, when a high-resolution image is printed on the server computer side in accordance with an instruction from the client computer, a low-level image is transmitted from the client computer to the server computer. By transmitting the compressed code related to the high resolution image and decoding and printing the result merged with the compressed code related to the high resolution image stored in the server computer, the high resolution on the server computer side is instructed by the client computer. Can be printed, and the compression code associated with the low-resolution image stored in the client computer can have the meaning of a print key.
[0125]
According to the seventh aspect of the present invention, in the document management system according to the third aspect, when the server computer executes data conversion processing based on a high-resolution image in accordance with an instruction from the client computer, By transmitting a compression code related to the low-resolution image to the server computer, decoding the result of merging with the compression code related to the high-resolution image stored in the server computer, and executing data conversion processing, That the server computer can execute the data conversion processing based on the high-resolution image in accordance with the instruction, and that the compression code for the low-resolution image stored in the client computer has the meaning of the data conversion processing key. Can be.
[0126]
According to the eighth aspect of the present invention, on the server computer side, a compression code relating to a low resolution image corresponding to an arbitrary hierarchy is extracted, and the compression code relating to the extracted low resolution image is transmitted to the client computer via a network. , And all the compression codes are stored in the storage unit. On the other hand, on the client computer side, a compression code related to a low-resolution image corresponding to an arbitrary layer transmitted from the server computer via the network is received, and the received compression code related to the low-resolution image is stored in the storage unit. By doing so, the entire compression code is stored in the storage unit of the server computer, and the compression code related to the low-resolution image is stored in the storage unit of the client computer. Can be reduced.
[0127]
According to the ninth aspect of the present invention, in the document management system according to the eighth aspect, when a high-resolution image is printed on the server computer side in accordance with an instruction from the client computer, the client computer transmits the high-resolution image to the server computer. By transmitting an identification number associated with the compression code relating to the low-resolution image of the low resolution image and decoding and printing all the compression codes associated with the identification number stored in the server computer, by an instruction from the client computer, A high-resolution image can be printed on the server computer side, and network traffic can be reduced because the image data itself does not flow.
[0128]
According to the tenth aspect of the present invention, in the document management system according to the eighth aspect, when the server computer executes data conversion processing based on a high-resolution image in accordance with an instruction from the client computer, Transmits the identification number associated with the compression code relating to the desired low-resolution image to the server computer, decodes all the compression codes associated with the identification number stored in the server computer, and executes data conversion processing By doing so, it is possible to execute data conversion processing based on a high-resolution image on the server computer side in accordance with an instruction from the client computer, and to reduce network traffic because the image data itself does not flow. .
[Brief description of the drawings]
FIG. 1 is a functional block diagram of a system for realizing a hierarchical coding algorithm which is a basis of the JPEG2000 system which is a premise of an embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a divided rectangular area of each component of an original image.
FIG. 3 is an explanatory diagram showing subbands at each decomposition level when the number of decomposition levels is three.
FIG. 4 is an explanatory diagram showing a precinct.
FIG. 5 is an explanatory diagram showing an example of a procedure for ranking bit planes.
FIG. 6 is an explanatory diagram showing a schematic configuration of one frame of code string data.
FIG. 7 is a schematic diagram illustrating a system configuration example according to the first embodiment of this invention;
FIG. 8 is a module configuration diagram of the image processing apparatus.
FIG. 9 is a flowchart illustrating a flow of an image storage process executed by the image processing apparatus according to the image processing program.
FIG. 10 is an explanatory diagram showing a resolution model of a compression code generated according to a “JPEG2000 algorithm”.
FIG. 11 is an explanatory diagram showing a distributed storage state of a compression code for a high-resolution image and a compression code for a low-resolution image.
FIG. 12 is a flowchart illustrating a flow of an image display process in a client computer.
FIG. 13 is a flowchart illustrating a flow of an image printing process from a client computer.
FIG. 14 is a flowchart illustrating a flow of an image printing process from a server computer according to an instruction from a client computer.
FIG. 15 is a flowchart showing a flow of a data conversion process in a server computer according to an instruction from a client computer.
FIG. 16 is a flowchart illustrating a flow of an image storage process performed by the image processing apparatus according to the second embodiment of this invention.
FIG. 17 is an explanatory diagram showing a distributed storage state of a compression code for a high-resolution image and a compression code for a low-resolution image.
FIG. 18 is a flowchart illustrating a flow of an image printing process from a server computer according to an instruction from a client computer.
FIG. 19 is a flowchart showing a flow of a data conversion process in a server computer according to an instruction from a client computer.
[Explanation of symbols]
1 Document management system
2 Image processing device, server computer
3 network
4 Image processing device, client computer
15 Memory

Claims (14)

Low-resolution image data extraction means for extracting a compression code related to a low-resolution image corresponding to an arbitrary layer from a compression code hierarchically encoded by discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of tiles,
A low-resolution image data transmitting unit that transmits a compression code related to the low-resolution image extracted by the low-resolution image data extracting unit to another image processing apparatus;
High-resolution image data storage means for storing a compression code related to a high-resolution image except for a compression code related to a low-resolution image corresponding to an arbitrary hierarchy from all compression codes in a storage unit;
An image processing apparatus comprising: A compression code for a low-resolution image corresponding to an arbitrary layer extracted from a compression code obtained by performing discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and hierarchically encoding is received from another image processing apparatus. Low-resolution image data receiving means;
A low-resolution image data storage unit that stores a compression code related to the low-resolution image received by the low-resolution image data reception unit in a storage unit;
An image processing apparatus comprising: Low-resolution image data extraction means for extracting a compression code related to a low-resolution image corresponding to an arbitrary layer from a compression code hierarchically encoded by discrete wavelet transform of pixel values for each tile obtained by dividing the image into a plurality of tiles; A low-resolution image data transmitting unit that transmits a compression code related to the low-resolution image extracted by the low-resolution image data extraction unit via a network, and a compression code related to the low-resolution image corresponding to an arbitrary hierarchy from all the compression codes. A server computer having high-resolution image data storage means for storing a compression code relating to the removed high-resolution image in a storage unit,
A low-resolution image data receiving unit connected to the server computer via the network and receiving a compression code related to the low-resolution image transmitted from the server computer; and a low-resolution image received by the low-resolution image data receiving unit. A low-resolution image data storage means for storing the compression code according to the storage unit in the storage unit,
Document management system comprising: When displaying a low-resolution image on the client computer side, decoding and displaying a compression code related to the low-resolution image stored in the client computer,
When displaying a high-resolution image on the client computer side, a compression code for a high-resolution image associated with a compression code for a desired low-resolution image stored in the client computer is obtained from the server computer. 4. The document management system according to claim 3, wherein the compressed code related to the low-resolution image and the compressed code related to the high-resolution image are merged, decoded, and displayed. When printing a low-resolution image on the client computer side, decoding and printing a compression code related to the low-resolution image stored in the client computer,
When printing a high-resolution image on the client computer side, a compression code for a high-resolution image associated with a compression code for a desired low-resolution image stored in the client computer is obtained from the server computer. 4. The document management system according to claim 3, wherein the compressed code related to the low-resolution image and the compressed code related to the high-resolution image are merged, decoded, and printed. When printing a high-resolution image on the server computer side according to an instruction from the client computer, the client computer transmits a compression code related to a desired low-resolution image to the server computer, and the client computer transmits the compression code. Printing after merging and decoding the acquired compression code related to the desired low-resolution image and the compression code related to the high-resolution image stored in the server computer associated with the compression code related to the low-resolution image The document management system according to claim 3, wherein When performing data conversion processing based on a high-resolution image on the server computer side according to an instruction from the client computer, the client computer transmits a compression code relating to a desired low-resolution image to the server computer. By merging the compression code for the desired low-resolution image obtained from the client computer and the compression code for the high-resolution image stored in the server computer associated with the compression code for the low-resolution image 4. The document management system according to claim 3, wherein data conversion processing is performed after decryption. Low-resolution image data extraction means for extracting a compression code relating to a low-resolution image corresponding to an arbitrary layer from a compression code hierarchically encoded by discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of tiles; A low-resolution image data transmitting unit that transmits, via a network, a compression code related to the low-resolution image extracted by the low-resolution image data extraction unit; and an all-image data storage unit that stores all the compression codes in a storage unit. A server computer,
A low-resolution image data receiving unit connected to the server computer via the network and receiving a compression code related to the low-resolution image transmitted from the server computer; and a low-resolution image received by the low-resolution image data receiving unit. A low-resolution image data storage means for storing the compression code according to the storage unit in the storage unit,
Document management system comprising: When printing a high-resolution image on the server computer side according to an instruction from the client computer, an identification number associated with a compression code relating to a desired low-resolution image is transmitted from the client computer to the server computer. Obtaining an identification number associated with a compression code relating to a desired low-resolution image from the client computer, and printing after decoding all compression codes associated with the identification number stored in the server computer; The document management system according to claim 8. When performing data conversion processing based on a high-resolution image on the server computer side, transmitting an identification number associated with a compression code related to a desired low-resolution image from the client computer to the server computer, Obtaining an identification number associated with a compression code relating to a desired low-resolution image from the client computer, and performing data conversion processing after decoding all compression codes associated with the identification number stored in the server computer. 9. The document management system according to claim 8, wherein the document management system performs the operation. A low-resolution image data extraction function for extracting a compression code related to a low-resolution image corresponding to an arbitrary layer from a compression code hierarchically encoded by discrete wavelet transform of a pixel value for each tile obtained by dividing the image into a plurality of tiles;
A low-resolution image data transmission function of transmitting a compression code relating to the low-resolution image extracted by the low-resolution image data extraction function via a network;
A high-resolution image data storage function of storing a compression code related to a high-resolution image in a storage unit excluding a compression code related to a low-resolution image according to an arbitrary hierarchy from all compression codes;
A program that causes a computer to execute. A low-resolution receiving, via a network, a compression code related to a low-resolution image corresponding to an arbitrary layer extracted from a compression code obtained by performing discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically Image data receiving function,
A low-resolution image data storage function of storing a compression code related to the low-resolution image received by the low-resolution image data reception function in a storage unit;
A program that causes a computer to execute. A low-resolution image data extraction function for extracting a compression code related to a low-resolution image corresponding to an arbitrary layer from a compression code hierarchically encoded by discrete wavelet transform of a pixel value for each tile obtained by dividing the image into a plurality of tiles;
A low-resolution image data transmission function of transmitting a compression code relating to the low-resolution image extracted by the low-resolution image data extraction function via a network;
A high-resolution image data storage function of storing a compression code related to a high-resolution image in a storage unit excluding a compression code related to a low-resolution image according to an arbitrary hierarchy from all compression codes;
Computer-readable storage medium storing a program for causing a computer to execute the program. A low-resolution receiving, via a network, a compression code related to a low-resolution image corresponding to an arbitrary layer extracted from a compression code obtained by performing discrete wavelet transform of a pixel value for each tile obtained by dividing an image into a plurality of layers and encoding hierarchically Image data receiving function,
A low-resolution image data storage function of storing a compression code related to the low-resolution image received by the low-resolution image data reception function in a storage unit;
Computer-readable storage medium storing a program for causing a computer to execute the program.

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