KR100583325B1 - Method and system of zooming digital images - Google Patents

Abstract

Disclosed are a method and system for digital image zooming. A position base can be defined by marking one or more coordinates using an index (eg, a cursor) within the display area. After the selection of the zooming ratio by the user or the generation of the zooming ratio by the marked coordinates is determined, the display area is updated with the zoomed image according to the positional reference and the zooming ratio. Compared to continuously moving the zoom image for positioning, it can reduce a lot of computing and hardware costs.

Digital Image, Zooming, Zoom, Indicator, Marking, Mark, Position

Description

Digital image zooming method and system {METHOD AND SYSTEM OF ZOOMING DIGITAL IMAGES}

1 is a view schematically showing a flow chart of the prior art.

2A and 2B schematically illustrate a flowchart according to an embodiment of the present invention.

3A and 3B schematically illustrate a flowchart according to an embodiment of the present invention.

4 is a schematic block diagram of another embodiment of the present invention.

The present invention relates generally to a method and system for displaying an image, and more particularly to a method and system for marking a zooming ratio and an image display position of an image in accordance with an index or cursor. It is about.

In the field of image display, it is usually required to display image information in a picture with a certain zooming ratio. This kind of application is usually bundled with certain software or hardware, such as digital image zooming or image editing software of a digital camera, for example.

This kind of application in the prior art takes as the image position where there is image information which is usually located in the center of the display area which is a position base such as, for example, pixels. After zooming the original image information at a specific zooming ratio, the zoom image is renewed according to a positional reference located at the center of the display area. When the zooming ratio is changed, the user must move the image so that the intended image can be displayed in the display area because the new image must be larger or smaller than the original display range. As a result, computing costs will increase significantly. First, in step 110 illustrated in FIG. 1, the zooming ratio and the position reference are acquired. There may be various methods of acquiring the zooming ratio. For example, one of the preset default zooming ratios may be selected, the zooming ratio may be increased in proportion to the default zooming ratio, or the user may input the zooming ratio. On the other hand, the position reference is generally obtained by the upper left corner of the display area (for example, the position of the first pixel of the display area) or the position of the display information along the center. Next, in step 120, the zoom image is updated in the display area according to the zooming ratio. Then, in operation 130, a zoom image is displayed on the display area according to the location reference. Finally, the zoomed image continues to move until the portion of the intended image is displayed in the display area in step 140.

As in the above method, the zoom image is updated after the entire image information is zoomed according to the zooming ratio. If the image information is very large, several disadvantages will arise. First, since an image is generally stored in a frame buffer before output, the conventional method requires a large frame buffer. In addition, only a portion of the frame buffer is used for display in the display area, and other frame buffers remain unused. In addition, each time an image is moved, the portion of the image to be displayed in the display area must be acquired again from the frame buffer, thus requiring a large computing cost. Furthermore, since the image display after the image cannot be predicted before the image is moved, the image must be continuously moved until it is appropriate. Each move requires additional power and time, which is uneconomical when applied to portable devices such as digital cameras, considering cost, power, hardware cost, and battery usage.

Clearly, it is uneconomical to move the image continuously after the image is zoomed by the zooming ratio. Therefore, there is a need for portable devices with more economical methods or systems.

According to the foregoing needs, one of the main objects of the present invention is to provide a method and system for zooming a digital image according to a specific zooming ratio by a single coordinate. The present invention is convenient for the user when arbitrarily selecting an image portion in the display area, and then updating the zoom image after zooming in or zooming out.

In addition, another object of the present invention is to provide a method and system for zooming an image using a plurality of coordinates, wherein the positional reference and zooming ratio are obtained by a method of selecting two coordinates or marking a range by a user. do. The present invention is convenient for the user when randomly selecting an image portion in the display area and then updating the zoomed image after enlarging or reducing it.

According to the above object, the present invention provides a method for marking a position and zooming an image according to a single coordinate. This method is used to mark the position criterion according to the indicator and to observe the zooming ratio, thus updating the zoom image in the display area according to the position criterion and zooming ratio.

The invention also provides a method of marking a position and zooming an image according to a plurality of coordinates. This method is used to mark two coordinates using an indicator to obtain a positional reference and zooming ratio, so that the display area is updated with the zoom image according to the positional reference and zooming ratio.

The present invention also provides a system for marking a position and zooming an image, comprising: an image memory for storing image information, an interface means for calculating a positional reference and a zooming ratio which is a specific position of the image information, and displaying according to the positional reference and the zooming ratio A position marking and image zooming system includes an image processing unit for updating a zoom image in an area, and display means for displaying an image in the display area.                         

Since the image is expected to be updated with the original image, there is no need to continuously move the image. Therefore, a large amount of computing cost and frame buffer cost are reduced.

The invention will be best understood from the following description and the annexed drawings.

Some suitable and preferred embodiments of the present invention are described below. However, it should be noted that the present embodiment is merely exemplary and that various modifications may be made without departing from the scope of the present invention.

However, it is to be understood that the drawings, which are not to scale, are intended for explanatory purposes and are not intended to be limiting of the invention, and therefore, serve as a reference to the appended claims.

In the prior art, when zooming an image, the image is generally zoomed or moved, which requires a large frame buffer and a large computing cost. As a result, the main feature of the present invention is to first mark the position criterion actually displayed in the image, and then calculate the new image using the position criterion according to the default value or the zooming ratio adjusted by the user. Thus, the present invention updates the zoom image in the display area (eg LCD panel or OLED panel). Therefore, there is no need to constantly move the image in the process of zooming the image, thereby reducing a lot of computing cost. Since there is no need to zoom the entire image information in order to continuously move and move the image, it is only necessary to zoom the image portion necessary for the new image to generate the zoom image, thus saving unnecessary frame buffers. In addition, the pixels of the new zoom image can be generated one after the other and output to the display area, thus eliminating the need for a frame buffer.

Therefore, one embodiment of the present invention is a method of zooming a digital image in a single coordinate. 2A schematically illustrates a flowchart in accordance with an embodiment of the present invention. First, in step 210, an image is displayed on the display area, which may be displayed according to the format of the image information after acquiring the image information from the digital image capture means. In addition, the image information may be stored in another storage medium (for example, a disk, a flash card or a memory). The storage method and the format of the image information of the present invention are not limited. In addition, the image displayed in the display area may be represented using only a part of captured image information or may be represented using the entire image information. The range represented by the image information captured in the display area of the present invention is not limited. In FIG. 2B, block 2100 shows a diagram according to step 210.

Next, in step 220, a positional reference of the image information is obtained, the positional reference being obtained according to the image information related to the coordinates of the display area. In other words, the position relative to the coordinates in the image information displayed in the display area is taken as the position reference. For example, moving an indicator (e.g., a cursor) to that coordinate and then obtaining a positional reference, or otherwise a user entering the coordinates to obtain the positional reference. The coordinate of the position reference is a relative position in the image information with respect to the coordinate, that is, to find what is used in the image information for display in the coordinate, and the relative position may be the relative position or coordinate of the pixel. The method of acquiring the position reference of the present invention and the method of indicating the relative position are not limited. In operation 220, the coordinates of the center position of the display area may be acquired while the reference coordinate point is used when the zoom image is updated. Block 2200 of FIG. 2B is a diagram of step 220.

In step 220, the position reference is acquired according to the position relative to the cursor position, and then in step 230, the zooming ratio is obtained. There are several methods of acquiring the zooming ratio. For example, the user may select one from the default zooming ratio, increase the zooming ratio in proportion to the default zooming ratio, or obtain the zooming ratio by directly inputting by the user. Therefore, the method of acquiring the zooming ratio of this invention is not limited.

Finally, as shown in step 240, the zoom information is updated in the display area according to the positional reference and zooming ratio using the image information, otherwise the zoom image is updated in the display area after referring to the coordinates of the center position. And, the image display is to take the positional reference to the cursor position as a marked point, which may be any specific position within the display area. For example, the specific position may be the center of the display area, one of four corners of the display area (ie, upper left, upper right, lower left, lower right) or another position, but is not limited thereto. The display area then updates the zoom image in accordance with the zoom ratio. In addition, the updated image may be enlarged and reduced in accordance with a default zooming ratio or a zooming ratio that increases (decreases) in direct proportion to the default zooming ratio. In addition, the size of the zoom image may match only the display area (i.e. use only a portion of the image information for image update) and may exceed the range of the display area (i.e., the entire image information for image update). use). It can also point to the coordinates of the center position and update the zoom image in the display area. In addition, the size of the image in the present invention is not limited. The former method saves the cost of the frame buffer and does not even require a frame buffer, but directly updates the image in the display area. The latter method can reduce the user's image travel time, but it requires a large frame buffer because it greatly increases computing costs (eg, power). Block 2300 of FIG. 2B is a result diagram after processing according to step 240. Thus, the present embodiment not only includes the conventional image shift function, but also makes the image selection more convenient and saves the user time and effort.

Another embodiment of the present invention provides an image zooming method using a plurality of coordinates, and FIG. 3A schematically illustrates a flowchart of the present embodiment. The difference between this embodiment and the previous embodiment is that step 220 and step 230 of FIG. 2A are replaced with step 320 and step 330 of the present embodiment, respectively. In step 320, the first coordinate 3310 and the second coordinate are obtained (shown in FIG. 3B). The method of acquiring the first coordinate and the second coordinate is input by the user, or the cursor displayed in the display area by the user in order to acquire the range or area of the coordinates is sequentially moved to the position of the first coordinate and the second coordinate. It may be to.

The above-described method of acquiring the first coordinate and the second coordinate may be treated as marking the range of the display area, or acquiring the first coordinate and the second coordinate by marking the range of the display area. For example, it is to use a method of marking a rectangle in the display area as shown in FIG. 3B. First, the indicator marked at the first coordinate 3110 is controlled. Next, while moving the indicator, it displays a rectangular frame line 3210 that takes the indicator and the first coordinate as the two endpoints of the diagonal in the display area, which is used to indicate the marked range. Meanwhile, the indicator is directly controlled to sequentially mark the first coordinate 3110 and the second coordinate 3120, respectively, and then the rectangular frame line 3210 is generated by taking two coordinates as two end points of a diagonal line. Likewise, the marked range is not limited to rectangles only. The marked range may be a circle created by taking the first coordinate and the second coordinate as two end points of the diameter. In addition, the marked range may be an ellipse generated by taking the first coordinate and the second coordinate as major and minor axes according to the aspect ratio of the display area.

In operation 330, the zooming ratio and the position reference are calculated according to the size of the range marked by the first coordinate 3110 and the second coordinate 3120. The position reference may be obtained by selecting the center point 3130 of the range marked by the first coordinate and the second coordinate or the two coordinates as shown in FIG. 3B. The zooming ratio may also be obtained by the ratio according to the vertical width of the display area to the vertical distance between the first coordinate and the second coordinate. Otherwise, it can be obtained by the ratio according to the horizontal width of the display area to the horizontal distance between the first coordinate and the second coordinate.

Finally, image information is used to update the zoom image according to the positional reference and zooming ratio as described in step 240. In addition, since the detail of this embodiment is similar to the previous embodiment, it is not included in a following description.

According to the previously announced method, it is another embodiment of the present invention to provide a system for zooming a digital image as shown in FIG. 4. This embodiment includes an image memory unit 31, an interface unit 32, an image processing unit 33, a display unit 34 and a temporary storage unit 35, and the image memory unit 31 Records image information 312. The image is created according to step 210 described above. The image is generated by the image processing unit 33 according to the image information 312, and then displayed by the display unit 34, and the processed image may be stored in the temporary storage unit 35. Thus, the temporary storage unit 35 includes a frame buffer which stores the image and provides it to the display unit 34 for display.

In addition, the image processing unit 33 further includes adding the indicator coordinates 352 to the image. The coordinate position is generated in relation to the indicator position, and the coordinate data may be stored in the temporary storage unit 35. On the other hand, it may also change the indicator coordinates 352 by the interface unit 32 to control the indicator position, which may be defined as the indicator position displayed on the display area 342. On the other hand, it may be defined as an indicator position that is part of the image information 312 displayed in the image area 342. For example, the position of one pixel and the position of that pixel in the image information 312 is indicated by the indicator position.

In addition, the interface unit 32 is also used to generate the position criterion 354 and the zooming ratio 356 according to the above-described steps 220 and 230, and the position criterion 354 is used to generate the detailed position ( specific position). The method of acquiring the position reference may be a user inputting the coordinates to acquire the coordinates of the position reference, or moving the indicator for the detailed position and then acquiring the position reference according to the indicator coordinate 352. It may be another way of obtaining the detailed position in the image information 312 according to the coordinates. The position reference 354 and the zooming ratio 356 may be stored in the temporary memory 35, and thus the temporary memory 35 may include a plurality of temporary storages, as described above. Stores indicator coordinates 32, location reference 354, and zooming ratio 356.

In addition, the interface unit 32 may acquire the first coordinates 3110 and the second coordinates 3120 according to the above-described steps 320 and 330, and according to the two coordinates, the position reference 354 and the zooming ratio ( 356) can be obtained. Therefore, the interface unit 32 selects a method of acquiring the zooming ratio 356 (for example, input by a user, selection of one of the default zooming ratios 356, or acquisition according to the first coordinate and the second coordinate). It further includes a selection unit (option) to. Thus, as shown in step 240 described above, the image processing unit 33 uses the image information 312 to update the zoom image in the display area 342 according to the position reference 354 and the zooming ratio 356. Details of the present embodiment are similar to the previous embodiment and thus will not be included in the following description.

The present invention can be applied to displays and location systems where the indication of the indicator is not a prerequisite. For example, the above-described position reference or coordinates may be obtained by the touch screen when applied to the touch screen system. In a touch screen system, the indicator may or may not be displayed on the screen. The invention can also be applied to portable devices such as digital cameras or mobile phones.

While the invention has been described above in connection with exemplary embodiments, this description should not be intended or interpreted in a limiting sense. It will be apparent to those skilled in the art with reference to the detailed description that other embodiments of the present invention, of course, various modifications and combinations to the exemplary embodiments are possible. Accordingly, the appended claims are intended to cover all such modifications and embodiments.

According to the present invention, one can provide a method and system for zooming a digital image according to a specific zooming ratio by a single coordinate.

In addition, according to the present invention, it is possible to provide a method and system for image zooming with a plurality of coordinates in which the position reference and zooming ratio are obtained by a method of selecting two coordinates by a user or marking a range.

Claims (16)

delete delete delete delete A digital image zooming method using a plurality of coordinates, Displaying an image on the display area according to the image information, Acquiring first coordinates of the image information; Acquiring second coordinates of the image information; Acquiring a position reference for a zoom image of the first and second coordinates according to the first and second coordinates; Calculating the zooming ratio, and Updating a zoom image in the display area using the image information according to the zooming ratio and the position reference Digital image zooming method comprising a. In claim 5, And the first coordinate and the second coordinate are acquired according to the position of the indicator by moving the indicator displayed on the display area to the first coordinate and the second coordinate, respectively. In claim 5, The zooming ratio is based on a ratio of the vertical width of the display area to the vertical distance between the first coordinate and the second coordinate; and the display relative to the horizontal distance between the first coordinate and the second coordinate. A digital image zooming method, obtained by any one of the methods based on the ratio of the horizontal width of an area. In claim 5, The position criterion is selected as a central point between the position of the first coordinate and the position of the second coordinate, And a zoom image is updated at the center position according to the intermediate point and the center position of the display area. In claim 5, The display area includes four corners of upper left, upper right, lower left and lower right, The image information selects the first coordinate as the location reference, And the zoom image is updated at one corner of the display area according to the positional reference and the zooming ratio. In claim 5, And the size of the zoom image corresponds to the display area. An image memory unit for storing image information, An interface unit for generating a location reference and a zooming ratio which is a specific location in the image information An image processor for updating an image displayed in the display area using the image information according to the zooming ratio and the position reference; A display unit which displays the image in the image area, and A temporary storage unit storing the position reference, the zooming ratio and the image Including; The interface unit includes an indicator, the indicator being controlled by the interface unit, The position of the indicator displayed in the display area is related to the coordinates of the indicator, The position reference is obtained according to the indicator coordinates when the indicator is moved to a specific position, The zooming ratio is directly generated according to first and second coordinates of the display area. The first coordinate and the second coordinate are obtained by the coordinates of the indicator when the indicator is moved to two specific positions in turn. Digital image zooming system, characterized in that. delete delete delete delete In claim 11, The zooming ratio is based on a ratio of the vertical width of the display area to the vertical distance between the first coordinate and the second coordinate; and the display relative to the horizontal distance between the first coordinate and the second coordinate. A digital image zooming system, characterized in that it is obtained by any of the methods based on the ratio of the horizontal width of the region.

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