KR20090123240A - Partially-updating method for image data - Google Patents

Abstract

PURPOSE: A method for using compressed image data for partially updating mass image data is provided to partially updating the mass image data by preventing the share of a memory resource. CONSTITUTION: A client device transmits a request message about an update file information to a service server in network(S62). The client device determines whether the update file information is received(S63). The client device determines whether the validity of the received update file information(S66). The client device requests the update file corresponding to the received update file information in the service server(S68). The client device queues until the update file is received from the service server(S69).

Description

[0001] PARTIALLY-UPDATING METHOD FOR IMAGE DATA [0002]

The present invention relates to a method for partially updating image data, and more particularly to a method for partially updating image data using compressed image data for partial updating in large-capacity image data.

When a large-capacity digital image is viewed through a computer, a navigation, or a mobile communication terminal, a user can view a wide area with a low resolution or a specific area or a specific page due to the limitation of the size of a display mounted on the information- You will use a high-resolution, detailed view. The most common method of storing and transmitting digital images is to transfer the entire image data as it is or in compressed form.

Large-capacity images are stored in a file format using image compression storage methods such as JPEG, FlashPix, and JPEG2000, and JPEG2000 compressed images are used for network services.

In addition, U.S. Patent No. 6,978,049 or European Patent Publication No. 1,545,121 disclose a self-developed tile-pyramid format to enhance screen display and network transmission efficiency.

Generally, the lossy compression of JPEG represents a compression ratio of 1:10 to 1:20, and the lossy compression of JPEG2000 of wavelet type is 1 : 50 to 1: 300. The higher the compression rate, the more computation is required.

In the case of an image of a small size commonly used, it is possible to decompress the image in real time on the memory to edit or modify the desired portion to update the image so as to be a compressed image.

U.S. Patent No. 6,980,700 decompresses a JPEG-compressed original image in real time into memory, adds another image to the original image area, compresses the original image in JPEG format, and updates or adds necessary parts to the user In a previous image. In this method, when a specific area of the compressed image is to be modified, the compressed image must be decompressed in the memory, and thus, in the case of a large-capacity image such as a satellite image or high resolution aerial photograph, The waiting time becomes long and a memory corresponding to the original image before compression is secured.

In order to solve such a problem, it is an object of the present invention to provide a partial update method of image data which makes it possible to perform a partial update of a large-capacity image without causing a large-capacity image to be occupied more quickly and excessively.

It is another object of the present invention to provide a partial update method of image data in which only an image corresponding to an area requiring updating is transmitted and received through a network and only the portion corresponding to the image is updated.

It is another object of the present invention to provide a partial update method of image data for updating an original image by transmitting and receiving an image corresponding to an area requiring update in a tile-shaped compressed image.

In the following, various aspects of the claimed invention will be described. The following description forms part of a detailed description of the present invention and is intended to be illustrative only and is not to be taken by way of limitation with respect to the technical idea of the invention, And should not be construed as limiting the present invention.

A method for partial update of image data according to claim 1 when filed. With this method, it is possible to quickly update the original file corresponding to the small size of the image to be updated.

A method for partially updating image data according to claim 2 at the time of filing. With this method, only the image of the original file corresponding to the rows and columns included in the updated image data can be processed to process a small amount of data.

A method for partial update of image data according to claim 3 when filed. In this way, you can also perform updates to the original file with multiple levels of structure.

A method for partially updating image data according to claim 4 when filed. With this method, the update image data is added to perform the update as soon as possible.

A method for partial update of image data according to claim 5 when filed. In this way, it is possible to optimize the memory space by preventing the original file from being increased in capacity through updating.

A method for partial update of image data according to claim 6 when filed. In this way, you can optimize the memory space by creating a new source file.

A method for partial update of image data according to claim 7 when filed. In this way, the update can be performed at a selected point in time of the user's selection.

A method for partially updating image data according to claim 8 when filed. In this way, the entire update file is not transmitted, only the data of a small size is preferentially determined, and the entire update file is transmitted according to the determination, thereby improving the reliability of the data.

A method for partial update of image data according to claim 9 when filed. Through this method, the service server generates an update file that compresses only the image for which an update is requested, so that a small amount of data can be transmitted and processed.

A method for partial update of image data according to claim 10 when filed. With this method, update data including an image to be updated and an image not to be updated at a minimum is generated.

The method of partial update of image data according to claim 11, when filed. With this method, an update file corresponding to a plurality of levels is generated.

A method for partial update of image data according to claim 12 when filed. In this way, only basic information can be transmitted to the client device with priority.

A method for partial update of image data according to claim 13 when filed. In this way, the user can provide a confirmation service for the update at a desired point in time.

The method of partial update of image data according to claim 14 when filed. With this method, only the update file in which the update file information is confirmed is transmitted first, thereby improving the reliability of the data and preventing unnecessary data transmission.

The present invention with such a configuration makes it possible to perform partial update of a large-capacity image by making a large-capacity image more quickly but not excessively occupying memory resources, Which has a remarkable effect.

In addition, according to the present invention, only an image corresponding to an area requiring updating is transmitted and received through a network, and only the portion corresponding to the image is updated, thereby reducing time and cost for transmitting and receiving data through the network.

In addition, the present invention has an effect of transmitting and receiving an image corresponding to a region requiring update as a compressed image in the form of a tile, thereby updating the original image, so that updating is performed through a minimum decompression.

Hereinafter, the present invention will be described in detail based on embodiments of the present invention and the accompanying drawings.

1 is a configuration diagram of a system in which a method for partially updating image data according to the present invention is performed. 1, the system includes a service server 10 that stores large-capacity image data, a client device 30 that is connectable to the service server 10 via the network 20 and displays large- And a client device 32 which is connectable by the network 20 and the network connection device 40 and which displays large-capacity image data.

The service server 10 stores the large-capacity image data as an original file including the tile-shaped image data described below, and includes updated image data including the changed portion within the area corresponding to the large- Create and save the update file. The service server 10 transmits the update file to the client devices 30 and 32 when necessary so that the update by the updated image data is performed in each of the client devices 30 and 32. [

The network 20 is a combination of devices that allow a network service to be performed, including a transmission medium for general Internet services, an Internet service provider (ISP), a Web server or a WAP server and the like.

The client device 30 is a device having a unique network connection function, and the client device 32 is a device having no unique network connection function. These client devices 30 and 32 store original files including large images, such as computers, mobile communication terminals, personal digital assistants (PDAs), navigations, and the like. The client devices 30 and 32 have an input unit (not shown) for displaying the image data according to the original file to a user through a display unit (not shown) and acquiring a command from the user, The update file information, the update file, and the like according to the user's request, and moves, enlarges, or reduces the image displayed on the display unit.

The network connection device 40 gives a network connection function to the client device 32, and a computer or the like can be used.

FIG. 2 is a first embodiment of a process of generating an original file performed by the service server of FIG.

In step 1, the service server 10 receives and stores at least one or more original images 1 to 4 from the outside. Each of the original images 1 to 4 includes images such as ortho corrected satellite photographs or aerial photographs, coordinate information thereof, resolution information (e.g., pixel resolution, etc.), and the like.

In step 2, the service server 10 integrates the original images 1 to 4 to create one integrated image 50 (e.g., a mosaic image). The original images (1 to 4) may have different pixel resolutions depending on the shooting accuracy. For example, a LandSat image has a pixel resolution of 30 m, IKONOS has a resolution of 1 m, and aerial photographs have a resolution of 0.1 m. Accordingly, the service server 10 may perform a process of resampling the original images 1 to 4 to have a certain resolution. The integrated image 50 generated by the service server 10 has an image area including an image area displayed by the original images 1 to 4 and includes coordinate information indicating the image area and the like.

In step 3, the service server 10 divides the integrated image 50 into tiles of generally a certain size (horizontal and vertical), and compresses each tile of the image 52. However, it is also possible to divide it into tiles of different sizes (depending on the service environment) in the horizontal and vertical directions, and compress them. For example, when the screen size is 1200 * 500, the number of accesses to the tiles can be reduced by making the horizontal size larger than the vertical size of the tiles.

Here, compressing in units of tiles compresses the tiles by dividing the entire image 52 into tile units, and records the information in the head of the file (the original file described below). For example, if the image 52 is divided into n * m tiles, then the compressed file has offset (offset) and length information of n * m compressed tiles.

The tile compression method is lossy compression, and JPEG and JPEG2000 compression methods can be used. A library such as zlib may also be used for lossless compression. The compression method is recorded in a file in any way.

In addition, when dividing the image 52 composed of resampled images into tiles, the number of pixels included in a specific tile may be different for each image.

In particular, in the case of tile A, some of the images may be obtained from original image 1 and the remaining images may be obtained from original image 2.

FIG. 3 is a second embodiment of a process of generating an original file performed by the service server of FIG. Fig. 3 shows a case where tiles are divided into pyramidal shapes and compressed.

Level 1 is the highest resolution step of the image 52, and as the level increases, the previous image is resequitized to create the upper level images 54 and 56. [

 The size of the image 52 is W * H (where W is the number of horizontal pixels of the image, H is the number of vertical pixels of the image), and the resolution R (in m units in the rectangular coordinate system and in radians in the longitudinal latitude coordinate system) When the size is t (the number of horizontal and vertical pixels of the tile) and the resolution of the upper level is r1, the following expression (1) is derived.

Tile columns of level 1 image 52 = (W-1) / t + 1

Tile rows of level 1 image 52 = (H-1) / t + 1

 High-level image width = W * R / r1

 High level image height = H * R / r1

 The upper level tile cols = (W-1) / (t * r1 / R) + 1

 The upper level tile rows = (H-1) / (t * r1 / R) + 1

At this time, the relationship of r1 > R is always maintained.

The width, height, number of tile cols, and number of tile rows of the upper level images 54 and 56 are calculated in the same manner as in the above-described Equation 1, and the widths and heights of the images 54 and 56 are smaller than the tile size Until then, it is repeatedly divided into pyramidal tile units. These pyramid-shaped tiles are respectively compressed as shown in FIG. 2 to generate an original file.

4 shows the structure of the original file. The original file is composed of a fixed header for storing image basic information, level headers (1) and (2), and level data (1) and (2).

First, the fixed head stores image basic information. The basic information of this image is the signature of the file to check the error of the file format and to identify the original file including the version information. It also includes data offset information, image size, color information, number of levels (2 in this embodiment), coordinate information of image 52, resolution, and compression codec information. This compressed codec information can be used when the client device 30 decompresses the tile.

In addition, the level header 1 includes, for example, level 1 level basic information. The level basic information includes level 1 image size, resolution, tile size, number of tiles, offset of tiles, and length information. In particular, the offset, length information of the tiles causes the level data 1 to be identified. The level header 2 indicates the upper level of the level header 1.

Further, the level data 1 includes compressed image data of each tile (Tile ₀₀ to Tile _nm ). The level data 2 includes compressed image data of each tile of the upper level.

Further, as the level step increases, a level header and level data are added, respectively.

5A to 5C show a first embodiment of an update file generation process performed by the service server of FIG.

The service server 10 stores the original file for a specific image area, and also obtains area image data including an image change such as a terrain change within the image area. Accordingly, the service server 10 modifies the area image data into an update file of the same type as that of the original file, and transfers the update file upon request from the client device 30. This area image data also includes resolution information, coordinate information, and the like.

As shown in Fig. 5A, the service server 10 needs to calculate the tile area 52a corresponding to the image area occupied by the area image 60. [0060] This tile area 52a corresponds to a tile that is ultimately to be replaced in the original file. This tile area 52a can be defined as left, top, right, and bottom, and is calculated according to the following equation (2).

 left = (oil-nil) / (R * t)

        top = (oit-nit) / (R * t)

        right = (oir-nir) / (R * t) +1

        bottom = (oib - nib) / (R * t) +1

R is the resolution of the level, t is the size of the tile applied to the original image,

oil: left coordinate of original image, nil: left coordinate of update image,

oit: top coordinate of original image, nit: top coordinate of update image,

oir: the right coordinate of the original image, nir: the right coordinate of the update image,

oib: bottom coordinate of original image, nib: bottom coordinate of update image.

Here, the original image means images 50 and 52 divided into original files. left, top, right, and bottom correspond to the rows and columns of the tile corresponding to the original file.

As shown in FIG. 5B, the service server 10 decompresses the image data corresponding to the tile area 52a, and integrates the image data into one image 52b through mosaic processing. This image 52b also includes coordinate information so that the region image 60 can be overlaid on the image 52b in accordance with the coordinate information of the region image 60 as shown in Fig. The overlaid region image 60 should have the same resolution as the image 52b. Thus, when the resolution is different, the service server 10 performs resampling processing on the area image 60 so that the resolution is the same as the image 52b.

The region image 60 includes the region to be deformed and the region B excluding the region image 60 in the image 52b corresponds to the image which is not deformed. That is, the area of the image 52b superimposed on the area image 60 is deleted, and only the area image 60 and the area B are included in the update image 52c.

5C, the service server 10 divides the area image 60 and the updated image 52c composed of the area B by the size of the tile applied from the original file to form tiles, Compression is performed as described above. This updated image 52c may be the same as the area image 60 and may include the area B, as illustrated.

  FIG. 6 is a second embodiment of an update file generation process performed by the service server of FIG.

6 is a process of generating an update file corresponding to an original file compressed in a pyramid shape as shown in FIG. The update file of FIG. 6 estimates the area images 60, 60a, 60b corresponding to each level according to Equation (1) and calculates the level tiles corresponding to the respective region images 60, 60a, 60b Areas 52a, 54a and 56a are calculated. Thereafter, the service server 10 divides and compresses the tile areas 52a, 54a, and 56a and the area images 60, 60a, and 60b according to the method described in FIG. 5 at each level.

7 shows the structure of the update file. The service server 10 generates an update file including an update image, as disclosed in FIGS. This update file is structurally identical to the original file by default.

That is, the fixed header includes image basic information. The image basic information includes a file signature, version information, a file name, an image size, color information, a number of update levels, color information, compressed codec information, and the like. The version information finally includes information about which image (original file) has been updated.

In addition, the level headers 1 and 2 may store image size, tile size, resolution, number of rows and columns of tiles, offset information of corresponding level data, and data length information Record. In addition, the level data areas (1) and (2) are areas in which files compressed in units of tiles at each level are stored.

The service server 10 easily stores the pre-stored original file and the update file corresponding to the pre-stored original file.

FIG. 8 is a first embodiment of a partial update method of image data according to the present invention, and FIG. 9 is a second embodiment of a partial update method of image data according to the present invention. That is, FIG. 8 shows a method performed by the client devices 30 and 32 (only the client device 30 will be described below), and FIG. 9 shows a method performed by the service server 10.

More specifically, in step S61 of FIG. 8, the client device 30 confirms whether it has received a request input of the update file information from the user. If a request for update file information is input from the user, the process proceeds to step S62; otherwise, the process waits. However, instead of step S61, the client device 30 may proceed to step S62 according to an update period (for example, one week interval, one month interval) set by itself.

The client device 30 transmits the request message for the update file information to the service server 10 while being connected to the network 20 in step S62 of Fig. The request message for the update file information includes version information of the original file stored in the client device 30, file name, coordinate information, and the like, so that the service server 10 stores the type of the original file stored in the client device 30 So that it can be identified.

In step S63 of FIG. 8, the client device 30 determines whether the update file information has been received. If the update file information is received, the process proceeds to step S66; otherwise, the process proceeds to step S64.

In step S81 of FIG. 9, the service server 10 waits until it receives a request message of the update file information from the client device 30 via the network 20. When receiving the request message, the service server 10 proceeds to step S82 do.

In step S82 of FIG. 9, the service server 10 determines whether there is an update file corresponding to the received request message. That is, the service server 10 determines whether there is an update file corresponding to the original file identified by the received request message. If a corresponding update file exists, the process proceeds to step S84. Otherwise, if there is no update file for the original file, the flow advances to step S83.

In step S83 of FIG. 9, the service server 10 transmits the absence of the update file to the client device 30 via the predetermined notification message in response to the original file stored in the client device 30. FIG.

In step S64 of FIG. 8, the client device 30 determines whether or not a notification message informing the absence of the update file has been received. If the notification message is received, the flow advances to step S65. If not, the flow advances to step S63 to maintain the reception state of update file information for a predetermined time.

In step S65 of FIG. 8, the client device 30 displays the received notification message to the user through a predetermined display unit, and ends the update method.

In step S84 of Fig. 9, the service server 10 transmits update file information including only the fixed header to the client device 30, in the corresponding update file. In order to transmit only the update file information, it is first determined whether the original file stored in the client device 30 and the update file stored in the service server 10 correspond to each other, and then the update image data having relatively large capacity is transmitted .

In step S66 of FIG. 8, the client device 30 determines the validity of the received update file information. The client device 30 checks the validity of the basic information (coordinate, size, resolution, compressed codec information) of the file on the basis of the received update file information, and this validity indicates that the basic information corresponding to the original file is updated file information And the like. For example, when it is determined that the client device 30 can not decompress the compressed update image data by judging the compressed codec information included in the received update file information, it becomes invalid. This prevents reception of unnecessary data. If the update file information is valid, the process proceeds to step S68, and if not, the process proceeds to step S67.

In step S67 of FIG. 8, the client device 30 transmits a notification message including information indicating that the received update file information is invalid, that is, no update file corresponding to the pre-stored original file, Lt; / RTI >

In step S68 of FIG. 8, the client device 30 requests the service server 10 for an update file corresponding to the received update file information.

In step S69 of Fig. 8, the client device 30 waits until an update file is received from the service server 10.

In step S85 of FIG. 9, the service server 10 waits until there is a request for an update file from the client device 30.

In step S86 of FIG. 9, the service server 10 reads the pre-stored update file corresponding to the request, and transmits it via the network 20, thereby ending the update method.

In step S70 of FIG. 8, the client device 30 performs an update for updating and updating the pre-stored original file in accordance with the updated image data included in the received update file.

The client device 30 checks the tile area to be updated in the original file according to the row and column information of the tile included in the level header 1 stored in the update file. 7, the tile area to be updated for level 1 is (Tile ₂₂ to Tile ₂₄ , Tile ₃₂ to Tile ₃₄ , Tile ₄₂ to Tile ₄₄ ).

First, when the capacity of the original file is small, the client device 30 may regenerate a new original file with respect to the image data included in the pre-stored original file and the updated image data included in the update file. In other words, the client device 30 generates a new original file with the image data corresponding to the image area other than the tile area according to the updated image data, and the updated image data. Thus, the client device 30 newly generates offset and length information in the level header, and the updated image data is included in place of the previous image data.

Alternatively, if the original file has a large capacity, it takes a lot of time and memory to create a new original file as described above, and therefore, only the image data in the tile area to be updated is processed.

Accordingly, the client device 30 first compares the size of the updated image data with the size of the image data in the tile area to be updated. If the size of the updated image data is smaller than or equal to the size of the image data, the client device 30 deletes the previously stored image data, stores the updated image data in the memory space, and updates the original file. If the updated image data is smaller than the image data, there is a portion of the original file that does not have the updated image data. If the original file has a large capacity, the impact on the overall image is small even if there is a loss.

If the size of the updated image data is larger than the size of the image data, the client device 30 stores the updated image data in series with the last level data of the original file. That is, the client device 30 stores the updated image data in the original file. At this time, the client device 30 may delete the image data to be updated, and modify the offset and length information included in the level header to have the location information and the size information on the stored update image data.

1 is a configuration diagram of a system in which a method for partially updating image data according to the present invention is performed.

FIG. 2 is a first embodiment of a process of generating an original file performed by the service server of FIG.

FIG. 3 is a second embodiment of a process of generating an original file performed by the service server of FIG.

4 shows the structure of the original file.

5A to 5C show a first embodiment of an update file generation process performed by the service server of FIG.

FIG. 6 is a second embodiment of an update file generation process performed by the service server of FIG.

7 shows the structure of the update file.

8 is a first embodiment of a partial update method of image data according to the present invention.

9 is a second embodiment of a partial update method of image data according to the present invention.

Description of the Related Art

10: service server 20: network

30, 32: Client device

Claims (14)

A partial update method of image data in a client device storing an original file including at least one image data compressed in tile units, the update method comprising the steps of: Receiving an update file including at least one or more updated image data compressed in tile units; And updating the original file in accordance with the updated image data. The method according to claim 1, Wherein the updating step performs processing on image data corresponding to row and column information of each of the updated image data included in the update file. 3. The method of claim 2, Wherein the updating step performs processing on image data corresponding to the level information of each of the updated image data included in the update file. 4. The method according to any one of claims 1 to 3, Wherein the update step updates the image data by adding the update image data to the original file. 4. The method according to any one of claims 1 to 3, Wherein the updating step deletes the image data corresponding to the updated image data and includes the updated image data in the original file. The method according to claim 1, Wherein the updating step generates image data excluding image data corresponding to the updated image data and a new original file including the updated image data. The method according to claim 1, Wherein the update method comprises obtaining a request input of a user for update file information including basic information of the update file or the update file. 8. The method of claim 7, Wherein the update method comprises the steps of: requesting the service server for the update file information; receiving update file information in response thereto; determining validity of the received update file information; And requesting the update file to the service server when the update request is received. A partial update method of image data in a service server storing an original file including at least one image data compressed in tile units, the update method comprising the steps of: Obtaining region image data included in an image region of the original file; Calculating a tile area of image data corresponding to the area image data; Dividing the updated image data including at least the area image data into tile units of a predetermined size according to the size of the image area of the tile area; And generating an update file including the updated image data. 10. The method of claim 9, The updating method may include generating the updated image data by overlaying the image data in the tile area and the area image data according to the coordinate information when the tile area is wider than the image area of the area image data And updating the partial image data. 10. The method of claim 9, Wherein the updating method further comprises the step of resampling the area image data according to the resolution of each level when the original file includes image data having a plurality of levels. 10. The method of claim 9, Wherein the update method comprises generating update file information including basic information of the update file. 13. The method of claim 12, The update method comprising the steps of: receiving a request for update file information corresponding to the original file from a client device; and transmitting the corresponding update file information in response to the request. Way. The method according to claim 12 or 13, Wherein the update method includes receiving a request for an update file corresponding to the original file from the client device, and transmitting a corresponding update file in response to the request. .

Images