JP4000693B2 - Image display device and image display method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention particularly relates to an image display device suitable for use in thumbnail display in which reduced images are arranged and a list of images is displayed on the same screen. And image display method About.
[0002]
[Prior art]
There is a case where it is desired to display thumbnails by forming a plurality of reduced images and arranging the reduced images and displaying a list of images on the same screen. Conventionally, such a thumbnail display conventionally takes in an input image signal for forming a reduced image into a memory, reads out the image data from the memory, forms a reduced screen by a CPU (Central Processing Unit), and displays the reduced screen. An image corresponding to a thumbnail image stored in the memory and displayed on the screen is expanded on the memory, and the expanded thumbnail image is displayed on the memory.
[0003]
That is, in FIG. 14, 101 is a CPU, 102 is a memory, 103 is an image writing circuit, and 104 is a display control circuit. An image signal for forming a reduced image is captured from the input terminal 105 via the image writing circuit 103, and the image signal is temporarily captured via the bus 106. Then, the CPU 101 performs interpolation calculation processing, thinning-out processing, and the like to form reduced image data. The reduced image data is stored in the memory 102.
[0004]
Then, the next image data for forming a reduced image is supplied from the input terminal 105 via the image writing circuit 103. Similarly, the image data is once taken into the memory 102 via the bus 106, and the CPU 101 performs interpolation calculation processing, thinning processing, and the like to form reduced screen data. This reduced image data is stored in the memory 102.
[0005]
In this way, reduced image data is formed for each screen. The reduced image data is arranged at an address corresponding to the thumbnail image to be displayed on the display, and one screen data corresponding to the thumbnail image to be displayed is formed in the memory 102. Image data corresponding to the thumbnail image is sent to the display control circuit 104, and an image signal corresponding to the thumbnail image is output from the display control circuit 104. The output of the display control circuit 104 is output from the output terminal 107.
[0006]
For example, when displaying thumbnail images composed of reduced images P100, P101, P102,... As shown in FIG. 15, the memory 102 stores display images P100, P101, P102,. .. Are arranged at addresses corresponding to..., PIC100, PIC101, PIC102,. Image data corresponding to the thumbnail image is sent to the display control circuit 104 and displayed on the display.
[0007]
[Problems to be solved by the invention]
As described above, conventionally, when thumbnails are displayed, image data is fetched one by one, a reduced screen is formed one by one by the CPU, and thumbnail images displayed on one screen are developed on a memory. . For this reason, there is a problem that the burden on the CPU becomes heavy and the time until the thumbnail image is displayed becomes long. Further, during data processing, the CPU and memory are frequently accessed and the bus is occupied, so the frequency of use of buses in other blocks is reduced. Furthermore, if the thumbnail display is performed with a moving image, the burden on the CPU becomes very heavy.
[0008]
Further, conventionally, the formed reduced screen is stored in a memory corresponding to the display position, and a thumbnail image to be displayed on one screen is developed on the memory. For this reason, it is necessary to recreate the image each time the thumbnail screen for reducing the thumbnails is deleted or rearranged.
[0009]
Accordingly, an object of the present invention is to reduce the burden on the CPU and to perform thumbnail display at a high speed. And image display method Is to provide.
[0010]
Another object of the present invention is to provide an image display device that can easily delete or rearrange reduced screens for thumbnail display. And image display method Is to provide.
[0011]
[Means for Solving the Problems]
This invention Picture First storage means for storing a plurality of image data;
Image data stored in the first storage means About A storage location in the first storage means; Double Display position when arranging a number of image data on the same screen, Enlarging / reducing rate and But Picture Second storage means stored in association with each image data;
Comparison means for comparing the display position for each image data stored in the second storage means with an arbitrary position on the screen;
Corresponds to any position on the screen based on the comparison result in the comparison means. Painting Image data is determined and determined based on the storage position stored in the second storage means Picture Read image data sequentially from the first storage means Control the enlargement / reduction of the image data according to the enlargement / reduction ratio Reading control means;
By read control means Read from the first storage means Picture An image display device comprising display means for displaying image data.
[0012]
When displaying thumbnail images that display a list of reduced images side by side, a reduced image is formed in real time and stored in the memory, and a register for the window is prepared, and in this register, the position and size of the window, The address on the memory where the reduced image is stored is stored, and the thumbnail image is displayed while reading the reduced image from the memory using the information in this register. As described above, according to the present invention, the reduced image is formed in real time, and the thumbnail image does not need to be developed on the memory. Therefore, high-speed display is possible, and continuous shooting display and moving image display are easily performed. Can do.
[0013]
In addition, a register that stores the window position and size and the address on the memory where the reduced image is stored is provided, so you can rearrange, add, and delete thumbnail images simply by changing the register information. The size and position of the window frame can be easily changed. Furthermore, the display can be enlarged and reduced by changing only the register information, and wipe-in and wipe-out can be performed.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an example of a graphic system to which the present invention is applied. As shown in FIG. 1, the graphic system to which the present invention is applied includes a CPU 1 and an image processor 2.
[0015]
The image processor 2 is a processor that can perform thumbnail display, enlarged / reduced display, and wipe-in / wipe-out processing. An image to be displayed as a thumbnail is taken by, for example, the camera 3 and sent to the image processor 2.
[0016]
Based on the user input from the input unit 6, the CPU 1 sends information such as the position and size of the window and the image to be displayed in the window. These pieces of information are taken into the image processor 2. The image processor 2 forms an image based on these pieces of information. The formed image is sent to the display 4 and displayed on the display 4.
[0017]
Thus, in the graphic system to which the present invention is applied, image processing is performed on the image processing processor 2 side. For this reason, it is possible to greatly reduce the burden on the CPU 1 when displaying the thumbnail display.
[0018]
As shown in FIG. 2, the image processing processor 2 includes an image processing unit 11, an image writing unit 12, a display control unit 13, and a memory 14.
[0019]
The image processing unit 11 performs image processing such as enlargement, reduction, and deformation on the input image signal. The image processing unit 11 performs image processing in real time. The image processed image data is sent to the image writing unit 12.
[0020]
The image writing unit 12 performs processing for writing the image data processed by the image processing unit 11 into the memory 14. The image writing unit 12 sends the image data processed by the image processing unit 11 to the memory 14 via the bus 17. Then, the image processed image data is stored at a desired address in the memory 14.
[0021]
The display control unit 13 generates and outputs an image output signal based on the image data stored in the memory 14. The display control unit 13 is provided with registers Reg0, Reg1, Reg2,. In these registers Reg0, Reg1, Reg2,..., Information to be displayed in each window, for example, the read start address on the memory of the reduced image displayed in each window, the display start and display end addresses of each window, and the enlargement -The reduction rate is stored. The display control unit 13 accesses the memory 14 based on the information about the windows stored in the registers Reg0, Reg1, Reg2,... Of the image processing unit 11, and forms a display image. This display image signal is output from the output terminal 16 and displayed on the display 4.
[0022]
When displaying a thumbnail image using such an image processor 2, signals of a plurality of images to be displayed as thumbnails are sequentially supplied to the input terminal 15, and each of these image signals is supplied to the image processing unit 11. On the other hand, the reduction processing of the screen is performed in real time, and a reduced image is formed. Reduced image data formed by the image processing unit 11 is sequentially stored in the memory 14 through the bus 17 by the image writing unit 12. Thereby, the memory 14 stores a plurality of reduced image data to be displayed in each window.
[0023]
When a plurality of reduced image data to be displayed in each window is stored in the memory 14, the display control unit 13 performs a thumbnail image display process. At this time, the reduced image data is read from the memory 14 based on the information stored in the registers Reg0, Reg1, Reg2,.
[0024]
FIG. 3 is a functional block diagram showing the operation of the image processor 2 when displaying such thumbnail images.
[0025]
3, the memory 14 stores a plurality of reduced image data PIC0, PIC1, PIC2,... Taken in as described above. In the registers Reg0, Reg1, Reg2,..., Corresponding to each window, the read start address on the memory 14 of the reduced image data PIC0, PIC1,. The rate is remembered.
[0026]
A display address is generated from the display address generation unit 21 corresponding to the current display position of the display 4. This display address is sent to the comparison unit 22. Further, the display start and display end addresses of each window are read from the registers Reg0, Reg1, Reg2,. The display start and display end addresses of each window are sent to the comparison unit 22.
[0027]
The comparison unit 22 compares the current display address with the display start and display end addresses of each window from the registers Reg0, Reg1, Reg2,..., And whether the current display address is within the display range of each window. Is judged. If the current display address is not within the display range of each window, the display drive unit 23 advances the display position.
[0028]
If there is a window whose current display address falls within the display range, the reduced image data PIC0, PIC1, PIC2, and the like displayed at the position of the window based on the contents of the registers Reg0, Reg1, Reg2,. Are read from the memory 14. The read reduced image data PIC0, PIC1, PIC2,... Are sent to the display 4, and images corresponding to these reduced image data PIC0, PIC1, PIC2,.
[0029]
Then, the display drive unit 23 advances the display position, and the comparison unit 22 again compares the current display address with the display start and display end addresses of each window from the registers Reg0, Reg1, Reg2,. The If there is a window whose current display address falls within the display range, the reduced image data PIC0, PIC1, PIC2, and the like displayed at the position of the window based on the contents of the registers Reg0, Reg1, Reg2,. Are read from the memory 14, and the reduced image data PIC0, PIC1, PIC2,... Read from the memory 14 are sent to the display 4 and displayed.
[0030]
When the current display address deviates from the display address of the window, reading of the reduced image data PIC0, PIC1, PIC2,... Corresponding to the window from the memory 14 is stopped, and the display drive unit 23 advances the display position. It is done.
[0031]
In this way, the reduced images specified by the registers Reg0, Reg1, Reg2,... Among the reduced images stored in the memory 14 are displayed in the window at the display position specified by the registers Reg0, Reg1, Reg2,. Is done. Thereby, a thumbnail screen is formed and displayed.
[0032]
In this way, the image processor 2 reads thumbnail image PIC0, PIC1, PIC2,... To be displayed at the position of the window based on the contents of the registers Reg0, Reg1, Reg2,. Can be displayed in real time. At the same time, by rewriting the information in the registers Reg0, Reg1, Reg1, Reg2,.
[0033]
4 and 5 are flowcharts showing the processing at this time. 4 and 5, each variable has the following value.
[0034]
Xbgn [n]: horizontal display start address of window number n
Ybgn [n]: display start address in the vertical direction of window number n
Xend [n]: horizontal display end address of window number n
Xend [n]: Display end address in the vertical direction of window number n
BgnAdd [n]: start address on the memory of the reduced image data of window number n
wino: Window number currently being processed (window numbers are assigned in order of priority)
WinMax: Maximum window number
add: Address on memory
Wadd: horizontal address width in memory
x: Current horizontal display address
y: Current vertical display address
xmax: Maximum display address in the horizontal direction
ymax: Maximum display address in the vertical direction
In FIG. 4, it is determined whether or not the display position of the display 4 is the start position of the scanning line (step S1). When the scan line start position is reached, the display address (x, y) is initialized to the initial position (0, 0) (step S2). Then, display window selection processing is performed at the display address (step S3).
[0035]
In the display window selection process, it is determined whether there is a window whose current display address is the display range based on the contents of the registers Reg0, Reg1, Reg2,. If there is, processing for reading out the reduced image of the window from the memory 12 is performed.
[0036]
When the display window selection process is completed, the horizontal display address x is advanced by “1” (step S4). Then, it is determined whether or not the horizontal display address x is greater than the maximum value xmax of the horizontal display address (step S5). If the horizontal display address x is smaller than the maximum value xmax of the horizontal display address, the process returns to step S3, the display window selection process is performed, and when the display window selection process is completed, the horizontal display address x is determined in step S4. The display address x is advanced by “1”.
[0037]
In step S5, when the horizontal display address x becomes larger than the maximum value xmax of the horizontal display address, the display address has reached the end in the horizontal direction. When the horizontal display address x becomes larger than the maximum value xmax of the horizontal display address, the vertical address is advanced by “1”, and the horizontal address is returned to the starting end (step S6).
[0038]
When the vertical address is advanced by “1” and the horizontal address is returned to the beginning, it is determined whether or not the vertical display address y is larger than the maximum value ymax of the vertical display address (step S7). ). If the vertical display address y is smaller than the maximum value ymax of the vertical display address, the process returns to step S3, and display window selection processing is performed at that display address.
[0039]
In step S7, when the vertical display address y becomes larger than the maximum value ymax of the vertical display address, the display address has reached the end of one screen, and the processing for one screen is terminated.
[0040]
Thus, the display address is scanned by steps S1 to S7. Then, while scanning the display address, it is determined in the display window selection process in step S3 whether or not there is a window whose display range is the current display address based on the contents of the registers Reg0, Reg1, Reg2,. If there is a window whose current display address is the display range, a process of reading a reduced image of the window from the memory 12 is performed. As a result, a thumbnail image is formed based on the contents of the registers Reg0, Reg1, Reg2,.
[0041]
FIG. 5 is a flowchart showing the display window selection process in step S3 of FIG. In FIG. 5, the window number wno is initialized to (wno = 0) (step S11). The window number wno is shown in the priority order of the windows. Then, the display start address Xbgn [0] and end address Xend [0] in the horizontal direction with the window number (wno = 0) are determined from the contents of the register Reg0 in which the information with the window number wno (wno = 0) is stored. And the horizontal display start address Xbgn [0] and end address Xend [0] of the window number wno (wno = 0) are compared with the current horizontal display address x. From this comparison result, the current horizontal display address x is between the horizontal display start address Xbgn [0] and the horizontal display end address Xend [0] whose window number wno is (wno = 0). It is determined whether or not there is. That is, it is determined whether (Xbgn [0] ≦ x) and (x ≦ Xend [0]) are satisfied (step S12).
[0042]
The current horizontal display address x is not between the horizontal display start address Xbgn [0] of the window number wno (wno = 0) and the horizontal display end address Xend [0]. If it is determined that Xbgn [0] ≦ x) and (x ≦ Xend [0]) do not hold, the current horizontal display address x is the horizontal display of the window whose window number is wno (wno = 0). It can be said that it is not in range. At this time, the process proceeds to step S14, and the window number wno is incremented to (wno = 1).
[0043]
In step S12, the current horizontal display address x is between the horizontal display start address Xbgn [0] of the window number wno (wno = 0) and the horizontal display end address Xend [0]. , (Xbgn [0] ≦ x) and (x ≦ Xend [0]), the current horizontal display address x is within the display range of the window whose window number wno is (wno = 0). It is in.
[0044]
At this time, the display start address Ybgn [0] and end address Yend [0] in the vertical direction with the window number (wno = 0) are determined from the contents of the register Reg0 in which the information with the window number wno (wno = 0) is stored. ], And the vertical display start address Ybgn [0] and end address Yend [0] whose window number is (wno = 0) are compared with the current vertical display address y. From this comparison result, the current vertical display address y is between the horizontal display start address Ybgn [0] and the horizontal display end address Yend [0] with the window number wno (wno = 0). It is determined whether or not there is. That is, it is determined whether (Ybgn [0] ≦ y) and (y ≦ Yend [0]) are satisfied (step S13).
[0045]
If it is determined that the current vertical display address y is not between the vertical display start address Ybgn [0] and the vertical display end address Yend [0] of the window number wno (wno = 0). That is, if it is determined that (Ybgn [0] ≦ y) and (y ≦ Yend [0]) do not hold, the current vertical display address y is the window number wno (wno = 0). It can be said that it is not in the vertical display range. At this time, the process proceeds to step S14, and the window number wno is incremented to (wno = 1).
[0046]
If the window number wno is incremented to (wno = 1) in step S14, it is determined whether or not the window number wno exceeds the maximum window number WinMax (step S15). If the window number wno does not exceed the maximum window number WinMax, the process returns to step S12.
[0047]
It is determined whether or not the current horizontal display address x is between the horizontal display start address Xbgn [1] of the window number wno (wno = 1) and the horizontal display end address Xend [1]. If the current horizontal display address x is not between the horizontal display start address Xbgn [1] of the window number wno (wno = 1) and the horizontal display end address Xend [1]. Since the current horizontal display address x is not in the display range of the window whose window number wno is (wno = 1), the process goes to step S14, where the window number wno is incremented to (wno = 2) and again, Returning to step S12, the above-described processing is repeated.
[0048]
In step S12, the current horizontal display address x is between the horizontal display start address Xbgn [1] with the window number wno (wno = 1) and the horizontal display end address Xend [1]. However, in step S13, the current vertical display address y is obtained by setting the horizontal display start address Ybgn [1] and the horizontal display end address Yend [1] with the window number wno (wno = 1). If not, the current vertical display address y is not in the display range of the window whose window number wno is (wno = 1), so go to step S14, and the window number wno is incremented (wno = 2), Returning to step S12 again, the above-described processing is repeated.
[0049]
Thus, in step S12 and step S13, it is determined whether or not the current display address is within the display range of the window. If the current display address is not within the display range of the window, the window is displayed in step S14. The number wno is incremented.
[0050]
In step S12, when the window number wno is set to (wno = n (n is an arbitrary integer)), the current horizontal display address x is the horizontal display start address Xbgn [n] and the horizontal display. It is determined that it is within the range of the end address Xend [n]. In step S13, the current vertical display address y is set to the vertical display start address Ybgn [n] and the horizontal display end address Yend [n]. If it is determined that it is within the range, it can be said that the current display address is within the display range of the window having the window number wno (wno = n).
[0051]
If it is determined in step S13 that the current vertical display address y is within the range of the vertical display start address Ybgn [n] and the vertical display end address Yend [n], the window number is read from the register Regn. The start address BgnAdd [n] on the memory where the reduced image with wno (wno = n) is stored is read out. Then, an address on the memory 14 is obtained using the start address BgnAdd [n] (step S16).
[0052]
The address add on the memory 14 is
add = BgnAdd [n] + (y−YBgn [n]) × Wadd + (x−XBgn [n])
As required.
[0053]
Then, the data of the address “add” obtained in step S16 is read from the memory 14 and displayed on the display 4, and the display window selection process is completed. Then, the process proceeds to the process of advancing the display address (step S4 in FIG. 3).
[0054]
If the window number wno is larger than the maximum window number WinMax in step S15, it can be said that there is no window whose display address is the current display address. In this case, display is not performed (step S18), the display window selection process is terminated, and the process proceeds to a process for advancing the display address (step S4 in FIG. 4).
[0055]
As described above, the display window selection process shown in FIG. 5 determines whether there is a window whose display address is the display range based on the contents of the registers Reg0, Reg1, Reg2,. If there is a window whose address is the display range, the reduced image of the window is read from the memory 14. As a result, thumbnail images are displayed based on the contents of the registers Reg0, Reg1, Reg2,.
[0056]
For example, in the memory 14, as shown in FIG. 6, reduced image data PIC 0 indicating the character “a”, reduced image data PIC 1 indicating the character “c”, and reduced image data indicating the character “b”. Assume that PIC2 is stored. Then, on the display 4, as shown in FIG. 7, the reduced image P0 indicating the character “a” is displayed in the window W0, the reduced image P1 indicating the character “c” is displayed in the window W1, and the window W2 is displayed. It is assumed that the reduced image P2 indicating the character “b” is displayed.
[0057]
In this case, as shown in FIG. 8A, in the register Reg0 whose window number wno is (wno = 0), a horizontal display start address Xbgn [0] corresponding to the display position of the window W0 shown in FIG. x _Five Is stored and y is displayed as the vertical display start address Ybgn [0]. ₂ Is stored and x is displayed as the horizontal display end address Xend [0]. ₆ Is stored, and y is displayed as the vertical display end address Yend [0]. _Four Is memorized. Also, in correspondence with the memory address shown in FIG. 6, # 100 is stored as the start address BgnAdd [0] on the memory of the reduced image data.
[0058]
In the register Reg1 having the window number wno (wno = 1), the horizontal display start address Xbgn [1] corresponding to the display position of the window W1 shown in FIG. ₁ Is stored, and y is displayed as the vertical display start address Ybgn [1]. ₁ Is stored and x is displayed as the horizontal display end address Xend [1]. _Three Is stored and y is displayed as the vertical display end address Yend [1]. _Three Is memorized. Further, # 900 is stored as the start address BgnAdd [1] on the memory of the reduced image data corresponding to the memory address shown in FIG.
[0059]
In the register Reg2 having the window number wno (wno = 2), the horizontal display start address Xbgn [2] corresponding to the display position of the window W2 shown in FIG. ₂ Is stored and y is displayed as the vertical display start address Ybgn [2]. _Five Is stored and x is displayed as the horizontal display end address Xend [2]. _Four Is stored and y is displayed as the vertical display end address Yend [2]. ₆ Is memorized. Further, # 500 is stored as the start address BgnAdd [2] on the memory of the reduced image data corresponding to the memory address shown in FIG.
[0060]
The current display address P (x, y) in FIG. 7 is scanned from left to right and from top to bottom by the processing of steps S2 to S7 in FIG. In the display window selection process in step S3, it is determined whether there is a window whose current display address P (x, y) is in the display range based on the contents of the registers Reg0, Reg1, Reg2,. If there is a window whose current display address is the display range, a process of reading a reduced image of the window from the memory 14 is performed.
[0061]
That is, the display address P (x, y) is (x ₁ , Y ₁ ), The display address P (x, y) is stored in the register Reg1, and the window number wno is (wno = 1) in the display range (Xbgn [1], Ybgn [1]) to (Xend [ 1], Yend [1]), the image of the reduced image P1 from the address # 900 of the memory 14 based on the start address BgnAdd [1] on the memory of the reduced image data stored in the register Reg1. Data PIC1 is read. Thus, when the display position P (x, y) is in the range of (Xbgn [1], Ybgn [1]) to (Xend [1], Yend [1]), the reduced image stored in the register Reg1. The image data PIC1 of the reduced image PI is read based on the start address BgnAdd [1] on the data memory, and the reduced image P1 indicating the character “c” is displayed in the window W1.
[0062]
The display address P (x, y) is (x _Five , Y ₂ ), The display address P (x, y) is stored in the register Reg0 and the window number wno is (wno = 0) in the display range (Xbgn [0], Ybgn [0]) to (Xend [ 0], Yend [0]), the image of the reduced image P0 from the address # 100 of the memory 14 based on the start address BgnAdd [0] on the memory of the reduced image data stored in the register Reg0. Data PIC0 is read. Thus, when the display position P (x, y) is in the range of (Xbgn [0], Ybgn [0]) to (Xend [0], Yend [0]), the reduced image stored in the register Reg0. Based on the start address BgnAdd [0] on the data memory, the image data PIC0 of the reduced image P0 is read, and the reduced image PIC0 indicating the character “a” is displayed in the window W0.
[0063]
The display address P (x, y) is (x ₂ , Y _Five ), The display address P (x, y) is stored in the register Reg2, and the window number wno is (wno = 2) in the display range (Xbgn [2], Ybgn [2]) to (Xend [ 2], Yend [2]), the image of the reduced image P2 from the address # 500 of the memory 14 based on the start address BgnAdd [2] on the memory of the reduced image data stored in the register Reg2. Data PIC2 is read. Thus, when the display position P (x, y) is in the range of (Xbgn [2], Ybgn [2]) to (Xend [2], Yend [2]), the reduced image stored in the register Reg2 is displayed. Based on the start address BgnAdd [2] on the data memory, the image data PIC2 of the reduced image P2 is read, and the reduced image P2 indicating the character “b” is displayed in the window W2.
[0064]
As described above, in the graphic system to which the present invention is applied, a reduced screen is formed in real time by the image processing unit 11, and this reduced screen is stored in the memory 14. Information about each window is stored in the registers Reg0, Reg1, Reg2,..., And based on the contents of these registers Reg0, Reg1, Reg2,. The thumbnail image is formed. Therefore, the thumbnail image can be displayed at high speed, and the thumbnail image can be easily changed.
[0065]
Each window number wno represents a priority order. As shown in steps S12 to S17, processing is performed in the order of the window number wno, so that a reduced image is displayed according to the priority order. For this reason, as shown in FIG. 9, when there is a window image P10 having a low priority and a window image P11 having a high priority, the priority image is displayed on the image P10 having a low priority. It is possible to display a high window image P11 in an overlapping manner.
[0066]
In the graphic system to which the present invention is applied, the thumbnails can be easily sorted by the information sent from the CPU 1 to the registers Reg0, Reg1, Reg2,. That is, when the thumbnail images composed of the reduced images P20 to P28 in the order shown in FIG. 10A are rearranged or deleted so as to become the reduced images in the order shown in FIG. 10B, The information of the start address of the reduced image of Reg0, Reg1, Reg2,... Is replaced or deleted. As described above, the thumbnail images can be easily erased and rearranged simply by rewriting the information in the registers Reg0, Reg1, Reg2,.
[0067]
In addition, when performing continuous display of thumbnails as shown in FIG. 11, when the input image is a moving image signal, if the register of the image processing unit 11 is rewritten every frame or every several frames, the memory 14 stores the past. It becomes possible to leave frame data. Therefore, continuous image display of continuous reduced images P30, P31,... Is possible by setting image data of continuous times in the registers Reg0, Reg1, Reg2,. Here, if an area where moving image data is overwritten is displayed in a window, the process of continuous shooting display can be displayed as a moving image.
[0068]
In the registers Reg0, Reg1, Reg2,... Of the display control unit 13, an enlargement / reduction ratio is stored. Using this enlargement / reduction ratio information, the moving image or still image P40 can be enlarged / reduced in real time as shown in FIG. That is, when an image is read from the memory 14 based on information stored in the registers Reg0, Reg1, Reg2,... Can be enlarged or reduced.
[0069]
Further, by combining the enlargement / reduction control and the overlapping of the windows, the effect of wipe-in / wipe-out used for scene switching can be obtained as shown in FIG.
[0070]
【The invention's effect】
According to the present invention, when displaying thumbnail images in which reduced images are arranged and displayed as a list, the reduced images are formed in real time and stored in the memory, and registers for windows are prepared. The position and size of the image and the address on the memory where the reduced image is stored are stored, and the thumbnail image is displayed while reading the reduced image from the memory using the information in this register. As described above, according to the present invention, the reduced image is formed in real time, and the thumbnail image does not need to be developed on the memory. Therefore, high-speed display is possible, and continuous shooting display and moving image display are easily performed. Can do.
[0071]
In addition, according to the present invention, since the register for storing the position and size of the window and the address on the memory where the reduced image is stored is provided, it is possible to arrange the thumbnail images only by changing the register information. You can easily change, add, delete, and change the size and position of the window frame. Furthermore, the display can be enlarged and reduced by changing only the register information, and wipe-in and wipe-out can be performed.
[Brief description of the drawings]
FIG. 1 is a block diagram of an example of a GRAPHIG system to which the present invention is applied.
FIG. 2 is a block diagram showing a configuration of an image processor to which the present invention is applied.
FIG. 3 is a functional block diagram used to describe an image processor to which the present invention is applied.
FIG. 4 is a flowchart used to describe an image processor to which the present invention is applied.
FIG. 5 is a flowchart used to describe an image processor to which the present invention is applied;
FIG. 6 is a schematic diagram used for explaining reduced addresses on a memory in an image processor to which the present invention is applied;
FIG. 7 is a schematic diagram used for explaining thumbnail display in the image processor to which the present invention is applied;
FIG. 8 is a schematic diagram used for describing a register in an image processor to which the present invention is applied;
FIG. 9 is a schematic diagram used for explaining window overlap control;
FIG. 10 is a schematic diagram used for explaining rearrangement display of thumbnail images;
FIG. 11 is a schematic diagram used for explaining continuous shooting display;
FIG. 12 is a schematic diagram used for explaining enlargement / reduction display;
FIG. 13 is a schematic diagram used for explaining a wipe-in / wipe-out display;
FIG. 14 is a block diagram of an example of a conventional graphic system.
FIG. 15 is a schematic diagram used for explaining conventional thumbnail display;
FIG. 16 is a schematic diagram used for explaining conventional thumbnail display;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 2 ... Image processor, 11 ... Image processing part, 12 ... Image writing part, 13 ... Display control part, 14 ... Memory, Reg0, Reg1, Reg2 ... Register

Claims (6)

A first storage means images data is stored in plural numbers,
The related image data stored in the first storage means, a storage location within the first storage means, a display position for arranging the image data of the upper Kifuku number on the same screen, scaling factor Doo and second storage means stored in association with each upper Kiga image data,
Comparison means for comparing the display position for each image data stored in the second storage means with an arbitrary position on the screen;
Determine the images data that corresponds to an arbitrary position on the screen based on the comparison result of the comparing means, sequentially the images data determined above on the basis of the stored position stored in the second storage means Read control means for controlling the enlargement / reduction of the image data in accordance with the enlargement / reduction ratio when reading from the first storage means;
An image display device comprising a display means for displaying the images data read from the first storage means by said read control means. An editing instruction means for instructing the editing control for a plurality of images displayed on the screen of the display means,
The image display apparatus according to claim 1 comprising a updating means for updating the display position of each each image data stored in said second storage means in response to an instruction of the editing instruction means. The image display apparatus according to claim 2 , wherein the editing instruction is an erasing operation or a rearranging operation. Said further comprising a second update means to update the scaling factor for each each image data stored in the storage means, performs enlargement or reduction display of images by the update of the scaling factor The image display device according to claim 1 . Image of claim 1, wherein the second further comprising an updating means for updating the scaling factor for each each image data stored in the storage unit, performs a wiping operation by the update of the scaling factor Display device. Storing a plurality of image data in the first storage means;
Regarding the image data stored in the first storage means, the storage position in the first storage means, the display position when arranging the plurality of image data on the same screen, and the enlargement / reduction ratio Each image data is stored in association with the second storage means,
The display means for each image data stored in the second storage means and an arbitrary position on the screen are compared by the comparison means,
Image data corresponding to an arbitrary position on the screen is determined based on the comparison result in the comparison means, and the image data determined based on the storage position stored in the second storage means is sequentially applied to the first data. When reading from the storage means, the reading control means controls the enlargement / reduction of the image data according to the enlargement / reduction ratio,
An image display method for displaying image data read from the first storage means by the read control means on a display means.

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