MXPA97004570A - Method and apparatus for processing a cua - Google Patents

Abstract

The present invention relates to a method and apparatus for processing a frame, wherein the image data is stored as the cell data of the frame data, so that an operation and method for processing the image data as the data of cell (e.g., an image data image process or an image cell output designated cell) can be simple. In the process of outputting the data of the table, it is discriminated if the type of the designated cell is numeric, character, image or sound, the corresponding data is read from a data file of the frame, an image file or a file of sound in accordance with the cell type discriminated, and the reading data is sent to an output region of the cell designates

Description

"METHOD AND APPARATUS FOR PROCESSING A PICTURE" TECHNICAL FIELD The present invention relates to a method and apparatus for processing a frame in units of cells constituting the frame, and more particularly, with a method and apparatus for processing a frame that allows an image data process in units of cells in a frame. data processing apparatus.

ANTECEDENTS OF THE TECHNIQUE In a conventional frame processing apparatus incorporated in a computer system or the like, which has a function of forming a frame in units of cells, the types of data entry to the cells constituting the frame are limited to two: numerical data and of character. If the numeric or character data (cell data) is to be mixed with another type of data (eg, image or sound data) in the table, the last type of data is expressed in a structure method and administration of data different from those of the cell data.

For example, an operation to avoid the normal cell data is restricted within cell boxes. On the other hand, in the case of expressing the image data in a frame, an arbitrary region independently of the cell frames is established as an image data frame and an operation of pasting the desired image data in the frame is required. of image data. The image frame data and the image data are processed by the structure and data management method different from those of the processing of the numerical cell data and character of the frame. The conventional box processing apparatus described above has the following disadvantages. To incorporate the data other than the numerical data of character (eg, image or sound data) in a table, the data is processed by the method of structure and data management different from those of the data processing of data. numeric and character cell. In this way, for example, in order to avoid the cell data when the image data or the sound data is incorporated in the frame, it will be difficult for the user to understand an operation for the aforementioned object due to the difference between the operations to process the numerical character data, the image or sound data and the operating procedures are complicated.

In this way, the operation of treating the image data and the sound data in the process of forming a frame is complicated resulting in low functionality of the frame processing apparatus.

EXHIBITION OF THE INVENTION An object of the present invention is to provide a method and apparatus for processing a frame, wherein the image data is stored as a cell data of the frame data, so that an operation and procedure for processing the image data as the data of cell (e.g., a process of image of the image data or an output of the image data to a designated cell of the frame), can be simple and the way of expressing the cell data can be diversified. In accordance with the present invention, there is provided a method for processing the frame data in a form consisting of a plurality of cells, the method comprising the steps of storing the data including the image data in a storage device in order to corresponding respectively to the cells of the data of the table; discriminate whether the data in a designated cell of the data of the table to be processed is a numerical data, a character data or an image data; if the data in the designated cell is discriminated as the image data, produce an image based on the image data stored in the storage device to correspond to the designated cell; and send the produced image to an exit region of the designated cell.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a functional diagram of a computer system according to a first embodiment of the present invention; Figure 2 is a diagram showing a data structure of the cell data stored in the data file of the table shown in Figure 1; Figure 3 is a flow chart of an image definition process executed by the computer system of the first mode; Figures 4A to 4C are diagrams showing image definition input screens presented in a display device through the image definition process shown in Figure 3; Figure 5 is a diagram showing the structure of the image data stored in an input data region shown in Figure 2, by the image definition process shown in Figure 3; Figure 6 is a flow chart showing a table data output process executed by the computer system of the first mode; Figure 7 is a diagram showing an example of the presentation data presented in the display device by the process of outputting the frame data shown in Figure 6; Figure 8 is a diagram showing a data structure of the cell data processed by the computer system according to a second embodiment of the present invention; Figures 9A to 9C are diagrams showing the examples of modified images by the cell attribute modification information shown in Figure 8; Figure 10 is a flow chart showing a data output process executed by the computer system of the second mode; and Figure 11 is a diagram showing an example of the presentation data presented in the display device by the process of outputting the frame data shown in Figure 10.

BEST WAY TO CARRY OUT THE INVENTION (First Modality) A first embodiment of the present invention will be described with reference to Figures 1 to 7. First, the structure of the modality will be described. Figure 1 is a functional diagram of a computer system 1 according to the first embodiment. As shown in Figure 1, the computer system 1 comprises a CPU (Central Processing Unit) 2, an input unit 3, a mouse 4, a ROM 5, a processing work memory 6, a file 7 of frame data, an image reader 8, a printing unit 9, a sound conversion unit 10, a loudspeaker 11, a presentation unit 12, an image file 13 and a sound file 14. These components are connected to a collector bus 15. The CPU 2 controls the components of the computer system 1 and carries out the various information processes in accordance with the control programs stored in the ROM 5. When a process is carried out of frame formation, the CPU 2 causes the items, the numerical values and the formula entry through the input unit 3 and the mouse 4 to be stored in the frame data file 7 through the calculation processes of frame. When a frame data output process (to be described later) is carried out, CPU 2 discrames the cell type of a designated cell of the frame; that is, if the cell stores the numeric data, the character data, the image data or the sound data. In accordance with the type of discriminated cell, the CPU 2 reads the corresponding data from the file 7 of the frame data, the image file 13 and the sound file 14 and sends the reading data to the output region of the unit 12 of presentation that corresponds to the designated cell of the table. When a frame definition process is carried out (to be described later), the CPU 2 causes the display unit 12 to present a sub-window for image definition so that the file name of the corresponding image is displayed. to the cell, subject to image definition, can be designated. Then, the CPU 12 reads the image data corresponding to the name of the image file designated from the image file 13 to carry out an image data editing process and sends the edited image to the output region of the image. designated cell in order to present it in the box. The image data defined by the image definition in the designated cell is stored in an input data region of the cell data shown in Figure 2, in the form of the data structure to be described later. The input unit 3 comprises function keys, numeric keys, character keys and others. It sends to the CPU 2 the different instruction signals that correspond to the user's key input operations. The mouse 4 is an indicating device for carrying out supplementary operations on entry through the input unit 3. It sends operation signals to the CPU 2. The ROM 5 stores the different control programs executed by the CPU 2, an output processing program of the frame data and an image definition processing program. The processing work memory 6 forms a memory region to prevent the output of the image data from the image file 13 when the CPU 2 performs the output process of the frame data. The file 7 of the frame data to the numeric character or image data is admitted, it stores the data of the frame constituted by a plurality of cell data processed by the CPU 2. The data structure of the stored cell data is shown in Figure 2. With reference to Figure 2, the cell data is constructed by regions to store the cell position coordinate data (two dimensional coordinates (X, Y)) that represent the position of a cell in the table; the cell type data representing the cell data type (eg, 0: numerical data, 1: character data, 2: image data, 3: sound data); the "direct" or "indirect" data, the cell attribute data; the real data, that is, the numerical input data, image character or sound. The "direct" data means that the image or sound data is stored in the input data region as cell data, while the "indirect" data means the image or sound data is stored in the image or image file 13. the 14 sound file. The cell attribute data includes the character size data (v.gr., 0: 8 point, 1: 10 point), the character style data (v.gr., 0: Ming style, 1: style) Gothic), the plotting data (v.gr., 0: left justification, 1: centered, 2: right justification) and the data in numerical form (0: normal, 1: three-digit scores). The image reader 8 scans an original game to be read, reads an image therein as a predetermined resolution and stores the reading image in the image file 13 as image data.

The printing unit 9 prints an output of the frame data through a frame output process executed by the CPU 2 on a sheet of paper. The sound conversion unit 10 converts, in a sound signal, a sound data that is sent as a result of the data output process of the frame executed by the CPU 2, when the content of the cell data in the designated cell is a sound data. It sends the sound signal through the loudspeaker 11. The presentation unit 12, comprising a CRT (Cathode Ray Tube) presents the input data of the key through the CPU 2 and the data of the developed chart. The file 13 of the image is a memory that stores a plurality of image data read by the image reader 8. The sound file 14 stores a plurality of sound data to be sent to the cells. An operation of the first mode will now be described. First, an image definition process executed by the computer system 1 will be described with reference to the flow chart shown in Figure 3. In the image definition process shown in Figure 3, when an object cell image definition (in this mode the cell coordinates C3) is designated in the datum of the table presented on the display screen of the presentation unit 12 by a predetermined operation of the input unit 3 or the mouse 4 (Step YES) ), a drop-down menu is presented including the article "Definition of Image" in the datum of the table as shown in Figure 4A. When the article "Image Definition" is selected from the drop-down menu (Step S2), a subwindow is superimposed for image definition in the frame data as shown in Figure 4E (Step S3). The sub-window for image definition includes definition items such as "File Name", "Amplification" (XL, YL), and "Rotation" that must be accepted by the user. By means of the article "File Name", the name of an image data file stored in the image file 13 is designated. By means of the article "Amplification" is meant an amplification of the presentation of an image to be sent in the region of output of the designated cell position in the X (horizontal) and Y (vertical) directions.

Through the article "Rotation", placement is designated (e.g., a rotation angle of 90 ° C) of the image to be sent in the output region of the designated cell position.

When the definition articles are admitted in the sub-window for image definition (Step S4), the image data corresponding to the input display name is read from the image file 13 to the processing work memory 6 (Step S5). The read image data is avoided in accordance with the amplification definition items and the rotation input in step S4 (Step S6). Subsequently, the edited image is sent from the processing work memory 6 to the designated cell position and the image is presented in the output region of the designated cell C3 of the frame data presented in the presentation unit 12 (Step S7). ), In this way, the process is completed. The image data presented in the designated cell has the data structure as shown in Figure 5. The cell data is stored in the input data region as shown in Figure 2, which corresponds to cell C3 designated of file 7 of the frame data. With reference to Figure 5, the image data is constituted by a portion of header information and a portion of image substance. The header information portion stores the control data necessary to present the image, such as the number of points (size) in the X and Y directions, resolution and placement as defined in Step S4. The image susbtance portion stores the actual data of the image data edited in Step S6. A table data output process executed by computer system 1 will be described with reference to the flow chart shown in Figure 6. FirstWhen the name of a file of the frame data presented in the presentation unit 12 is designated by a predetermined operation "of the input unit 3 or the mouse 4, the data of the frame corresponding to the designated file name is retrieved from the file 7 of the table data The cell data of each of the cells that constitute the recovered frame data is obtained (Step Sil), then determined with reference to the coordinates of the cell position of the cell data obtained , if the cell is included in a preset frame data cell region (Step S12) As a result of the determination, if the cell is not included in the cell region of the predetermined frame data, the process is given by If the cell is included in the cell region of the default frame data, the type of the data stored in the input data region of the discriminated cell data (whether the data is of numerical type, character, image or sound) with reference to the cell type data set in the cell data (Step S13). If the cell type is discriminated as the numeric or character type, the numeric character data stored in the input data region of the cell data is read and presented in the designated cell (Step S14). Then, the process returns to the Sil Pass. If the cell is discriminated as the type of image, it is determined whether the image data is indirect or not with reference to the "direct / indirect" data (Step S15). If the image data is the direct data, that is, if the image data is stored in the input data region, and the output region of the designated cell is sent in accordance with the header information of the image data (Amplification of presentation in the X and Y directions, resolution and placement) (Step S18). The process then returns to the Sil Pass. If the image data is the indirect data, that is, if the image data is not stored in the input data region, the image data corresponding to the name of the image file stored in the input data region is reads from the image file 13 to the processing work memory 6 (Step S16). The read image data is avoided in accordance with the image definition designated in Step S4 (Step S17). The edited image data is sent to the output region of the designated cell and is presented (Step S18). The process then returns to Paso Sil. If the cell discriminates as the type of sound in Step S13, it is determined whether the sound data is indirect or not with reference to the "direct / indirect" data (Step S19). If the sound data is the direct data, that is, if the sound data is stored in the input data region, it is read from the input data region and sent to the sound conversion unit 10. The sound data is converted into a sound that is sent through loudspeaker 11 (Step S21). Then, the process returns to the Sil Pass. If the sound data is the indirect data, that is, if the sound data is not stored in the input data region, the sound data corresponding to the name of the sound file stored in the input data region is reads from sound file 14 (Step S20). The read sound data is sent to the sound conversion unit 10. The sound data is converted into a sound that is sent through loudspeaker 11 (Step S21). Then, the process returns to the Sil Pass. The process of Steps S13 to S21 mentioned above is repeated with respect to all the cells in the frame data to send the cell data to the respective cells. Then, if it is determined in step S12 that there is no cell in the data region of the frame, the output process of the frame data is terminated. The process of outputting frame data, as described above, is carried out repeatedly in order to read the pre-stored numeric, image character and sound data., in accordance with the cell types (numeric, image character or sound) established for the respective cells that form the data of the frame, and are presented in the presentation unit or sent as a sound. Figure 7 shows an example of the presentation data presented in the presentation unit 12 through the process of outputting the datum data. In Figure 7 the numerical data of character are presented in the coordinates Al to A3 and Bl to B3 of the cell and the image data are presented in the coordinates Cl to C3 of the cell. In this way, with the frame processing function incorporated in the computer system 1 of the first mode, the image data and the sound data as well as the numerical and character data can be processed as the cell data of the data of the box. Therefore, the operations and methods for processing the image data and the sound data in the processing of the frame can be simpler compared to the conventional technique. In addition, the way to express the cell data can be more diversified thus improving the function of processing the table and increasing convenience. In the first embodiment described above, the image data and the sound data are presented or sent as a sound in the output region of the designated cell position. However, the animation data may be presented as the cell data if it is pre-stored in the image file 13. In addition, the image data, the sound data and the animation data can be processed not only individually but can be combined with each other so that the combination of these data can be presented or sent as a sound. Therefore, the way to express the cell data can be much more diversified.

(Second Mode) A second embodiment of the present invention will be described with reference to Figures 8 to 11. Since the structure of the computer system block of this embodiment is the same as that of the computer system 1 of the first embodiment, it is they omit a drawing of the structure and a description of the functions of the same.

Figure 8 is a diagram showing a structure of the data of the cell data stored in the file 7 of the data of the computer system 1 table shown in Figure 1. With reference to Figure 8 the cell data is constructed by regions to store the data of the coordinate of the cell position (two dimensional coordinates (X, Y)) that represent the position of a cell in the box; the cell type data representing the cell data type (eg, 0: numerical data, 1: character data, 2: image data, 3: sound data, 4: animation data); the cell attribute data; the input data, that is, the numerical, character, image or sound input data; and the formula data to indicate the way to synthesize the numerical, image and sound data. The cell attribute data includes the character size data (v.gr., 0: 8 point, 1: 10 point), the character style data (v.gr., 0: Ming style, 1: style) gothic), the layout data (v.gr., 0: left justification, 1: centered, 2: right justification) and modification information (0: normal, 1: inverted, 2: specular, 3: closing) . The fibers 9A to 9C show examples of images based on the modification information.

Figure 9A shows a case in which the modification information is set up to "1: inverted", so that the image is presented inverted. Figure 9 shows a case in which the modification information is set to "2: speculate", so that the image is presented as a mirror image (symmetrically). Figure 9C shows a case in which the modification information is set to "3: closing" so that the image is presented with an envelope (it is emphasized with a box). The formula data shown in Figure 8 represents a content of the synthesized data of the image data or sound data with a simple formula. For example, the "+" operator means a process of bit OR of images to be synthesized and the successive generation of the sound of a cell on the left side and that of a cell on the right side. The operator "*" means an AND process of the "AND" bit of images to be synthesized. An operation of the second mode will now be described. A data output process of the frame executed by the computer system of the second mode will be described with reference to the flow chart shown in Figure 10.

First, when the name of the data file of the table presented in the display unit 12 is designated by a predetermined operation of the input unit 3 or the mouse 4, the data of the table corresponding to the name of the designated file is retrieved from the file 7 of the data of the box. The cell data of each of the cells that constitute the data of the recovered frame is obtained (Step S31). Then, it is determined, with reference to the coordinates of the position of the cell of the cell data obtained, whether the cell is included in the cell region of the data of the preset table (Step S32). As a result of the determination, if the cell is not included in the cell region of the table data, the process is terminated. If the cell is included in the cell region of the datum data, the type of data stored in the input data region of the cell data is discriminated (with respect to whether the data is of a numerical type of image or sound character). ) with reference to the cell type data set in the cell data (Step S33). If the cell type is discriminated as a character, the process proceeds to step S38 where the character data stored in the input data region of the cell is read if it is presented in the output region of the cell designated in accordance with the items set in the cell attribute ( character size, character style, layout information and modification): Then, the process returns to Step S31. If the cell type is discriminated as numeric, it is determined whether the formula data is set in the designated cell (Step S34). If the formula data is not set in the cell, the process proceeds to Step S38, where the numerical data stored in the input data region of the cell is read and presented in the output region of the designated cell, in accordance with the items set in the cell attribute (character size, character style, and layout and modification information). Then, the process returns to step S31. If the formula data is set in the designated cell, the numerical data in the respective cells contained in the formula is read (Step S35), the calculation of the numerical data of the respective cell is carried out in accordance with the formula (Step S36) and the result obtained by the calculation is stored in the input data region of the corresponding cell as the numerical data (Step S37). The numerical data stored in the input data region is read and displayed in the output region of the designated cell in accordance with the items set in the cell attribute (the character size, the character style, the diagramming and modification). Then, the process returns to Step S31. If the cell type is decremented as the image type in Step S33, it is determined whether the formula data is set in the designated cell (Step S39). On the other hand if the formula data is not set in the cell, the process proceeds to step S46 where the image data stored in the input data region is read back to the processing work memory 6. Then, the read image data is subjected to a modification process in accordance with the modification information set in the cell attribute of the cell, and a modified image pattern is stored in the processing work memory 6 (Step S42). ). Subsequently, it is checked whether the numerical or character data is stored in the input data region (Step S43). If the character numeric data is not stored in the input data region, the process proceeds to step S47, wherein the modified image pattern is read from the processing job memory 6 and stored in the input region of data of the cell as the entry data. The modified image stored in the input data region is read and displayed in the output region of the cell (Step S45). Then, the process returns to Step S31. If the formula data is set in the cell designated in Step S39, the image data in the respective cells contained in the formula are read (Step S40), and the image data of the cells is processed in a pattern (Step S41). Subsequently, the processed image is subjected to a modification process in accordance with the modification information set in the attribute of the cell of the cell and a modified image pattern is stored in the processing work memory 6.

(Step S42). Then, it is checked whether the numeric or character data is stored in the input data region of the cell (Step S43). If the character numeric data is not stored, the process proceeds to step S47, wherein the pattern of the modified image is stored in the input data region of the cell as the input data. The modified image is read from the input data region and is presented in the output region of the cell (Step S45). Then, the process returns to Step S31. An example of the process of synthesizing the image data using a formula will be described with reference to the data shown in Figure 11.

In the example of the frame data shown in Figure 11, the image data are presented respectively in the coordinates Al and Bl of the cell. If the formula "D1 = A1 + B1" as shown in Figure 11 is established using the Al and Bl coordinates of the cell as variables, the images of the Al and Bl coordinates of the cell are added together and synthesized and presents an image synthesized in the DI coordinates of the cell. If the formula "D3 = A1 + (2XB1)" is set as shown in Figure 11, the image of the Al coordinates of the cell is added to an amplified Bl image twice (synthesized with), and the synthesized image is presented in the D3 coordinates of the cell. The following are examples of cases where other formulas are established. If the formula "D3 = A1X (-2)" is established, an image 1/2 Al is presented in the coordinates D3 of the cell. If the formula "D3 = A1 + 10" is established, a 10-point Al image is displayed shifted to the right at the cell's D3 coordinates. If the formula "D3 = A1-10" is established, a 10-point Al image is displayed displaced to the left at the D3 coordinates of the cell. If the formula "D3 = INV (A1)" is set, an inverted pattern image Al is presented at the cell's D3 coordinates.

The sound data in the cells can also be synthesized using a formula in the same way. The process of outputting the frame data as described above is carried out repeatedly so that the pre-stored numerical cell data of image and sound character are read in accordance with the cell types (numeric character of image or sound) established for the respective cells that constitute the datum of the picture, and are presented or sent as a sound. In addition, the image data and the sound data are synthesized in different patterns based on the modification information in the cell attribute data set in the cell data or the formula data, and are presented or sent as a sound. In this way, with the frame processing function incorporated in the computer system of the second embodiment, the image data and the sound data as well as the numerical and character data can be processed as cell data of the frame data and Different synthetic patterns of the cell data are established and presented. Therefore, the operations and methods for processing the image data and the sound data in the processing of the frame can be simpler compared to the conventional technique. In addition, the way of expressing the cell data can be further diversified thereby improving the processing function of the box and increasing convenience. In the second embodiment described above, the image data or the sound data or the synthesized data thereof are presented or sent as a sound in the output region of the designated cell position. However, the animation data can be synthesized and presented as the cell data if it is pre-stored in the image file 13. In the first and second mnodalities, the image data is sent as a presentation data in the data of the table presented in the presentation unit 12. However, the image data may be sent as a print data through the printer unit 9. further, in the aforementioned embodiments, the different control programs, the output processing program of the frame data and the image definition processing program are stored in the ROM 5 shown in FIG. 1. However, these programs can be stored in another memory device having a memory medium in which programs and data are pre-stored. The memory medium is formed of a magnetic or optical memory medium or a semiconductor memory. The memory medium can be fixed to the memory device or detachably fixed thereto.

The programs or data may be supplied to and stored in the memory medium from another device connected to the memory device through a communication line or the like. The other device connected to the memory device through the communication line may comprise a memory device including a memory means, so that the programs and data stored in the memory means may be used by the apparatus of the present invention. invention, through the communication line. The memory means stores, in the form of program codes that the CPU can read, programs to achieve the functions indicated in the flow charts shown in FIGS. 3, 6 and 10 which illustrate the operations of the first and second modes of operation. the present invention.

Claims (7)

R E I V I N D I C A C I O N E S:

1. A method for processing the data of the table in a form of a table consisting of a plurality of cells, the method comprises the steps of: storing the data including the data of the image in a storage dipsositivo so as to correspond respectively cells of the picture data; discriminate whether the data in a designated cell of the data of the table to be processed is a numerical data, a character data or an image data; if the data in the designated cell is discrimated with the image data, produce an image based on the image data stored in the storage device to correspond to the designated cell; and send the produced image to an exit region of the designated cell.

2. A method for calculating the data of the table in a form of a table consisting of a plurality of cells, the method comprising the steps of: storing the data in a storage device so that it corresponds respectively to the cells in the picture; establish a table calculation formula, use cells to which the data of the image corresponds as variables in a cell that is not even the cells in which the data is admitted; when a calculation is carried out based on the calculation formula of the table, read the data of the image corresponding to the cells that correspond to the variables included in the formula of the calculation of the table; processing the image data read by an image based on the formula of the frame calculation; and sending the image data processed by means of an image to the output region of the cell where the formula for calculating the table is established.

3. A frame processing apparatus for processing the frame data in a form of a frame consisting of a plurality of cells, the apparatus comprising: a first storage means for storing the image data with the middle of the file the picture; a second storage means for successively storing the input of the data so that it corresponds respectively to the cells; a designation means for designating the image definition data including an image file name to a designated cell in which the image data will be sent; a first reading means for reading from the first storage means the image data having the name of the image file designated by the designation means; a writing means for writing the image data read by the first reading means together with the image definition data in a storage region of the second storage means corresponding to the designated cell; a first means of discrimination for each time a cell is designated in the table, discriminating a content of the data in the second storage medium corresponding to the designated cell; a second reading means for reading the image data together with the image definition data when the first discriminating means discriminates that the data in the designated cell is the image data and the image data is stored in the second medium storage; an image editing means for editing the read image data based on the image definition data read together with the image data; and a first output means for sending the data edited by the image editing means to an output region of the designated cell.

The frame processing apparatus according to claim 3, further comprising a third reading means for reading the image data from a first storage medium with the name of the file stored in the second storage medium as the image definition data corresponding to the designated cell, when the first discrimination means discriminates that the designated cell is an image cell and the image data is not stored in the storage region of the second storage means corresponding to the designated cell.

The frame processing apparatus according to claim 3, further comprising: a second discrimination means for discriminating whether the image modification data is added to the data corresponding to the designated cell in the second storage medium; an image modification means for, when the second discrimination means discriminates that the image modification data is added to the data of the cell designated to modify by image the image data edited by the image editing means based on the data of image modification; and a second output means for sending the image data modified by the image modification means to the output region of the designated cell.

6. A memory medium that includes computer readable program codes for processing the frame data in a form of a frame consisting of a plurality of cells, the memory means comprising: a storage data of the readable program code by the computer that includes the data of the image in a storage device so that it corresponds respectively to the cells of the data of the frame; a computer-readable program code to discriminate whether the data in a designated cell of the data of the table to be processed is the numerical data, the character data or the image data; a computer readable program code so that if the data in the designated cell is discriminated as the image data, produce an image based on the image data stored in the storage device to correspond to the designated cell; and a computer readable program code for sending the produced image to an output region of the designated cell.

7. A memory medium that includes computer readable program codes for calculating the data of the table in a form of a table consisting of a plurality of cells, the memory means comprising: a computer readable program code for storing the data in an input of the storage device to correspond respectively to the cells in the frame; a computer readable program code to establish a formula for calculating a table, using cells to which the image data corresponds as variables, in a cell other than the cells in which the data is admitted; a computer-readable program code so that when a calculation is carried out based on the calculation formula of the table, the reading of the image data corresponding to the cells corresponding to the variables included in the table calculation formula; a computer readable program code for the image processing of the reading image data based on the calculation formula of the frame; and a computer readable program code for sending the image data processed by images to an output region of the cell where the formula of the frame calculation is established.