JPH0490070A - Graphic processing method - Google Patents

Abstract

PURPOSE:To generate an appropriate graphic pattern by determining the attribute of a sampling point to be inserted based upon the attribute of its adjacent sampling points in accordance with an instruction for inserting the sampling point. CONSTITUTION:When M1 and M2 are specified as two adjacent points, the section E1M1M2E2 is changed to the section E1M1M3M2E2 as the result of a sampling point. A preferable example for the position of an insertion point is an intermediate point between the two adjacent points and the point attribute of the sampling point to be inserted is determined by the following rule. Namely, when two adjacent points are end points as shown in the section D2, the point attribute of the inserting point is determined as an end point because the specified section is a segment, and when either one or both of two adjacent points are intermediate points, the specified section becomes a curve and the point attribute of the inserting point is determined as an intermediate point. Thus, an appropriate graphic pattern can be generated.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to a graphic processing method for graphic editing.

[Prior Art] In order to handle characters in electronic devices such as word processors, workstations, and printers, character sets (fonts) are usually used in units of typefaces.
For this reason, it is necessary to prepare a very large number of character data.Especially in the case of Japanese fonts, each font must contain at least about 6,500 characters as specified in the JISXO208r Kanji Code System for Information Exchange. Moreover, unlike the bitmap method, the method of expressing characters using outline data has the advantage of being able to output characters of any size using a single type of character capital, so the outline character data used as the character capital has the ability to improve the aesthetics of the character. In some cases, stricter designs than analog original characters are required to maintain the same character.

The creation of photos based on these factors is largely manual work, and the work time required for each character can range from tens of minutes to even several hours, making it extremely inefficient.

In addition to the above fonts, when editing characters, figures, etc.,
Basically, the following functions can be considered.

First, there is digitization, a function that optically scans the basic analog character pattern to create binary digital data and generate character outline data.

Next, there is a function to create final outline data with the desired quality by editing the editing outline data generated and created by character production, that is, digitization.

However, the graphic processing described above has the following problems. Conventionally, when inserting a point at a desired position in a series of points representing a graphic pattern, it is necessary to erase the -degree curve or straight line,
It was very cumbersome to operate, as it was necessary to create only a point sequence, insert points, and specify attributes such as whether they were curved or straight lines.

[Purpose] In view of the above points, an object of the present invention is to provide a graphic processing that can automatically determine the attributes of the position where a sample point should be inserted and, by extension, generate an appropriate graphic pattern. The purpose is to provide a method.

〔Example〕

[Block diagram of graphic editing device] The graphic editing device according to the present invention will be explained in detail below using the drawings.

FIG. 1 is a block diagram of a graphic editing device to which the present invention is applied. Note that the graphics in the present invention include characters and other images. Furthermore, the various operations in the present invention can be applied to operations in all types of equipment such as copying machines, fax machines, and printers. Furthermore, when applying the present invention, each configuration of the block diagram shown in FIG. 1 is not limited to this.
Needless to say, other equivalent devices are also good. It may be composed of one device or may be composed of a plurality of devices. It also includes a case where the functions of the present invention are achieved by supplying a program to equipment such as a workstation. Also,
It includes both a graphic processing method and a graphic processing device.

1 is a control unit of this graphic editing device, 2 is an interface with a hard disk, etc., and RAM (RandomA
(c)
Internal memory, i.e. program memory, consisting of etc.
PMEM6, external storage device 3 such as hard disk, CP
It consists of U (central processing unit) 15. In addition, P
The MEM6 stores a program represented by a flowchart described later.

Reference numeral 7 denotes an image input device, for example, a document reader that converts an image document placed on a document table into an electrical signal. 4 is an interface between 7 and the system bus. 8 is an image input section including these.

Reference numeral 13 denotes a CRT device, which is an image processing display section in this graphic processing device. In addition, 12 is a PD (pointing device) for instructing editing of image information on the CRT 13, and by moving the cursor on the CRT la arbitrarily in the X1Y direction and selecting a command image etc. on the command menu, It is also possible to input any point of the figure displayed on the CRT 13 as coordinate information. Reference numeral 11 denotes a device that accepts key input, such as a keyboard.

14 is a VRAM (video memory), which expands the data to be displayed on 13 on a bitmap.

Reference numeral 9 denotes a printer, which outputs a hard copy of the image processing results in this graphic editing system. 5 is an ink face part with 9. 10 is an image data output section. It goes without saying that the printer may be a laser beam printer or a bubble sheet printer that prints using ink.

Hereinafter, a case will be described in which a character pattern is processed as an example of a graphic.

[Functional Configuration Diagram] FIG. 2 is a configuration diagram conceptually representing each function of the graphic editing device to which the present invention is applied.

In FIG. 2, file creation S1 secures an area for storing character data, that is, an original data file and a font data file, on DISK 3.

Digitizing S2 reads the original from the image input device IR7, converts it into bitmap data, and performs an extraction process to be described later to form it so that it can be received in character production S3, which will be described later. Store in files and font data files.

Character production S3 is the DI created in the digitizing S2 mentioned above.
Load the original data file and font data file of SK 3 into PMEM6, edit the editing section using each function described later, and register the edited original data and font data in the DI S K 3 original data file and font data file, respectively. do.

In the screen inspection S4, the font data created in the character production S3 is read from the DISK 3 to the PMEM 6, processed, written to the VRAM 14, and displayed on the CRT 13.

The printer output S5 reads out the font data created in the character creation S3 from the DISK 3 to the PMEM 6, processes it, and outputs it to the PRT 9.

The utility S6 edits and manages the original data file and font data file created in the digitizing S2 and the original data file and font data file created in the character creation S3.

Control S7 is a control unit that controls each of the above-mentioned functions.

Hereinafter, the characteristics of each of the above-mentioned functions will be explained using FIGS. 3 to 7.

[Digitizing] The digitizing S2 has various functions as shown in FIG. 3, namely, scanning 52-a, code setting 52-b, center setting 52-c, noise removal 52-d, and contour line generation 52-e.
It consists of each step.

The scan 52-a scans the original using the IR 7 and stores the image data in the DISK 3.

The code setting 52-b sets a character code to the image data of each character read by the scan 52-a.

The center setting 52-c sets the center of the character, that is, the body frame, for each character in the image data of each character.

The noise remover 52-d edits the image data of each character.

The contour generation 52-e generates original data (details will be described later) and contour lines (details will be described later) from the image data of each character, and stores them in the original data file and font data file of the DISK 3, respectively.

[Character production S3] Next, character production S3 in FIG. 2 will be explained.

The character creation S3 has various functions as shown in FIG. Character production S3 can be roughly divided into functions according to their properties: display control S3;
8. Character data correction S9, character information display 5IO1 character information related input/output Sll, character data registration/termination S12.

The display control S8 has a function of controlling the display during character data correction 89, which will be described later, that is, controlling the state of characters displayed on the CRT 13. That is, scroll 58-a, zoom 58
-b, standard size 58-c, original ON/OFF
58-d, sample point 0N-OFF 58-e, outline/filling 58-f, curve display/straight line display 58-g
.

Line ON/OFF 58-h, cursor 0N-OF
FS8-i, redisplay 58-j.

The scroll 58-a is for scrolling the display screen.

The zoom 58-b is for enlarging or reducing the display screen.

The standard size 58-c is for displaying characters being scrolled, enlarged, reduced, etc., in a predetermined size and position on the screen.

The original 0N-OFF 58-d is A- in the editing area of the CRT 13 shown in FIG.
1-1 is used to switch between displaying and not displaying the aforementioned original data.

Sample point ON/0FFS8-e is character data correction 8
At 9:00, it is switched whether or not to display sample points, which will be described later, in the editing area of the CRTI 3, which will be described later.

Outline/Fill 58-f is used to display the font data displayed in A-1-1 in the editing area (Figure 30) of the CRT 13 later as an outline or fill out the inside of the character when modifying character data 89. This is used to switch whether to display the status.

The curve display/straight line display 58-g is used to display the font data currently displayed in A-1=1 in the edit area (Fig. 30) of the CRTL 3, which will be described later, as a contour line when modifying character data 89, or to simply display a straight line between sample points. This allows you to switch between displaying a collection of straight lines connected by .

Line 0N-OFF 58-h is character data correction 8
A-1- in the editing area in Figure 30 of the CRT 13 at 9 o'clock
1, it is used to switch whether to display or not display the body frame and various lines set in line setting 5ll-b, which will be described later.

Cursor ON/0FFS8-i is character data modification 89
At times, the cursor displayed in the editing area Al-1 in FIG. 30, which will be described later, of the CRT 13 is switched between a small cursor and a full-screen long crosshair cursor.

The character data modification S9 has a function of editing the font data itself, such as editing sample points, editing outlines, and line segments. That is, point insertion 59-a, point deletion 59b, point attribute reversal 59-C, point movement 59-d, point alignment 59-e, outline deletion 59-f, and outline movement 59-g.

Virtual line generation 59-h, circular arc formation 59-i, figure generation 59
-L center S9-, undo/redo 59-
It is 1.

Point insertion 59-a is for inserting a sample point at an arbitrary location on the contour.

Point deletion 59-b is performed when there is one arbitrary sample point t, Nl'
It divides a line segment consisting of multiple sample points by 1.

The waste inversion 59-c changes the attribute of an arbitrary sample point from an end point to an intermediate point or from an intermediate point force 1 to an end point.

Point movement 59-d is for moving an arbitrary sample point, that is, changing the coordinates of the sample point.

Point alignment 59-8 is the X coordinate of an arbitrary sample point, or
This is to match the coordinates of one or more other specified sample points to the coordinates.

The contour line erasure 59-f is to remove an arbitrary contour line.

The contour line movement 59-g is for moving an arbitrary contour line segment, that is, changing the coordinates.

The virtual line generation 59-h generates a contour line on an arbitrary editing area.

The regular arc conversion 59-4 is for converting a line segment of an arbitrary shape in an arbitrary portion into a computationally optimal regular ellipse.

The figure generator 59-j generates a contour line of a perfect circle, polygon, etc. on an arbitrary editing area.

The center movement S9- changes the positional relationship of all outlines with respect to the body frame.

undo-redoS9-■ is for canceling the correction of data made in a straight line and returning to the previous state.

The character information display SIO has a function of displaying various information of font data, that is, a point coordinate display 510-a.

List display 510-bo Point coordinate display 5IO-a shows sample point attributes and x,
The X coordinate is displayed on the screen.

The list display 5IO-b displays various information such as the position of font data relative to the body frame, body frame information, and font data information on the screen.

The character information related input/output Sll has the function of inputting various information of font data and setting various lines for display on the editing screen, that is, it consists of a character information manual 5ll-a and a line setting Sl 1-b.

The character information manual 5ll-a is for inputting various information of font data.

The line setting 5ll-b is used to make settings for displaying various lines, etc. that serve as a reference when correcting characters on the editing screen.

Character data registration/termination S12 stores the font data modified on the editing screen to the font data file of DISK 3, and calls the next font data to the editing screen, or
Or, it ends character production.

[Tube Surface Inspection] Tube surface inspection S4 in FIG. 2 means checking the pattern on the screen having various functions as shown in FIG.

That is, it includes a quality inspection 54-a and a center inspection 54-b.

The quality check 54-a displays characters on the CRT 13 to check the quality and quality of the font data.

The center inspection 54-b is for displaying characters on the CRT 13 to inspect the quality of the font data, especially the center.

[Printer output S5] The output S5 in FIG. 2 has various functions as shown in FIG. 6, namely, contour line inspection 55-a, scalar quality inspection 55-
b. Scale pull center test 55-c.

List S5-do The contour line inspection 55-a outputs a printed matter for inspecting the quality of font data, sample point information, line width information, etc. using the PRT9.

The scalar quality inspection 55-b outputs a printed matter for inspecting the quality and quality of font data using the PRT9.

In the scalar pull center inspection 55-c, the PRT 9 outputs a printed matter for inspecting the center, especially among the quality of the font data.

The list 55-d is for outputting various types of information printed by the PRT 9, such as the position of font data relative to the body frame, body frame information, and font data information.

[Utility S6] The utility S6 shown in FIG. 2 has various functions as shown in FIG. 7, namely, copy 56-a, merge 56b1, append 56-c, delete 56-d, and resize 56-e.
including.

The copy 56-a is for copying the original data file and font data file of DISK3.

Merge 56-b is for integrating the original data file and font data file of DISK3.

Append 56-c is for adding data to the original data file and font data file of DISK3.

S6-d is for deleting the original data file and font data file of DISK3.

The resizer 56-e has a function of compressing and expanding the font data file of DISK3.

[Explanation of Terminology] Here, the terms, operations, etc. necessary for explaining the present invention will be explained below.

The original data is the contour of the image data read by IR7 expressed by 8 adjacent data. From now on, the original data will be referred to as the original, and the file that stores the original data will be referred to as the original data file. The original data file is created on DISK 3 in FIG.

Next, font data will be explained using FIG. 9.

Al and a2 displayed as solid lines are called contour lines.

For example, the contour line is composed of a cubic B-spline curve, a straight line, and a combination thereof.

The circles shown at a3 in FIG. 9 are the control points of the curve excluding the start and end points of the curve, and are called intermediate points. The squares in A4 indicate the starting and ending points of a curved line or the starting and ending points of a straight line,
These are called end points. The end points and intermediate points are collectively called sample points. The terms "end point" and "intermediate point" sometimes refer to the point itself, and sometimes refer to the characteristic of the point.

The file that stores this font data is called a font data file. The font data file is created on DISK 3 in FIG.

When handling the above-mentioned font data, as shown in FIG. 11, the absolute coordinate system and the design coordinate system are applied as appropriate.

These differ in the direction of the y-axis, but the absolute coordinate system is suitable for handling data, and the design coordinate system is suitable for creators to design characters.

Next, the operation in this embodiment will be explained.

The operation is performed by moving the PD12 in FIG. 1 or pressing a button. The PD 12 in this embodiment has three buttons. From left to right, they are called the left button, middle button, and right button, respectively. Basic button operations on the PD include the following: pressing the button, releasing the button, moving the PD while holding the button, and moving the PD while releasing the button.

In the operation description of this embodiment, the following terms are used in combination with the above-mentioned operations.

A series of operations in which you press a click button, do not move, and then release the button.

Double Click Clicking twice within a certain period of time. Similarly, you can move the PD while holding down the A0 drag button.

Release Release the button you were pressing. The above-mentioned drag is terminated by release.

Move the PD to the position of the item to be selected and press the button. Buttons are not limited.

Menu selection: Pinching the menu to be selected, for example with the left button.

und.

Undo refers to returning changes to figures, etc. caused by the previous operation to their previous state. For example, the fourth aspect of the present invention
In FIG. 89, there are the following steps: 1. Cancel the selected point. 2. Cancel the position clicked by PD 12. 3. Return the changed figure data to the data before the change, and return the display to the previous state.

red.

Redo means to return the data and display of figures, etc. that have been undone to the state after the change (und).

undo).

[Symbol Definitions] Next, symbols used when explaining the present invention are defined below.

As mentioned above, the end point is expressed as El, the intermediate point as Mi, and the end point and the intermediate point are collectively expressed as Pi.

Let the contour line be expressed as Li.

Let the input data be expressed as Ni.

Let the position input be expressed as 11.

[Contour Data Storage Unit] FIG. 10 shows details of the outline data storage unit on the RAM of the PMEM 6. FIG. 10(a) is an area that holds the number of contour lines n1oop constituting a character pattern. 10th
FIG. 10(b) shows the arrangement of the area for holding the number of sample points npoint forming each contour line and the address addrl of the sample point information storage area of FIG. 10(d).

FIG. 1O(d) is a diagram showing the arrangement of areas for storing sample point information. Sample point information is coordinate values x, y
, if the detailed fish waste property and sample point is the starting point of the curve, this is the address of the area for storing the attributes of the curve, that is, the array shown in FIG. 1O(e). FIG. 10(e) shows the attributes of a curve, in this case a cubic B-spline as an example, and the number of coefficient sets ncoef and coefficients a H, b for determining the curve.
This is an area for storing 11%(n, dn (n=0.1...).

If the parameters indicating the curve attributes change, Fig. 10(e)
It goes without saying that the structure of the area that stores the attributes of the curve shown in FIG. Taking the rDJ pattern shown in FIG. 10(C) as an example, FIGS. 10(a), (b), (d), and (e)
will be explained in detail. The character pattern in Figure 10(C) is composed of two outlines: LOlLl, so (a)
The value stored in the area shown in, that is, n1! oop is 2
becomes. (b) is an array of size equal to the number of contour lines, so in this case, it is an array of size 2, and each 17 (L
O), 13 (Ll).

In the sample point information storage area (d), P[0] is an end point and is not the starting point of the curve, so PDATA[0]
The point attribute value of is O. Since P [1] is the end point and the starting point of the curve, the point attribute value of PDATA [1] is
The number of curve configuration sample points is 4 in this case.

Furthermore, since P[1] is the starting point of the curve, it holds the address of the curve attribute storage area (e). PDATA [1]
n of the curve attribute storage area (e) that holds the address in
coef is 1 and aoSbolCoSdo is RAM
is stored in

Correction work such as point deletion, point movement, etc. performed by the operator using the PD 12 is realized by referring to/modifying FIGS. 10(a), (b), (d), and (e).

The display changes on the CRT 13 are shown in Figure 10 (a), (b), (
This is done by converting into bitmap data and transferring it to the VRAM 14 with reference to d), (e), etc.

[Create file] Next, file creation S1 in FIG. 2 will be explained.

FIG. 8 shows a file creation menu displayed on the CRT 13. From this file creation menu, by picking a new or changed item on the PD, the screen moves to the file creation screen shown in FIG. 12. In the case of changes, the currently entered contents will be displayed. Pick each item on the PD and enter it on the KBD. By picking the creation of Yl with PD,
A new file is created or the header section is changed.

By picking the end of Y2 with the PD, the process returns to FIG. 8 and the file creation ends.

Files include outline data files, original data files, radical data files, and element data files, all of which have the following structure. The structure of the file is shown in FIG.

The header section contains data to be managed for each file and information regarding the structure of this file. The index section has information regarding the code of each data and the storage address of the data. The free space management section manages the free space in the data section. The data section is an area for storing data for each figure, and is divided into blocks for use.

Digiquiz Next, digitizing (S2) shown in FIG. 2 will be explained. Digitizing is a process of automatically creating original data files and font data files from original characters.

The above process includes the following steps as shown in the flowchart of FIG. That is, scanning, code setting, center setting, noise removal, and contour line generation.

The created original data file and font data file are stored in DISKa shown in FIG.

In the digital quiz, as shown in FIG. 8, by picking the font code of a-1 on the PD 12, the font code is selected and displayed on a-2. By picking the digitizer a-6, the screen moves to the digitizing initial screen shown in FIG. 14.

A font code is displayed in b-1. b-2 is a message area. b-3 is a digitize menu, and b-4 to b-6 are submenus. Each menu is on P.
It can be picked with D12.

Digitizing is done page by page. In the example of the present invention, 1
There are two types available: a 5-character page and a 9-character page, and it can handle up to 5 pages. The flowchart in FIG. 3 corresponds to the menu in b-3, and the next menu cannot be picked unless each page is in the order of this flow, that is, the previous step has not been completed.

manag for each user to manage the progress of digital quizzes.
efile is prepared. The managefile is a matrix of the number of pages x the number of characters, and a flag for the completed step is set for each character on each page.

For completed steps, the menu field will be reversed and turned black, making it impossible to pick. If you pick b-5 with PD12, you will get the first
Moving on to Figure 5, by picking any page number and selecting YES, you can edit the managefile of that page.
It is possible to initialize the flag of e and cancel digitizing of that page.

Digitizing is completed by picking b-6 with the PD 12, and when digitizing is started again, it starts from the step continued from the previous step. When the digitization of one page from scanning to outline generation is completed, the m a of that page is completed.
The flag of n a g e f i 1 e is initialized, and all the menu columns of that page of b-3 are reversed and become white, and can be picked.

The resolution of the IR7 can be set in the environment variable of the CPU 15, and by referring to this at the time of scanning, any resolution can be supported.

In addition, by marking the center mark indicating the position of the document and the scan direction on the document mount in advance, it is possible to read this at the time of scanning, automatically recognize the distortion of the document and the scan direction, and perform appropriate processing. . 16th
An example of a manuscript is shown in the figure.

Further, in a menu column where it is necessary to recognize which image data it is, such as the scan column in FIG. 19, for example, a reduced version of the image data read by the IR 7 is displayed.

・Scan The scan procedure will be explained using the flowchart shown in FIG. Select a menu with PD12, and if it is b-9, end (step). I if it is scan 1-5
R7 is activated, and image data of each character for one page of the original is stored from PMEMS to DISK 3 in a preset order (step 2).

Next, as shown in FIG. 17, 15 characters are displayed in a reduced size on the CRT 13, and one character located in the center of the document is displayed in a larger size (step 3). A center mark is written on each character of the manuscript, making it possible to detect rotation and distortion of the manuscript.

If necessary, rescanning can be performed by picking b-7 with the PD 12 (step 5). At this time, it is also possible to specify characters to be rescanned using the PD 12 and to perform partial rescanning. Furthermore, by picking b-8, scanning of that page can be canceled and the original data in DISKa is also deleted (step 6).

Finally, update managefile (5step 7),
finish.

・Code setting From Figure 14 b-3, select the menu of the appropriate page of code settings 1 to 5 with the PD12.
Moving on to Figure 9. However, in this case, the pickable page number
, the scan must have finished.

The code setting procedure will be explained using the flowchart of FIG. 20. First, variables are initialized (step).

By picking the code field of b-io, KBDI
Code input becomes possible from I (step 2). If the picked code field is in the code setting style (step 3), the number of set characters is reduced by 1 (step 4). Enter the code from KBDII (step 5), and once it is set (step 5).
p7) The character corresponding to the character code is displayed in the corresponding column of b-11 (step 8), and 1 is added to the set number of characters.

For example, if the code system is JIS and the code is 2344, "D" is displayed.

Also, by inputting -1, it is possible to ignore that character from now on and not generate an outline (step 6).
).

Also, by picking b-12 serial number processing, it is possible to perform serial number processing based on the code system (ste
plo).

If the codes of all characters are set and b-13 is picked with the PD 12 (step H), the manage file is updated and the process ends (step 2).

- From center setting b-3, move to FIG. 21 by picking an appropriate page menu of center settings 1 to 5 with the PD 12. However, in this case, the page number that can be picked is
Code setting must be completed.

The center setting procedure will be explained using the flowchart of FIG. 22. First, use the PD 12 to pick the scan field of the character for which center setting is to be performed (step).

This will display the picked image data (s
step 2), the cursor of the PD 12 changes to a cross-pair cursor (step 3), and center setting becomes possible.

Place the cursor on the center mark marked in advance on the document mount and click the left button on the PD12 (
As a result of step 4), a body frame appears on the screen (step 5). Thereafter, fine adjustment can be made by moving the center in units of one dot using the arrow keys of KBDll (step 8).

For the size of the body frame, set the pitch column of b-14 to PD12.
You can change it by picking it (step 6) and inputting it from KBDII (step 7). Further, this pitch information can also be automatically input from OCR or character code.

The center setting is automatically determined for each character by picking the next character, and when all character settings are complete, b-
If you pick the next menu from 3 or b-15 (step), the managefile is updated and the process ends (step).

- From Noise Removal b-3, move to FIG. 23 by picking an appropriate page menu of Noise Removal 1 to 5 with the PD 12. However, in this case, the center setting must be completed for the page number that can be picked.

The noise removal procedure will be explained using the flowchart of FIG. 25. First, the PD 12 picks the scan field of the character whose nozzle is to be removed (step 1). As a result, image data is displayed as shown in Fig. 24 (step
2). Here, noise refers to things other than the necessary image, such as blurring of the image that occurs when reading with a scanner, dust in the document, and registration marks.

Noise removal is performed by turning on or turning on bits of the corresponding image data stored on the PMEM 6. It should be noted that in the explanation here, it is assumed that in a necessary part of the image data, that is, a part representing a character, the corresponding bit in the memory is 1 (on).

The present invention introduces the concept of a body frame, and has functions such as extra-body deletion that turns off all bits outside the body frame, and functions that turn on or off the inside or outside of a specified rectangle.

The deletion outside the body is executed by picking b-15 with the PD 12 (step 3.4). If there is more noise (step 5), depending on the type of noise (step 6)
, b-16 menu with the PD 12, and switch on (step 8) and off (step 7) in the rectangle. Specify the range by dragging with PD125
step 9), perform noise removal (step).

By picking the next character, noise removal for that character ends (5tepH), and the image data is DISKa.
The previously picked scan field will be highlighted to indicate that the character is finished.

After noise removal of all characters is completed, pick b-17 with PD12 or pick the next menu from b-3 (st
epH) to update the managerile and end the process (step 2).

Further, noise is automatically removed in the next contour line generation.

・Outline generation-3 starts automatically by picking a menu of appropriate pages 1 to 5 of outline generation on the PD 12 (FIG. 26). However, in this case, noise removal must be completed for the page number that can be picked.

The outline generation procedure will be explained using the flowchart of FIG. 29. b-4 parameter setting menu on PD12
When you pick (step 1), the automatic noise removal maximum value is displayed, as shown in FIG. 27, for example.

By default, it is set to 80, and this value is the number of dots that make up the contour, and as a result of contour tracking, contours smaller than this value are regarded as noise and are not regarded as a contour point sequence. For example, an isolated point consisting of 24 dots is considered noise. Note that this value can be input and changed from KBDII by picking b-18 (step
2). In addition, parameters for feature point extraction and sample point automatic generation when automatically generating font data can be changed. This makes it possible to control the optimal contour data generation method for each typeface, such as a typeface with many straight lines such as Gothic, and a typeface with many curved parts such as cursive. These parameters are stored in PMEM6, for example, depending on the typeface.

Extract a sequence of contour points from the image data from which noise removal has been completed and create original data (5step 3)
, stored in DISK3. This original data can be referenced on the CRT 13 at any time during character production.

Generally, image data such as characters is composed of a plurality of contour lines, but in this case, all point sequences indicating the "inner edges" of the image data are extracted.

The point sequence data extracted in this way becomes a set of coordinate values (χ1Syi) from the reference point of the image data. The method of extracting the contour point sequence is realized by using a method proposed by the applicant in Japanese Patent Laid-Open No. 64-71767, etc., or a generally known contour tracking method.

Furthermore, feature points are extracted from the original data obtained here, straight parts and curved parts are determined, and font data representing characters is automatically generated (Fig. 29, 5 step 4).
. Here, the feature points refer to the end point (E4) of the contour point sequence, the maximum/minimum point (E2), and both end points (El, E3) of the straight line portion, as shown by squares in FIG.

After extracting feature points, for the point sequence section determined to be a curved section, for example the section from El to E2, spline fitting processing is performed to automatically generate sample points M1 and M2 necessary to express the corresponding section. do.

After applying this spline fitting to the entire curve section and creating font data constituting one character in memory, DIS
Store it in the font data file created in K3.

When contour line generation is completed for all characters (step 5), the manager is automatically initialized and terminated (step 6).

[Character Production] Character production is performed by performing various operations on the basic screen shown in FIG. 30. Although the explanation is given here in letters, it goes without saying that the explanation is not limited to letters. In the example, the basic screen is 1280 x 1024 pixels and has the following contents. FIG. 30 will be explained below. A-1
is a character display area, which is composed of an editing area (A-11) for displaying and editing the character pattern being edited and a compositing area (8-I-2) for displaying a compositing pattern.

A-2 is a code area, and the left part is a font code indicating the file name containing the character pattern being edited. The right part is the character code of the character pattern being edited.

A-3 is a coordinate value area. The “real-time” value indicates the coordinate value of the point currently under control in x and y.
Numbers 1 to 4 above indicate the coordinate values d x -, d Y of the latest four points as well as the coordinate values of the previous and subsequent points. Every time a new point is controlled in the order of 4 to 1, it scrolls up (.

A-4 is a message area that displays error messages and the like for various operations.

A-5 is a menu area for character creation, which is divided into five areas, FIG. 30(b) to FIG. 30(f).

Each menu process is basically terminated by another menu entry. Furthermore, the execution order and number of executions of all menus are not limited.

FIG. 30(b) is a menu area related to screen display changes such as scrolling and redisplaying the character pattern being edited.

These menus are controlled by an interrupt menu control method, which will be described later, which is different from the normal menu control method.

Each display control is not exclusive; for example, a combination of zooming and scrolling is also possible.

FIG. 30(C) is a menu area related to character data modification such as transformation, composition, and point control.

FIG. 30(d) is a menu area where character information such as point coordinates is displayed.

FIG. 30(e) is a menu area where character information such as pitch, line settings, etc. are performed.

FIG. 30(f) is a menu area related to character data storage such as return, -time storage, and registration/termination.

A to A6 are composite pattern control menu areas, which are divided into two areas, FIG. 30(g) and FIG. 30(h).

FIG. 30(g) is a menu area used for changing the screen display such as scrolling the composite pattern, and FIG. 30(b)
) is an interrupt menu similar to the editing display control menu.

FIG. 30(h) is a composite pattern call menu.

The character correction work begins by calling character data to the editing area A-1-1 in FIG. 30(a).

Character data is loaded from the character data storage area on the DISK in FIG. 1 to the PMEM in FIG. 1 through the I10 interface in FIG. 1 and 2.

In the PMEM of 6, the data is processed for display and shown in Fig. 1.
Transfer the display data to the VRAM of 4, and
Display on RT.

When modifying characters after calling character data, rules are set for the positional relationship between end points and midpoints in order to standardize the design and add line width information to prevent deterioration of display quality at specific sizes.

The rules are that the end points must be taken at the maximum or minimum points on the continuous curve of the contour, and the intermediate points must be on the horizontal or vertical line passing through the end points.

The functions of moving the point 39-d and aligning the point 59-e in FIG. 4 are based on this convention.

Among the menus in character data correction S9 in Figure 4, for those that require sample points to be displayed, if the sample points are not displayed when selecting the menu in S9, the sample points will be displayed automatically. I have to.

After calling the character data, correction work is performed by operating the PD 12 and keyboard 11. This operation will be explained using FIG.

PD operations such as menu selection and sample point selection are as described above (terminology explanation).

For precise input such as moving sample points in units of several dots, please refer to KB.
Operate the arrow keys on the DII.

In this case, the PD 12 has three buttons, which are used as appropriate in each menu.

When you operate the PD, arrow keys, etc., the information is transferred to PMEM.
6, and in PMEM6, DIS
It inputs data from K3, changes and processes data already on PMEM6, transfers the data to VRAM14, and displays it on CRT13.

undo 11 red.

Next, the aforementioned undo*redo will be explained.

In the present invention, the timing for instructing the execution of undo-redo is, for example, when the right button of the PD 12 is clicked in the operation stage of each menu process.
The und is used as an input to execute the do-redo operation, and is to be performed in each processing procedure.

and redo (undo of undo), or provide a menu for undo-redo, which will be described later, and when the menu is selected, undo-redo is executed for the immediately previous change in graphic data.

FIG. 31 shows unclo-red by changing the graphic data.

10. The figure data table is a table that stores the figure data in FIG. 10, and each figure is represented by the number i @ F i, and the undo table is the same as the figure data table. This table stores the figure number and data only for the figure Fi in the specified figure data table, and is cleared as appropriate or exchanges data with the same number for Fi in the figure data table. It is a table where you can do things. In the flow diagram, 5tepl is u
This is a step that instructs to return to the state before the change when executing ndo. This instruction is determined according to the processing of each menu, and when this instruction is issued, un
Clear the contents of the do table (step 2). Next, the operator inputs the next data N, and if in step 4 the next data N is an operation that instructs to change the figure data Fi, for example, to delete one vertex of figure F1, then in step 7 the figure Fi is undo
If it is not stored in the table, store the data of Fi in the figure data table as the data before the change in the undo table along with the figure number in the undo table. In 5step 9, store the data of the figure data table F1 in the undo table. Change it and display the result (step 5), and wait for the next data N to be input (step 3).
).

If Fi has already been saved in the undo table at 5step7, skip 5step8 and proceed to 5step9.
Proceed to. That is, in 5tep7, the process proceeds to 5tep8 only when there is a change instruction for the first time after clearing the undo table regarding the figure Fi.

Next, in 5step 4, when input N is an undo instruction (step 5), all data Fi in the undo table is exchanged with Fi in the figure data table (5tepH), and the result is processed in the same way as in 5teplo. , performs display processing (step 12), and then inputs the next data (step 3). If an end instruction is given in step 5 (step 6), this menu processing is ended, and if there is any other instruction, other processing is executed in step 13, and the process returns to step 3.

Also, when there is an undo instruction again in 5tep5, in the process of 5tepH, all figures Fi in the undo table will be exchanged again, so redo will be performed, and in 5tepH-12, u
This means repeating ndo/redo.

Interrupt Menu Control Interrupt menu control will be explained. An interrupt menu is a menu that can be executed during normal character data correction menu processing without interrupting the operation.

FIG. 32 is a diagram explaining the interrupt menu control method for executing the interrupt menu, and FIG.
32(a) is a diagram briefly explaining the internal flow of normal character data correction menu processing, and FIG. 32(b) is a diagram illustrating the input control section in FIG. 32(a).

The input control unit accepts input from the PD 12 and KBDII, and outputs input information from the operator, such as whether it is a menu pick or a sample point pick.

The flow of processing in the character data correction menu will be explained using figure (a).

Here, it is assumed that whether or not the type of menu is an interrupt menu is determined in advance by having a flag or the like in the menu.

Receives input from the operator at 5 tepl (N1)
, If N1 is another menu, end the menu processing, and if it is not another menu, perform processing according to the contents of each menu (step 3), wait for input from the operator again (step 1), and repeat this process. performs menu processing. This makes it possible to exit each menu without issuing an exit instruction.

The input control section will be explained in (b). Receive input information from the operator in 5 tepl and set it to Nl, 5 tep
2, N1 is determined, and if N1 is not an interrupt menu, N1 is output and the process ends. When N1 is an interrupt menu, each interrupt menu process is performed here in step 3, the next input is waited for (step 1), and the input control section is not terminated. That is, when the interrupt menu is instructed by the operator, it is processed within the input control section, and each step in (a) is not interrupted.

[Display Control] FIG. 33 is a diagram simply showing the flow of display control in character production S3, where 33-1 is the part with each function of character data correction of N9 in FIG. The part having each function of display control of N8 in FIG. 4, 33-
3 is a part for changing font data, 33-4 is a part for changing display data, and 33-1 to 33-
4 shall be on PMEMS, and 33-a shall be on 33
- If the font data actually changes in 1,
It means to request 33-3 to change the font data, and similarly, 33-b also requests 33-2 to change the display data, etc.
33-C indicates that a request is made to 33-4 to change the display due to the font data change, and 33-d indicates that the actual change from 33-4 to CRT131:m
VRAM14 tl- street.

It means to request display. To explain the flow a little more, if font data is changed during character data correction work in 33-1, a data change request 33-a is sent to 33-3, and 33-3 actually changes the font data. After that, a display change request 33-C is issued to 33-4. At 33-4, the font data is referred to, display data is created, and a display request is sent to the CRT (33-d) for display. If there are display change requests from two display control units (33-b), only the display data is changed at 33-4 and displayed on the CRT.

Each function of 33-2 is the above-mentioned interrupt menu, so even if 33-4 receives a request from 33-2 to 33-b while modifying character data, requests 33-a or 33-3
It will not affect the processing.

33-4 will be explained using FIGS. 33 and 34.

FIG. 34 divides the processing contents in step 4 into two parts, Ca) shows the flow of display data creation processing, and (b) shows the flow of display data display processing. In (a), the font data, original data, line data, and these data are set as one set, and the number assigned to that data, the display magnification rate S, the display reference point coordinate O, and the curved part of the font data are divided into straight lines. The curve division interval N, which is a parameter used as a guideline, is input, and the font display data, original display data, and line display data developed in the display coordinate system are output in correspondence with the display data number No. Therefore, by changing the value of No., it is possible to have multiple sets of output data.

(b) shows the font display data, original display data, and line display data that are output from (a), as well as their data number No., a flag DT for selecting data in the set, and the selected data. A flag ST that indicates the display format of the data, a flag PF that determines whether or not to display the data in a filled manner, and a WD that indicates the display destination of the data.
PL, which instructs the brain, and flag DS, which instructs whether to actually display or erase, are input, and bitmap data is developed in VMEM.

Each step will be explained in turn.

Input S, which is the enlargement rate or zoom rate at the time of display, at 5 tepl. 5. In step 2, input the coordinate O that will be the display reference after zooming. The parameters of S10 are generally the same as those required when performing coordinate transformation from the absolute coordinate system to the display coordinate system. 5tep3 curve division interval N
Enter. In 5tep4, the font data previously stored on the PMEM 6 is subjected to coordinate transformation using 810, and sample point display data shown in FIG. 35 (c) is created from the sample point data of the font data shown in FIG. 10 (d).

In step 5, the sample point display data created in step 4, the coefficients shown in FIG. 10(e), and the curved portion of N are developed into short vectors. Needless to say, the number of divisions can be changed depending on the value of N. The data expanded into short vectors is converted into PME as short vector data.
Hold on M (d).

Here, FIG. 35 will be explained. (a), (b)
The explanation is the same as in FIGS. 10(a) and (b). In addition, DDATA in (c) is the coordinate of the sample point in FIG. 10 (d) PO (X), P o (Y) ~p, -, (X),
Pn-1(y) is a value that has been coordinate transformed for display, and regarding point attributes, L means the line start point, C means the curve start point, and in the case of C, the curved part is converted into a short vector. The address of the expanded area (d) is shown below. (
d) stores the number npt of point coordinates and npt coordinate values.

In step 5, the original data on the PMEM is also subjected to coordinate transformation in the same manner as in step 4, and is stored on the PMEM as original display data. The same applies to the line data of 5tep7.

Next, (b) will be explained.

In step 5, a flag number No. which determines which data set to use among the font display data, original display data, and line display data created in (a) is input. In step 9, a flag DT for determining which data to display among the numbers is input. DT=1
When , it is font display data, when DT=2, it is original display data, and when DT=3 (7), it is 1-! Line display data is input.

At step 5, the display format ST is input. ST is D
Valid only when T=1, takes three values, 5T=l(7
), DDATA (1) curve display, 5T = 2 (7) Bl
kDDATA is displayed as a straight line, and when 5T=3, DDATA is displayed as a sample point. In other words, when displaying a curve, (c
), when the point attribute is C, refer to addr2, and (
The data including the short vector data of cl) and sequentially connected by line segments is used as display data. When displaying a straight line, (C
) and only the data of sample point coordinates are connected in order as display data.

When displaying a sample point, data such as an end point being a square and an intermediate point being a circle is used as display data according to point attributes.

Figure 36 shows (a) curve display, (b) straight line display, (c)
FIG. 3 is a diagram showing an example of sample point display.

In 5tepH, input a flag PF indicating whether or not to fill in the outline of the display data selected in 5step 8.9 and the display data created in 5teplo. PF = 0 is an instruction to display the outline, and PF = 1 is an instruction to fill it. . At this time, when the data is line display data, this flag is not referenced.

At 5tep12, an area for displaying the display data created up to 5tep is input. The WD may be a window.

In 5tep13, if the VRAM can have a plurality of brains, a PL indicating the display destination brain is input. When there is only one brain, the flag is ignored.

In 5tep14, a flag DS is input which instructs whether to display or erase when expanding on the VRAM.

In step 14, the display data selected by DT is
It is developed into a bitmap on the VRAM 1d according to T, DF, WD, PL, and DS and ends. After this step is completed, the image is displayed on the CRT from the VRAM.

Also, the data number No. specified through (a) and (b)
, can be considered to have one for each display destination area WD.

It goes without saying that various display combinations can be made by combining DTSST and PF.

Next, each function of display control will be explained. In Fig. 4, the display controls (S8-a to S8-j) are all interrupt menus, and as mentioned above, even if these functions are executed during character data modification, the operation during character modification cannot be interrupted. do not have.

The scrolling of the scroll 58-a will be explained. FIG. 37 is a flowchart showing the scrolling procedure. First, 5 steps
Initialize i with l. 5. In step 2, input the display destination area WD'. W for scrolling the editing area
D' Edit area. 5 step 3 and PD the reference point O'
Enter from II. In step 5, the multi-value number, DTSSTSPFXWD, is input for display processing.

Set PL and DS. It is assumed that one No. exists for each designated WD, and F is a function that associates a WD with No. Here you can select the type of display data currently displayed.
Assume that the current display state is stored in advance on the PMEM along with the data type DT (No,)i (i=0, n-1) for that number, and DT, S
The current values are substituted for T, PF, and Pi, WD' of 5tep2 is substituted for WD, deletion is substituted for the display flag DS, and the display is erased by the above-mentioned display processing in 5tep5. 5
tep6 is 5tep for all data types (n)
This is the part that determines whether to repeat step 4.5. If there is still data in the display state, it increments by 1 in step 5 and repeats step 4.5 again.

Next, each step of displaying after scrolling will be explained.

In step 8, for the display data number No., the scale S and the reference point 01 curve division interval N necessary for creating the display data are input. The reference point O is O' input in 5tep3.
For S and N, the current values for display data number No. are substituted.

In step 9, create display data according to the display data creation procedure described above, set i=0 in step 5, and
In tepH, input values necessary for display processing are set. DT
, ST, PF, and PL, the current display state corresponding to No. is substituted, and WD' and DS, which were input in step 5 and 5, respectively, are substituted with the display state.

In step 12, display is performed according to the display process described above,
In step 13, the current display state is newly stored in the PMEM, and this process is repeated for the amount of data to be displayed, and the process ends.

FIG. 39 is an example of FIG. 38 scrolled. In this case, WD' is a number associated with the editing area number F (WD'), the display data type is font data, so n=1, and no filling is specified for PF.

zoom Explain about zoom.

In the zoom process, simply add S as described in the scroll process above as a new operator input.
The subsequent processing is the same. That is, following 5tep3, the step of inputting the scale value S' is added, and 5tep8
The only thing that is substituted into S is S'. Therefore, only the WD' input, the ○' input, and the S' input section will be newly explained, and the rest will be omitted.

This will be explained using FIG. 40.

At step 5, the display destination WD' is input. If zooming is within the editing area, the editing area is assigned to WD'.

In step 5, change the cursor shape to a long crosshair cursor. The cursor will be explained later in step 3.
to display the display center. 5 Step 4 waits for input from the operator. If input Nd is another menu pick, 5t
End processing is performed in ep17 and the program ends. The termination process includes processes such as returning the cursor shape to its original shape and hiding the center. When the first rectangle P1 is input in 5tep6, the input of the next rectangle point P2 is waited for in 5tep8. 5t
In ep9, if the input Nd is another menu, the process ends after the end process, and if it is an undo instruction (steplO), Pl is canceled (5stepH) and the process returns to step4. 5step1
When the rectangle 2nd fish P2 is specified in 2, for example, Pl, P
The length and width of the rectangle with 2 as the two diagonal points, w, WD
When the vertical and horizontal lengths of the area specified by ' are H and W, magnification rate S' ==min (H/h, W/w) center o'
= Make it the center of the rectangle.

In 5tep14, WD', S', and O' are new inputs, the above-mentioned display processing is performed, and the process ends.

For example, when inputting the magnification ratio in step 5, the reference point ○'
is the current value, and display processing is performed in the same manner in step 516.

Regarding the input of Nd in step 5, step 6, and step 7, for example, if the left button is clicked, Pl is input, and if the middle button is clicked, the enlargement rate is input. Regarding the magnification rate in step 5, for example, when clicking above the center in the display destination area, the click is enlarged, and when clicked below, the magnification rate is determined based on the distance from the center.

Figure 41 shows the zoom processing screen, 41-1
is the display center, 4I-2 is the long crosshair cursor, 4
1-3 shows the appearance of a rectangular echo, and FIG. 42 is a diagram zoomed in accordance with instructions from PI and P2.

Needless to say, you can zoom the composite screen by changing the WD.

1 piece Explain standard sizes.

Standard size is a function that returns the scrolled and zoomed display state to the original size and display position in one go. The original display state means, for example, that 1 dat of font data corresponds to 1 pixel of the display area, and the display is performed so that the center of the body is located at the center of the display area.

In the display processing section described above, the initial scale S is input to S. , O is the initial reference point 0°, and the area WD' can be realized as a new input.

Original ON/OFF Original ON/OFF will be explained.

This menu is a toggle menu, and each time you pick the menu, you can turn the original display on or off.
L.

This is also No. 4-F (WD') in the display processing section (b).
) WD' can be achieved by specifying the display destination area, DT←2, and setting and inputting DS←Hide if the original is currently being displayed, and DS←Display if it is currently not being displayed. It goes without saying that by changing the PL when displaying the original display data, it can be displayed in a different brain from the font display data and can be viewed overlappingly.

Sample 0N-OFF The sample point 0N-OFF will be explained.

This menu is also a toggle menu. Display processing section (b
) ni No4-F(wD'), DT←], ST←3
All you have to do is enter.

FIG. 43 is an example showing the sample point ON and original ON states.

Import IJL Niko JJ17 This menu is also a toggle menu. Similarly, No+-
F(WD'), PF4-ONi:L, Ds←Display/erase is switched and displayed each time a menu pick is made.

Here too, overlapping display is possible by changing the value of PL to the plane of the font display data.

FIG. 44 is a diagram with fill-in turned ON.

The line 0N-OFF line, for example, the auxiliary line will be described later. Here, regarding the line set while displayed in the line setting menu,
This function can be displayed or hidden by picking this menu. This menu is also a toggle menu.

Similarly, in the display processing section (b), No. 4 is used for the display method.
Input -F(WD'), DT←3.

FIG. 45 is a diagram showing the line ON state.

Cursor ONψOFF The cursors to be switched here are the long crosshair cursor shown in (a) in Figure 46 and the short hair cursor shown in (b). - Display vines. This display can be controlled, for example, by changing the cursor, or by having cursor data as display data and using the same processing method as display processing (b), as shown in the display control above. This can be achieved by displaying methods.

4 presentation FIG. 4 52-10 Redisplay will be explained.

Redisplay is a function that refreshes the display screen and displays it again when, for example, noise appears on the display screen or lines disappear due to some external influence.

FIG. 47 is a diagram illustrating the redisplay operation. In each input waiting state (step) during character creation, when instructions are given by PD12 and KBDII (s
step 2), if it is a pick in the redisplay menu (step
p3) Perform redisplay processing (step 5), return to the original input holding state (step 2), and continue the current character production processing if it is not a pick in the redisplay menu at step 3 (step 4). Therefore, this interrupt menu does not interrupt the operation even in the middle of creating each character.

When redisplaying S5, the font data, menu data, message data, and echo data were referred to regarding the character data in PMEM6, and the data was processed for display based on the current display state and expanded on the VRAM44. After that, it is displayed on the CRT 13i.

The method of re-displaying the font data is realized by erasing all the display data once in the display process shown in FIG. 34(b) and displaying it again in the same display state.

Regarding the insertion of point 39-a in Figure 4, Figure 48 and 4
This will be explained using FIG.

The Insert Point function is invoked by picking the "Insert Point" menu.

Point insertion is a function that inserts and moves one or two sample points between two adjacent points to change a line segment or curve.

Figure 48 shows the state before point insertion, and if Ml and M2 are designated as two adjacent points, the sections E, M, M2E2 are
As a result of sample point insertion, sections E, M, and M3M in Figure 49
2E2.

In this embodiment, as a preferable example, the position of the insertion point is set at the midpoint of two adjacent points, and the point attribute of the sample point to be inserted is determined according to the following rules. That is, section D in Figure 48
2, when two adjacent points are end points, the specified section is a line segment, so the point attribute of the insertion point is set as the end point, and the section D in Figure 48
If one or both of the two adjacent points are the midpoint, as in 1, the specified section is a curve, so the point attribute of the insertion point is set as the midpoint.

Apart from this, there is a function to insert two intermediate points between two adjacent end points in order to change a line segment section to a curve section with a simple operation. In this case, the position of the insertion point is the adjacent 2
Use the internal division point of the end point.

The procedure for point insertion will be explained using the flowchart shown in FIG.

At 5 tepl, set the flag "insert FLAG" to indicate whether or not the point has been inserted.
Initialize J to OFF. In step 5, one point in the CRT editing area is selected with the left button of the PD 12, and it is set as PL. In 5tep3, the adjacent point P2 of Pl is 5te
Select in the same way as p2. In step 5, the point attribute of the insertion point is determined from the point attributes of Pl and P2 according to the above-mentioned fish waste determination rule. After recalculating the curve parameters of the section affected by point insertion and displaying them on the CRT 13 through the VRAM 14, the insertion FLAG is turned ON in step 5. 5
At step 6, the next input is accepted, and at steps 5, 7 to 10, the accepted input is determined. As a result of the determination, if the input is a menu pick, this function is terminated. If it is a normal point input, the input is set as the first point input at 5tepl 1, and the processing from 5step 3 onward is repeated. If it is a movement instruction (arrow key on KBDII), the point inserted in 5tep is moved in 5tep12, the changed outline is displayed on the CRT 13 via the VRAM 14, and the process returns to 5tep6. In addition, 5t
If the input in ep6 is undo (right button on PD12), determine the insertion FLAG in 5step13, and if it is ON, return to the outline display before inserting the sample point in 5step4. The inserted sample points are deleted, the contour line is redisplayed), and the insertion flag is turned OFF in step 517. Also, the judgment of 5tep13 is OF
If it is F, in step 14, reinsert the point to display the state of the contour line after inserting the point and redisplay the contour line),
5In step 15, turn on the insertion flag.

Through the above-mentioned steps 5tep14.15 and 5tep16.17, it becomes possible to delete and reinsert the points once inserted, and to redisplay the contour line simply by operating the right button on the PD 12.

As mentioned above, in order to realize the function of changing a line segment section to a curve section (inserting 2 intermediate points), input the points in step 2.3,
12 middle button, and after inserting two intermediate points in step 4, transfer the outline (or section) to the CRT1 through the VRAM14.
Display on 3.

Next, the point deletion 59-b will be explained below using FIG. 112. To delete points, press the "Delete points" menu.
It is activated by picking at D12.

Point deletion is a function that deletes an arbitrary sample point or a plurality of sample points in an arbitrary range on the contour line, and re-interpolates and displays the curve. FIG. 113 is an example in which sample point P1 in FIG. 112 is deleted, and FIG. 114 is an example in which sample point P1 in FIG.
This is an example in which sample points included in section K in FIG. 12 are deleted.

The procedure for point deletion is shown in the flowchart in Fig. 115 and in Fig. 11.
This will be explained using FIG. 2, FIG. 113, and FIG. 114.

[Delete FLAGJ, which is a flag indicating whether a sample point was deleted at 5 tepl, is initialized to OFF. 5t
Input the first point from PD12 in ep2. 5step3
Then, determine whether the input to PD12 at 5tep2 was a section instruction (pressing the middle button), and if it is a section instruction, consider point P to be the end point of the section as 1, and enter 5tep4゜5tep.
In step 5, enter 2 as the end point of the section and the point P2 on the section from the PD12. In step 5, sample points to be deleted from Kl, K2, and P2 are determined. If the input to PD12 at 5tep2 is not a section instruction, it is an instruction to delete one point, and s'
At step 20, P input at step 5 is set as the sample point to be deleted. 5tep7, 5tep6 or 5t
The sample points determined in ep20 are deleted from FIG. 10(d), the curve parameter table of FIG. 10(e) is re-created, display data is created, and displayed on the CRT 13 through the VRAM 14.

At 5step9, accept the following input, and at 5teplO~
In step 12, the receiver determines the input. As a result of the determination, if the input is a menu pick, this function is terminated. Also, in the case of normal point power, 5 step 13
Then, with this input as the first input, the deletion FLAG is turned OFF in 5tep14, and the process from 5tep3 onward is repeated. In addition, the input at 5tep9 is undo (PD1
2 right button), (determination 5 step 12)
, the deletion FLAG is determined in step 15, and it is O
If N, the state before sample point deletion is displayed on the CRT 13 through the VRAM 14 in 5step 16, and
Turn off the deletion FLAG on p17. Also 5tep1
If the judgment in step 5 is OFF, in step 5 step 18 the state after sample point deletion is sent to the CRT 13 through the VRAM 14.
, and turn on the deletion FLAG in step 19. The sample points once deleted in steps 16.17 and 18.19 above can be restored and deleted again simply by operating the right button on the PD 12. (For example, the display of FIG. 112 and FIG. 113 can be switched by simply operating the right button.

) Next, the point deletion 59-b will be explained using FIG. 51 below. Reading of this function is performed by picking the "Point Delete" menu with the PD12. At this time, if all sample points are not displayed on the character outline on the CRT 13 before picking the menu, by picking the menu. All sample points on the character outline are displayed.

Point deletion is a function to modify a line segment by deleting a specified point or multiple points within a specified section. To delete l points, pick the desired point with the left button of the PD12. To delete multiple points within a specified section, pick two points one point outside each end of the section to be deleted. This is executed by picking arbitrary points within the section to be deleted, a total of three points, with the middle button of the PD 12. FIG. 51 is a diagram showing an actual example of point deletion, and the alphabet in parentheses and the alphabet with a dash in parentheses indicate before and after execution in each case. That is, if both sides of the point to be deleted are straight lines (A), the point is interpolated into a straight line by performing the point deletion (A'). (B), (E) If one or both sides of the point to be deleted is a curve, by deleting the point, a new curve is interpolated.

(B') (E") When the point to be deleted is the intermediate point (C
), by deleting points, a new curve is interpolated at the remaining intermediate points (G'). However, if the midpoint of a curve with one midpoint is deleted (D), it will be interpolated with a straight line (D'
).

Next, when deleting within the specified section, if the first two points picked are endpoints (F), E51. E55.3 After picking fish E54, it is interpolated with a straight line (F'). Furthermore, if one or both of the two initially picked points are intermediate points, after picking M62, M66.3 fish E63 in (G), interpolation is performed using a curve (G').

Next, the fish waste reversal 59-c in FIG. 4 will be explained using FIGS. 52 and 53. This function is called by selecting the "Fish waste reversal" menu.

Inversion is a function that inverts the attributes of the selected sample points, that is, changes the attributes of the selected sample points to intermediate points if there are endpoints, and change them to endpoints if there are intermediate points, and corrects the contour line.

The procedure for reversing fish debris is shown in the flowchart in Figure 54 and in Figure 5.
This will be explained using the editing screens shown in FIGS. 2 and 53.

5tepl, select one point in the CRT editing area, for example P]
Pick (M2). 5tep2, referring to the fish debris shown in FIG. 10(b) retained in PMEM6,
The end points and intermediate points are inverted, and the parameter table showing the curve in FIG. 10(d) is changed. Figure 10(a),
The data in (b) and (d) are processed for display and stored in VRAM1.
4, the modified outline is displayed on the CRT 13.

In the case of Fig. 52, M2 is changed to the end point, E3, M3,
M2 and E2 become El, Ml, E3, and E2 shown in FIG.

At 5tep3, accept the next input, and at 5tep4~5t
In ep6, the receiver judges the input. As a result of the determination, if the input is a menu pick, this function is terminated. Also, if it is a normal point input, 5te
At p7, the input is set as Pl, and the processing from 5tep2 onward is repeated. Also, the input of 5tep3 is und.

(, right button on PD12), set the PI to 5.
By inverting the point attributes again using tepl, the current state can be returned to the previous state. In this case, the 53rd
The state shown in the figure returns to FIG. 51.

1. Next, the point movement 59-d will be explained below using FIG. 55, FIG. 56, and FIG. 57. To call this function, select the "Move point" or "Move one point vertically/horizontally" menu on PD1.
This is done by picking with 2.

Point movement is basically a function that moves one selected sample point to an arbitrary position, or only in the X-axis direction or only in the Y-axis direction, and at the same time corrects and displays the line segment. There are three ways to move selected points: That is, (1) When picking a point using PD12 described above, do not release the hot button after picking, and continue with PD1.2.
Drag and release at the desired position. In this case, changes in line segments as points move are displayed in real time as dotted lines. (2) Use the arrow keys on KBDII to move in the vertical and horizontal directions in units of one dot. (3) After inputting an arbitrary moving dot value on KBDII, use the arrow keys on the same < KBDII to move the input dot in units of input dots in the vertical and horizontal directions. However, when arrow key movements are performed continuously, the movement amount from the second time onwards returns to the initial value of 1 dot.

The point to be moved is usually only one picked point, but if the attribute of the picked point is an end point, the attribute of the point adjacent to the selected point is an intermediate point, and the X or Y coordinate is If it is the same as the selected point, one or two adjacent points
Like the selected point, the point is also highlighted in black and moves at the same time as the selected point moves.

(A) in FIG. 55 shows a state in which point M to be moved is picked. (B) shows a state in which the picked point M' is being dragged and moved by the PD 12, and a new line segment is displayed in real time as a dotted line as the point M' moves. Next, (C) shows a state in which the moved point M' is fixed at the destination and at the same time the corrected line segment is newly displayed.

FIG. 56 shows a state in which the point E2 to be moved is picked.

At this time, point E2 is connected to curve E , I E 2 and curve E2
Since there is an end point of the curve E3, and the intermediate points M2 and M3 are located at the same X coordinate as the end point E2, points M2 and M3 are also the point E2.
Similarly to black (highlighted).

FIG. 57 shows a state in which the picked point E2' is moved to the right. At the same time, points M2' and M3' are also moved while maintaining their positional relationship with point E2', and the corrected line segment is newly displayed.

FIGS. 58 and 59 are examples in which the moving direction is limited to the X-axis direction or the Y-axis direction.

The procedure for point movement is set using the flowchart shown in FIG. 60 and the editing screens shown in FIGS. 56 to 57.

A movement flag indicating whether or not the sample point has been moved is initially set to OFF in 5 tepl. In step 5, pick one point P1 in the CR7 editing area. 5. Turn on the movement flag in step 3. In step 5, it is determined whether the above-mentioned adjacent points should also be moved. In step 5, PMEM
The point to be moved is determined by referring to the data table shown in Figure 1O above. This decision follows the decision criteria described above.

In other words, the point to be moved is usually only one picked point, but the attribute of the picked point is end point, the attribute of the point adjacent to the selected point is intermediate point, and the X coordinate or Y If the coordinates are the same as the selected point, one or two adjacent points will also be highlighted in black like the selected point, and will move at the same time as the selected point moves.

In step 5, the next input is received, and in steps 7 to 1 of step 5, the received input is determined. If the result of the determination is that the input is a menu pick, this function is terminated. Also, if it is a normal point power, 5tepH
At step 5, the input is input to point P1, and the processing from step 3 onward is repeated. If the input is any of the items shown in (1) to (3) above, in step 12, P in FIG.
L(x) and pl(y) are changed, display data is recreated, and displayed on the CRT 13 through the VRAM 14.

In addition, if the input is undo (right button on PD12), the movement flag is determined in step 5,
If it is ON, return the currently displayed outline shape to the state before the sample point movement in 5step16, and
Turn off the movement flag in step 17/5te again
If the judgment on p13 is OFF, return the currently displayed outline shape to the state after moving the sample points, and then
In step 15, turn on the movement flag. Move flag to o
By performing NloFF and retaining the contour data before movement and the contour data being moved in PMEM,
By 5tep14.15 and 5tep16.17,
- It is possible to undo a previously moved point by simply operating the right button of the PD 12.

Next, the point alignment S9-e will be explained below using FIG. 61. This function is called by picking the "Align points" or "Align points within area j" menu using the PDI 2. When this function is called, a line cursor in the Y coordinate direction is displayed on the screen.

Point alignment is a function that moves the X or Y coordinate of an arbitrary sample point to the same coordinate as the X or Y coordinate of the reference point, and at the same time corrects and displays the line segment. To align the points, first select the direction of the coordinate axes to be aligned, that is, the X coordinate alignment and the Y coordinate alignment. The selection method is performed by displaying a line cursor on the screen and pressing the middle button of the PD 12. When you pick the "Align points" menu, a Y coordinate - horizontal line cursor will be displayed on the screen.
It is possible to move on to the next step of aligning the points in the Y coordinate-horizontal direction in this state, but in order to align the points in the X-coordinate-vertical direction, use the middle button on the PD12 to move the line cursor to the X-coordinate-vertical direction. Do this by changing the display. Furthermore, the same (
The XY coordinates of the line cursor can be switched using the middle button of the PD 12. Next, with the line cursor displayed on the screen, a reference point is selected by picking an arbitrary sample point with the left button of the PD 12. The selected reference point is highlighted in black, and a line cursor, that is, a reference line, is displayed at the same X or Y coordinate as the reference point. Also, at this time, an cursor is displayed on the cross in addition to the reference line. Note that the position of the reference point (reference line) can be corrected in units of one dot using the arrow keys on the KBDII. Next, select the sample points you want to align other than the reference point. There are two selection methods: picking the points you want to align one by one, and specifying a rectangle and targeting the points within it.

This is executed by pressing the middle button of the PD12. At this time, the line segments are simultaneously corrected and displayed. Note that point alignment can be executed continuously with the cross cursor displayed.

FIGS. 61A to 61F are diagrams sequentially showing the steps of point alignment. (A) shows the initial screen when the "point alignment" menu is selected. A line cursor in the Y coordinate direction is displayed on the screen.

(E) shows a screen that has been changed to a line cursor in the X coordinate direction using the middle button of the PD 12. In addition, at this time, PD
Pressing the middle button 12 returns the screen to (A).

(C) shows a state in which the reference point EO is picked with the left button of the PD 12 while a line cursor in the Y coordinate direction is displayed. At this time, the line cursor is black as a reference line (it is fixed at the Y coordinate of the highlighted reference point, and a crosshair cursor CC is displayed on the screen. (D) shows the position correction of the reference point in the downward direction. This shows the state where a few dots have been added to.

(E) shows a state in which point alignment has been executed for point E1 in (D). Place the crosshair cursor CC' on point E1 and use the middle button of PD12 to move point El to the same Y as the reference line.
The coordinate point El' is moved to, and the line segment is corrected and displayed. (F)
(E) shows a state in which point alignment has been executed for point E2 in (E).

FIGS. 62 and 63 are diagrams showing an example in which points to be aligned are specified by area.

E in Figure 62. is the reference point, l is the indicated rectangle, E,,M
, represents a sample point included within the rectangle l, and M2 represents a sample point outside the rectangle. In other words, we have selected E,,M, as the points we want to align.

Of course, it is possible to add or cancel target sample points regardless of whether they are inside or outside the rectangle.

Figure 63 is E. It is a diagram showing where E,,M, are aligned.

The procedure for point alignment is shown in the flowchart in Figure 64-1 and in Figure 6.
This will be explained using the editing screen shown in Figure 1. Initialize the movement flag indicating whether the movement took 5 tepl to OFF. 5 step 2, select one point in the CRT editing area, for example E.

Input the coordinates of from the PD12. At step 53, a vertical or horizontal line is generated as a reference line from the coordinates input at step 5 according to the vertical and horizontal directions of the cursor, and is displayed on the CRT 13 through the VRAM 14. In 5tep4, KBDI
Enter the amount of movement indicated by the arrow keys above I. 5t
E in ep5. , change P (x) and P (y) in Fig. 10 (d) based on the amount of movement of the reference line input in step 4, recreate the curve parameter table in (e), and create display data. It is displayed on the CRT 13 through the VRAM 14. The reference line is also redisplayed according to the amount of movement.

In step 5, the method of specifying the sample points to be aligned is determined from the input on the PD 12, and a moving point table shown in FIG. 64-3 is created. The moving point table holds the number of moving points (
a), the contour line No. of the moving point, L [i], and the sample point No. P [i], and exists on the PMEM. 5tep6 will be explained in detail using the flowchart of FIG. 64-2. In step 6-1, data from the PD 12 is input. In step 6-2, it is determined whether the input is a point pick (left button). If it is a point pick, 5t
MOVE the picked sample point in ep6-12
Register with TAB. At 5tep6-13, the next input is accepted, and at 5tep6-14.6-15, the accepted input is determined. As a result of the determination, if the input is a point pick, the process from step 6-12 onward is repeated.

In addition, the input at 5tep6-13 is an execution instruction (PD12
(middle button), end 5step6, and press 5te
Execute p7 and later. If the input in 5tep6-1 is not a point pick, in 5tep6-3 it is regarded as the start of region designation, and the position of the PD 12 in 5tep6-1 is set as the coordinates of one point in the region. Similarly, in step 56-4, the position of the PD 12 is set to the coordinates of the diagonal point of the point designated in step 6-1 of the area. 5 step 6-3. The sample points included in the area determined in 6-4 are P (x) and P in Fig. 10(d).
Search by referring to (y) and register with MOVETAB. At 5tep6-6, accept the next input, and at 5tep
67. At 6-8, the receiver judges the input. As a result of the determination, if the input is a point pick, it is determined in 5step 6-9 whether the picked point is registered in MOVETAB, and if it is registered, in 5step 6-9.
The information about the point picked in step 10 is deleted from MOVETAB. If it is not registered, register it in MOVETAB in 5step 6-11. Furthermore, if the input at 5tep6-6 is an execution instruction (the middle button of the PD 12), 5tep6 is ended and 5tep7 and subsequent steps are executed.

In step 5, P( of Figure 1O(d) on PMEM is
The amount of movement is determined by referring to x) and P (y), and the images shown in FIGS. 10(d) and (e) before the change are held in the PMEM 6, and this is designated as PDATA'. P (x) or P (y
) is set to be the same as the reference point, the curve parameter table in (e) is re-created, the display data is created, it is displayed on the CRT 13 through the VRAM 14, and the movement flag is turned ON. FIG. 61(E) shows the state after the movement. In step 5, the next input is accepted, and in steps 9 to 11, the accepted input is determined. As a result of the determination, if the input is a menu pick, this function is terminated. In addition, if the point is a normal point strength, the point is set as a reference point in 5tep12, and the process from 5tep3 onward is repeated. In addition, 5t
If the input in ep8 is undo (right button on PD12), determine the movement flag in 5step13,
If it is ON, return to the state before moving the point in 5tep14, that is, the data of PDATA' held in PMEM6 in 5tep7, and redisplay it, and then
15, the movement flag is turned OFF. Movement flag is OFF
If so, in 5tep16, the data of PDATA changed in 5tep7, that is, the state after the movement is displayed, and in 5tep17, the movement flag is turned ON.

By setting the movement flag to 0N10FF, PMEM6
You can switch the display of PDATASPDATA' above, and by doing so, the point moved once is retained as PDATA (after movement) and PDATA' (before movement) on PMEM6, and the current status can be seen by the movement flag. Therefore, it is possible to return the point once moved in 5tep 13.14 and 5tep 15.16 or to move it again by simply operating the right button on the PD 12.

Next, 39-f contour line deletion in FIG. 4 will be explained using FIG. 67 (illustration of contour line movement) and FIG. 65.

This function is activated by picking the "contour line deletion" menu with the PD 12.

Contour line deletion is a function by which the operator erases any contour line on the editing area. If Ll in FIG. 67 is deleted, the result will be as shown in FIG. 65.

The procedure for contour line deletion will be explained using the flowchart of FIG. 66. Initialize the flag “Erase FLAGJ” to OFF to indicate whether the outline was erased at 5tepl.5te
In p2, the contour line is input from the double-click information of the point on the PD 12. 5 step 3 to create the outline in VRAM1
The data is erased from the CRT 13 through step 4, and the erase FLAG is turned on in step 4. In step 5, the next input is accepted, and in steps 6 to 8, the accepted input is determined. As a result of the determination, if the input is a menu pick, this function is terminated. Also, if it is a normal contour input (double-clicking a point on PD12),
The input is set to L, and the processing from step 3 onward is repeated. In addition, the input of 5tep5 is und.

(Right button on PD12), 5 steps
l.

The erasure FLAG is determined in step 12, and if it is ON, the outline is displayed at 5 tep, and the erasure FLAG is turned OFF in 5 tep12. Further, if the determination at 5 teplo is OFF, the contour line is erased at 5 tep 13, and the erasure FLAG is turned ON at 5 tep 14.

Through the steps 5tepH, 12 and 5step13.14, it becomes possible to erase and redisplay the contour line that has been erased by simply operating the right button on the PD 12.

Yu JLt Ryo1 Contour movement will be explained using FIGS. 67, 68, and 69. Contour movement is started by clicking the "contour movement" menu with the PD12.

Contour movement is a function that moves one or more character contours or specified sections in any direction or by any amount in either the X or Y direction. FIG. 67 shows the character data before movement. FIG. 68 is an example in which the two outlines constituting the character rDJ are moved in arbitrary directions, and FIG. 69 is an example in which 1 is moved in the X direction in the section of FIG. 67.

The procedure for moving the contour line will be explained using the flowchart in FIG. 70. At 5 tepl, initialize "movement FLAGJ", which is a flag indicating whether the contour line or section has been moved, to OFF. At 5 tep 2, input the first point from PD 12. At 5 tep 3, the input from PD 12 at 5 tep 2 is the contour line instruction. (double click), and if it is a contour line instruction, in step 521 and 22, the input of the contour line to be moved is further performed until the end is instructed.

In 5tep3, if it is not a contour line instruction, 5tep3
The PI input at p2 is regarded as the section end point, and at step 5, the other section end point is input from PD12. 5tep
In step 5, points on the section are input, and the moving section is determined in step 5.

In step 5, accept the next input and press step 7.
In steps 8 to 11, the receiver determines the received input. As a result of the determination, if the input is a menu pick, this function is terminated. Also, in the case of normal point power, 5tcp+
In Step 2, the input is set as the first input, and the processing from step 3 onward is repeated. In addition, if the movement amount and movement direction are specified using the arrow keys or numeric keys on the KBDII, or the movement destination is specified by dragging the PD12, the display data of the outline or section is re-created in step 5, and the VRAM1
4, the transferred data is displayed on the CRT 13. 5
Turn on the movement FLAG in step 15.

In addition, if the input of 5tep7 is undo (right button of PD12) (judgment 5tepH), 5tep1
Step 6 determines the movement FLAG, and if it is ON, change the state of the contour line or section before movement to V in step 17.
Display on CRT13 through RAM14, 5tep18
Turn off the movement FLAG with . In addition, if the determination in 5tep16 is OFF, in 5tep19 the state of the contour line or section after movement is transferred to the CRT1 through the VRAM14.
3 and turn on the movement FLAG in step 20. By the above 5 step 17.18 and 5 step 19.20, the contour line and section that have been moved are restored and re-moved to P
This can be done simply by operating the right button on the D12.

Further, the function of moving the contour line or the section in either the X direction or the X direction is realized by referring to the type of input data in 5tep7 in 5tep14.

11 glands Next, virtual line generation 39-h in FIG. 4 will be explained.

Concept Description Virtual line generation is a function that allows an operator to arbitrarily create (generate) a contour line on a variant area, in addition to character contour data. After completing this function, the created contour line can be changed to any shape by performing various changes similar to normal contour lines, such as point insertion and point movement, in other functions. I can do that. The difference between virtual lines and character outlines is that virtual lines are used only for character creation and are not recognized as character outlines.
It is not stored in the font data file even "at the time of registration/termination".

The main purpose of using virtual lines is to use them as templates (underlays) when editing contour data, etc., and to create curved parts that appear continuous, such as sections E1 to E2 and sections E3 to E4 in Figures 71 and 72. The purpose is to easily check or edit the design of curves.

The contour shape initially generated as a virtual line is as described above (
, can be freely changed like normal contour data, and may be, for example, rectangular or circular; however, in this embodiment, an arcuate figure as shown in FIG. 74 is used as a preferred example.

Explanation of Flowchart The procedure for generating a virtual line is shown in the flowchart of Fig. 73 and Fig. 7.
This will be explained using the editing screen shown in Figure 4. At 5 tepl, the flag [Display FLAGJ] indicating whether or not the arcuate figure is displayed is initialized to OFF. In step 5, the coordinates of a point, for example If, in the CRT editing area are input using the PD 12. Next, in step 3, for example, the coordinates of I2 are similarly input. In step 4, outline data (sample point coordinates) of the arcuate figure Y1 is calculated from the coordinate values of It and I2. The contour line Y1 is composed of end points E1 and E2 and intermediate points M1 and M2 as shown in FIG. 74, and the coordinate values of these sample points are calculated as follows.

E 1 x = I l x E1y = 11y E2x = I2x E2V = I2Y M 1 x = I 1 x + (12x - I 1
x) *KMIY=IIY M2x=I2xM2y=I2y (12y-fly) *where,
K is a constant held in the program memory 6 and is 0.55 in the case of FIG. 74. The contour line data Y1 calculated in this way is stored in the VRAM1 in step 5.
After displaying on CTRL3 through step 4, the display FLAG is turned on in step 5. In step 5, the next input is received, and in steps 8 to 11, the received input is determined. As a result of the determination, if the input is a menu pick, this function is terminated. Further, if it is a normal point strength, the input is set as the first fish input in 5tep12, and the processing from 5tep2 onwards is repeated. Also, if it is a reversal instruction (middle button on PD12), 5 steps
Calculate the inverted figure Y2 of the arcuate figure Yl found in step 4.5t
ep13), arcuate figure Y1 currently displayed in 5tep14
, and in step 5 step 15, the arcuate figure Y2 is replaced with the data of the arcuate figure Y1, and the process returns to step 5. That is, the seventh
The inverted figure Y2 on the side indicated by the broken line in FIG. 4 is displayed. In addition, if the input at 5step7 is undo (right button on PDlZ) (judgment 5tepH), 5
The display FLAG is determined in step 16, and if it is ON, the currently displayed arcuate figure Y1 is erased in 5 step 19, and the display FLAG is turned OFF in 5 step 20. In addition, if the determination at 5tep16 is OFF, after displaying the sample point data of the arcuate figure Y1 at 5tep17, the display FLAG is displayed at 5tep+8.
Turn on. 5 step 17.18 and 5 step 1 above
9.20, it becomes possible to erase and redisplay a previously created arcuate figure simply by operating the right button on the PD 12.

Next, the regular arc 59-i in FIG. 4 will be explained using FIG. 75.

This function is called by clicking on the "regular arc" menu on the CRT 13. This function is for CRT1
This provides a means for easily changing the shape of the curved portion of the contour line displayed on the editing area No. 3 into a circular arc or an elliptical arc. Here, for curved parts such as circular arcs and elliptical arcs, this device performs 13-3 line approximation, and automatically generates control points for this, creating mathematically rigorous circular arcs and elliptical arcs. Not that I will.

The operating procedure will be explained using FIG. 78.

Set the unevenness flag to 1 in 5 tepl. 5. In step 2, input the end point P1 of the sample point on the figure. Next 5 step 3
Input the adjacent end point P2 on the same contour line. Pl,,P
From step 2 to step 4, sample points that will generate a new elliptical arc for the curve in that section are calculated. When the coordinates of PI are (Elx, Ely) and P2 is (E2xXE2y), the method for calculating the intermediate point is shown below.

By the X coordinate of the end point El and the X coordinate of the end point E2, intermediate points M1 and M2 are generated as shown in FIG. 76, and the interval E1 to P1 is
It is replaced with the sample point between ~E2.

Coordinates of generated intermediate points M1 and M2 (Mlx, Mly)
and (M 2 x , M 2 y ) are calculated by the following formulas, but which formula to use is determined by the unevenness flag shown in FIG. 78.

M 1 x = E 1 x + (E 2 x −E
1 x )・I or ElxM1y=E]y or E2
y+ (Ely-E2y)・I(M2x=E
2 x or E1x+(E2x-Elx)・IkuM2y=
E2y+ (Ely-E2y)・K or E2Y where,
K is a constant held in the program memory 6. In this way, the circular arc or elliptical arc in the cases of FIGS. 77(A) and 77(B) can be easily generated.

Next, in step 5, the curved portion C1 is displayed. 5tep
The next data N is accepted in Step 6, and the determination is made in Step 5 to IO, and if N is a menu pick, the process ends. Further, if N is the input of the end point P1, return to 5tep3. If N is an instruction to change the unevenness, a sample point with changed unevenness is calculated in 5tep13, the figure is set to 02, CI is erased in 5tep14, and C1 is changed to C2 in 5tep15. Next, set the uneven flag to 2 if it is a power moon, set it to 1 if it is 2, and set it to L/ (step
16), return to step 5 and display C1.

When N is an undo instruction, C1 is deleted and the original figure is restored (step 12). Then, return to step 5 and accept the input of the next data.

1 Skin Note Next, the generation of the figure 59-j will be explained using FIG. 79. This function is called by selecting the "Graphics" menu, and it is possible to easily create shapes such as perfect circles and regular polygons.

Whether to create a perfect circle or a regular polygon is selected from a submenu on the CRT. In this device, all curves are expressed using B-splines, so even when creating a perfect circle, parameters representing the circle, such as center coordinates (x, y) and radius R, must be stored in the form of Instead, it automatically generates about 15 plines of control points, which are necessary and sufficient to approximate a circle. How to create a perfect circle is to use PD to specify the center of the circle, for example Ll, and any point on the circumference, for example L2, on the editing area, or to specify two points that are the diameter of the perfect circle, for example Ml.
, M2 and from the keyboard, the center coordinates,
There is also a method of inputting the radius. L2 when instructing with PD
Alternatively, the perfect circle determined by M2 is also updated on the CRT according to the movement of the PD. In the case of creating a regular polygon, the determination of the regular circle is regarded as the creation of a polytangent circle of the regular polygon, for example C1, and the number of angles is input after determining the regular circle.

Next, regarding the center movement to 59- in Figure 4, 80
This will be explained using figures. This function can be called by "Center"
This is done by clicking on the menu.

Center movement is a function that displays the body frame and baseline and uses the arrow keys to change the positional relationship between the body frame and all contour lines, as shown in Figure 80. Display an italic body frame as shown in Figure 81.

The procedure for moving the center will be explained using the flowchart shown in FIG. 83 and the editing screens shown in FIGS. 80 and 82. 5te
The flag “Moving FLA” indicates whether the center has moved in pl.
Initialize GJ to OFF. In 5 step 2, to make it easier to set the center, remove the virtual line and display the original
FF, sample point display OFF, curve display, contour line display (
The state where the cursor display is OFF is displayed on the CRT 13 via the VRAM 14. 5tep
In step 13, the body frame and baseline are displayed from the character information on PMEM in the same way as in step 2. At this stage, the editing screen appears as shown in FIG. 80. KBD with 5tep4
Input the movement direction data using the arrow keys on the II. In step 5, based on the data input in step 4, the body frame and the baseline are displayed moving instead of the entire contour line in order to speed up the display. When moving the center, it is only necessary to know the relative positions of the body frame, baseline, and contour line as part of the process, so there is no problem with this.

Further, in step 5, the movement amount is held in PMEM.

At 5tep6, accept the next input, and at 5tep7~10
At the receiver, the input is judged. As a result of the determination, if the input is menubic, this function is terminated. In addition, if the input is a movement direction instruction using the arrow keys, turn off the movement flag in 5step18, and
Repeat the process from step 5 onwards. In addition, if the input is the return key on KBDII, the above-mentioned 5t
The sample point coordinates of all outlines are changed as follows from the movement amounts dx and dy held in PMEM in ep5.

Px [i] =Px [i] -dxPy [i]
=Py [ico -dy Change the contour data changed in this way, the body frame and baseline before moving in step 5 as shown in Fig. 82 (CR through VRAM 14)
After displaying on T13, move FLAG to O in 5tep12.
Set to N and return to step 5.

In addition, if the input of 5step6 is undo (right button on PD12) (step), 5step1
3 determines the movement FLAG, and if it is ON, 5te
Return to the state before movement on p16, and move F on 5tep17
Turn off LAG. Also, the judgment of 5tep13 is O
In the case of FF, return to the state in which it was moved at 5tepH, and
Turn on the movement FLAG in step 15. 5 steps above
14.15 and 16.17, it is possible to restore/remove contour data that has been moved by simply operating the right button on the PD 12.

The undo/redo menu is the same as the undo-red mentioned above.
.

The process is set up as a menu and its function is performed. For example, when this menu is picked by one of the other menu Pick etc. of the end process of 5 step 6 in FIG. It performs processing and realizes undo and redo.

Next, the point coordinate display of FIG. 4, 5IO-a will be explained with reference to FIGS. 84 and 85.

Point coordinates are the coordinate values of sample points of font data,
With two coordinate systems (absolute coordinates and design coordinates), you can display the coordinate values in the echo area by picking a sample point on the editing area, or check by displaying a list of all sample points. This is a feature that can be used.

Next, the procedure for displaying point coordinates will be explained using the flowchart of FIG. 85.

At 5 tepl, menu 4 all sample points and menu 5 coordinate system switching menu are displayed. 5tep2 waits for input of next data N, if N is sample point pick, 5t
Display the coordinate values picked in ep4 in the coordinate area.

Display in the coordinate area will be described later.

If N is the pick of menu 5 in 5step 5, 5te
At p6, switch the current coordinate system from absolute coordinates to design coordinates. This menu is a toggle menu item. If Table 1 is displayed at this time, the coordinate values displayed there are also rewritten. If N is Menu 4 selection, Menu 2 for scrolling Table 1, Menu 3 for terminating, and Table 1 displaying a list of all sample points are displayed. Table 1 displays point number, fish debris, X coordinate, and X coordinate in this order. If all sample points cannot be displayed in this area at once, refer to the next page using the scroll menu. N input is 5tep9
If you pick menu 2, scroll Table 1 (step). Display the previous item ↑, display the next item ↓
It is expressed as. When selecting the end menu or other menu picks, perform the end process (step 12) and end.

The termination processing includes processing for returning the menu and erasing Table 1 if it is displayed.

The echo of the coordinate values of the coordinate area will be explained using FIG. 86.

The coordinate values of the picked sample points are displayed in the following way: 86-1 indicates the echoed coordinate numbers 1 to 4, and the coordinates of the picked sample points are displayed as 86-1 for X according to the current coordinate system -2 column, 86- for y
Display them in order from the top row in the 4 column (, When up to 4 is displayed, the echo of the next coordinate is set to 4, the coordinate value in 4 goes to 3, and so on. Scroll to (
, 86-3, and 86-5 display the difference from the previous echoed point, which increases the distance between the two points. Echoing to this area is performed not only for the point coordinate menu function, but also when picking sample points for other character production. 86-6 is a toggle menu for whether or not to echo the coordinates in real time, and when it is ON, the area 86
-7, the coordinate values when dragging the sample point are displayed in real time.

History display The list will be explained using FIG. 87.

The list is a function that displays information about the typeface to which the character belongs and information other than the sample point coordinate values of the character for the font data currently being modified. 87
-1 is an area that displays information regarding the font, and 87-
2 is an area where the value of each character information is displayed for each item, with the value before correction and the current value side by side.

In addition, Ekuzu Gakugo character information is not font data such as the coordinates of sample points that make up a character and its character. It refers to the information related to the character coordinate system, which has a unique value for each character.

In other words, character information can have a value common to the entire typeface as a default, or can have a unique value for each character. In other words, it cannot be set for each character), but there is also information that has a fixed value for the entire font.

Character information input is a function to input character information that can be set for each character as described above, and the value set here is stored in the font data file and is sent to the DI along with the font data.
Stored in SK3.

The procedure for inputting character information will be explained using the flows shown in FIGS. 88 and 89.

When you pick the menu for inputting character information, the menu for inputting character information is displayed in 5 tepl (Figure 88).
88-1 in Figure 8 is YES, which indicates the result of character information input.
, NO1O2O, and 88-2 is a table of menus for inputting each character information name and its value. 5te
In p2, turn off the data manual flag, and wait for the next data N to be input in 5tep3.If the next data N is a menu pick in 5tep4, proceed to 5step5, and then input N.
If is a value input menu, turn on the data flag and 5
Return to step3. When N is not a value input menu, turn off the data input flag L (step 6), 5step 8
If it is a NO menu pick, the newly set input value is returned to the value before the start, and the process returns to step 3. If it is a YES menu pick, check the currently input value and register the setting value (5tepH) 5t
Return to ep3. 5tep12, s'tep13 when N is the end menu or another menu, 5tep14 is 5te
Check the input value in the same way as the pH, register the set value, and finish.

If N is outside the menu pick in 5step 4, 5step 15
If N is the key human power from KBDII, then 5tep1
Proceed to step 6, and when the key is the return key, turn off the data input flag to finish the input, and return to step 3.
If the key is not the return key, go to step 5 step 18, and if the data flag is OFF, do nothing and return to step 3, but if it is ON, go to step 19, echo the input value to the value input menu,
Perform data input processing and wait for the next data input in step 3. In other words, the input value from KBDII can be set in the value input menu only when the data input flag is ON, and the value input menu can be set by picking the value input menu. , only while the return key picks another menu. Also,
During that time, the data N input in step 3 will be echoed one by one to the value input menu.

iKonoKanYodoFigure 4 5ll-6 Line Setting Line setting is a function that allows the operator to set and display multiple auxiliary lines on the editing area in addition to the character outline data, and these auxiliary lines are called lines. , the line has, for example, X
A wind-in parallel to the axial direction and a wind-in parallel to the y-axis direction can be set.

The line set here can be displayed or hidden at any timing during the creation of each character using the line ON-OFF menu of the display control menu described above.

In addition, the set line information can be changed to the DI for each operator.
It is registered in SK3 and can be loaded and referenced on PMEM6 as appropriate unless the settings are changed or deleted.

The main purpose of lines is to serve as auxiliary lines as a reference for determining the size, height, width, etc. of individual characters when creating characters.By determining these auxiliary lines for the entire typeface, it helps to balance the overall character. You will be able to arrange the following.

The line setting procedure will be explained using flowcharts shown in FIGS. 90, 91, and 92.

Picking the line setting menu indicates the line setting result, as shown in FIG. YES, -No.

Each end menu 90-1 and a table 90-2 of menus for inputting line names, positions, and display state switching are displayed.

2, alphabets A to L and a to e in the symbol field correspond to lines A to L and ae in the editing area, and A to L are horizontal lines, and a to el, vertical lines are set. used for In other words, the values entered in the position formula menu field are the X coordinate value for A-L, and the a
For ~e, input the X coordinate value. The display state switching menu field is a menu for switching the display flag for each line to display or hide the set line, and when it is displayed, the line is displayed in the editing area.

At 5 tepl, only lines whose display flags are set to ON are displayed in the editing area according to the current setting state.

5Turn off the data input flag in step 2, and
In step 3, input the next data N. If N is a menu pick in step 4, 5step 5. If the menu picked in step 6 is a name input menu or a position input menu, turn on the data input flag in step 8,
5 Return to step 3, wait for next input, otherwise 5
Proceed to step 9. If N is the display switching menu in step 9, the display flag of the picked line is 0N1.
Switch 0FF and return to 5tep3. If N is a No menu, return the newly set line name, position, and display flag to the state before the start in 5teplO, and return to 5step3. If N is a YES menu, change each line, body frame, etc. according to the display flag in 5step14. It is displayed in the editing area and waits for the next input in 5 steps 3. At 5 steps 15 and 16, if N is the end menu or another menu pick, the currently input setting value is checked and registration is completed. 5tep
18 to 21 are the processes when N is not a menu pick. When using the return key manually, turn off the data input flag at step 19, mainly process the input by KBDII, and end the input, and when using anything other than the return key at step 18. ,
When the data input flag is ON, that is, when data input is possible, the input value is actually echoed to the menu area in step 21, input processing is performed, and the next data input is waited for again in step 3.

FIG. 91 shows, as an example, a state in which the lines in the symbol field a are set. For the line set here, line 0N1
It becomes possible to refer to the 0FF menu.

~Data, by selecting the missing book menu, register Figure 93,
Move to the end screen. Step No. (Sn) shown below is as follows:
This is the number in FIG. 94.

First, a default menu is displayed (Sl).

If necessary, select an appropriate menu 93-1 with the PD 12 and change the line width information (52-S3).

To register data, pick 93-3 with PD12 and KB
The code can be changed by inputting it from the DII (S6). Furthermore, by picking 93-4 with the PD 12, the correction work for that character can be invalidated (S7).

After registration, the next character to be called is the next code by default, but you can pick 93-6 with the PD12 and specify the code freely from KBDII (Sll). 93-7 to PD1
By picking 2, you can also exit the registration end menu without calling the next code (S9).

Finally, it is executed by picking 93-8 with PD12. By picking 93-9 with PD12,
It is also possible to cancel the registration process (S13)
.

[Tube Surface Inspection] The tube surface inspection is started by picking the tube surface inspection menu shown in FIG. 8, and is performed by performing various operations on the basic screen shown in FIG. 95. FIG. 95 will be explained below.

95-1 is a font data file name list, which is a menu for specifying a font data file to be inspected. 95-2 is an area for displaying the font data file name selected in 95-1. 95-3
is an area for specifying the character code range to be displayed using PD12 and KBDII.

For 95-4, the resolution of the output device is PD12, KBD
This is an area for specifying l1. 95-5 is an area for specifying the display point size. Reference numeral 95-6 is a menu area for instructing the type of fill-in display, which will be described later. 957
is a menu for instructing the end of the tube surface inspection, and selecting this menu returns to the control unit. 95-8 is a message area for displaying error messages and the like for various operations. Reference numeral 95-9 is a menu for instructing scrolling (or rehage) of the font data file name mentioned in 1 above.

Instructions for the above menus are provided by PD12 or KBDI.
This shall be done in accordance with I.

The font data file name list 95-1 mentioned above is created by searching DISK 3 when starting the tube surface inspection.

&iSteal Figure 96 shows the screen when the quality inspection shown in Figure 95 95-6 is selected. 96-1 is a data display area. 96-2 is a file name display area of the currently displayed font data selected at 95-1 in FIG. 96-3 is a menu group for controlling the display of the data display area 96-1. 96-4 is an area for displaying the resolution of the output device specified in FIG. 95-4.

In the case of the center inspection, only the one displayed in FIG. 96, 96-1, is for the center inspection, and 96-2 to 96-4 remain the same. If you check the menu of 96-3, you will see the 95th
Return to diagram.

The details of the quality inspection and center inspection are the same as the 85 printer output described later, so please refer to FIGS. 102 and 103 and the details of the printer output. However, the output device is different, and in the screen inspection, the display at step 9 in FIG. 103 is performed on the CRT 13 through the VRAM 14.

[Printer Output Coprinter output is started by clicking the printer output menu a12 in FIG. 8, and is performed by performing various operations on the basic screen shown in FIG. 97.

FIG. 97 will be explained below.

Reference numeral 97-1 is a font data file name list, which is a menu for specifying a font data file to be output. 97-2 is an area for displaying the name of the font data file selected in 97-1. 97-3
is an area for specifying the character code range to be output using PD12 and KBDII.

97-4 is an area indicating the resolution of the output device, in this case the printer. 97-5 is a menu for instructing the type to be described later when outputting the outline. Reference numeral 97-6 is a menu for instructing the size and type of filling output to be described later. 97-7 is a menu for instructing to output character information as a numerical value.

Reference numeral 97-8 is a menu for instructing the end of printer output, and selection of this menu returns to the control section. 97-9 is a message area for displaying error messages and the like for various operations. 97-10 C This is a menu for instructing scrolling (page break) of the font data file name-list mentioned in I above.

Instructions for the above menus are provided by PD12 or KBDI.
This shall be done in accordance with I.

The list of font data file names 97-1 is created by searching DISK 3 when starting printer output.

First, outline display will be explained.

The outline display is performed by specifying the character code range in 97-3 of FIG. 97 and ticking any one of A, B, C, or D in 97-5 of FIG. 97 with the PD 12.

The contents of the displays A, E, C, and D are shown below. That is, A
The outline is 1/2 of the data in the font data file.
For example, if the data in the font data file is defined as 8oo x 8oo dots, it will be displayed as 400 x 400 dots, which is used for a rough quality check, and B is the same as A. However, C shows the inner outline as a dotted line, and C shows one dot of data in the font data file corresponding to one dot of the printer, but at this time, solid lines are drawn between the sample points. The contour line is displayed as a dotted line, and line width information, which is publicly known to prevent quality deterioration at a specific character size, is displayed along with its parent-child relationship. D is used to confirm the validity of information, and the display size is the same as C, but the sample points are shown with dotted lines and the outlines are shown with solid lines.

The outline display processing procedure will be explained using the flowchart of FIG. 101 and the output example of FIG. 98.

At 5 tepl, the start and end codes specified in FIG. 97-3 are held in PMEM6. In 5tep2, the outline type selected in FIG. 97-5 is held in PMEM6. 5 Repeat the process from step 3 onwards. 5tep
In step 3, read the font data from the start code to the end code held in PMEM6 from the font data file of DISK3 in 5 tepl, and write the first
It is stored in the format shown in Figure 02. In step 5, it is determined whether the end code has been output or there is no more data in the font data file, and the outline display process is ended. At 5tep5, the outline type held in PMEM6 at 5tep2 is determined, and if it is C or D, scaling is applied to FIGS. 102(a) and 102(b) on PMEM6 at 5tep6. In step 5, display data is created and stored in the PMEM 6 with reference to (b). In step 5, the outline type is determined again, and in the case of C, in step 9, a line segment representing the parent-child relationship of the line width information is generated based on the data in FIGS. 102 (b) and (C), Hold in PMEM6. At 5 teplO, the sample point coordinate values and debris characteristics shown in FIG. 102(b) are converted into outline display data (line segment sequence data), and the data is stored in PMEM6. 5tep
In H, the data created in 5tep7.5tep9.5teplo and held in PMEM6 is sent to IO and PRT9
The diagram shown in FIG. 98 is then output.

Next, the filled display will be explained.

For filled display, specify the character code range in Figure 97-3, enter the point size range in Figure 97-97-6, and select the "Quality Inspection" or "Center Inspection" menu.
This is done by picking at D12.

The contents of the display for “Quality Inspection” Center Inspection are shown below.

In other words, "quality inspection" involves generating so-called typesetting using a font in the same condition as the product at a specified point size and using it for quality inspection, and "center inspection" involves using a font in the same condition as the product at a specified point size. It is the size and is displayed with scissors in letters for center inspection.

The processing procedure for fill-in display will be explained using the flowchart in FIG. 103 and the output example in FIG. 99.

Enter the output character code range in 5 tepl and select PMEM6
to hold. In 5tep2, the value index size is input and stored in PMEM6. Figure 97 in 5step 3
Is the menu selected in 7-6 “Quality Inspection”?
Whether it is a "center inspection" is held in PMEM6. 5
The processing is repeated for the designated point size for steps 4 to 5 and step 9. 5tep4.5 is the above-mentioned figure 101 5t
Similar to ep3.4, font data is read from DISK 3, and a decision is made as to whether or not to finish. In 5tep6, 5te
The output type instructed in step p3 and held in the PMEM 6 is determined, and in the case of "center inspection", a pattern for inspection is created in step 5. The pattern is, for example, a normal letter such as O or N, or a pattern such as a square, as shown in FIG. 99, Center Inspection. 5tep 8 is 5tep
4, FNTD held in PMEM6 as shown in Figure 102
Image data is created from ATA, taking line width information into consideration. In 5tep9, once the 5te held in PMEM
The data created in p7.8 is sent to 10 and outputted from PRT9 as shown in Figure 99.

Finally, character information output will be explained.

Character information is output by specifying a character code range in 97-3 in FIG. 97 and picking 97-7 in FIG. 97 with the PD 12. The character information displayed here is shown in FIG. 100, for example.

Character information output will be explained using the flowchart in FIG. 104. At 5tepl, the start and end codes specified in FIG. 97-3 are held in PMEM6.

In 5tep2, DI the font data from the start code to the end code held in PMEM6 in the previous 5steps.
Load from SK3 font data file and PME
It is held in M6 in the format shown in FIG. In step 3, it is determined whether the end code has been output or there is no more data in the font data file, and the character information output process is ended. In step 5, referring to FIG. 102(a), the data is formatted and output to the PRT9.

[By picking the Utility main menu, you will move to the Utility menu shown in FIG. 105. The utility will be explained using FIG. 105.

FIG. 105 shows the utility screen. Utilities are C0PY, MERGE, APPEND, DELE
T.E.

It is divided into six areas: RESIZE and MESSAGE. X-1 to X-10 are menus related to CO and PY. X-1 is a font code menu for inputting the font code indicating the copy source file, and C0P
If the Y pattern is all characters, there is an all-characters menu (X-2) that is specified, and an all-characters start code (X-3) that specifies the start code to which all the characters are to be C0PY'd. Code specification menu (X-4) for the start and end codes of the C0PY source when specifying a code, and target code menu (X-5) for inputting the code specification C0PY destination start code for inputting the start code of the C0PY destination. There is. copy
The font code menu (X-6) for inputting the target file font code, the character code menu (X-7) for specifying changes to the character code of this target file, and the processing for the original. There is an original menu (X-8) and a display menu (X-9) as a switch for displaying these processes. The execution menu (X-10) is used to execute the settings of X-1-X to X-9.

X-11-X-21 are menus related to MERGE. X-11 and X-12 are font code menus for inputting the font code of the file to be merged, and X-13 and X-14 are all character menus and code specification menus to be specified when merging all characters of that file. If so, pick the code specification menu (X-15, X-16). There is a font code menu (X-17) for specifying the font code of the merge file. x-18,X
-19, X-20, and X-21 have the same C0PY functions as X-7, X-8, X9, and x-10, respectively. X-2
2 to X-29 huff pend function menu. X-2
2 is the font code menu for inputting the font code of the append source file, X-23 is the all character menu for specifying all characters, X-24 is the coat specification menu for specifying the code, and the font code input menu for the append destination file is used. There is a font code menu (X-25).

X-26, x-27, X-28, and X-29 have the same copy function as X-7, X-8, X-9, and X-10, respectively.

x-30 to X-37 are delete function menus. X-30 is a font code menu for inputting the font code of the file to be deleted, X-31 is an all-character menu for specifying deletion of all characters, and x-34 is a code specification menu for specifying a code. There is a code designation only delete menu (X-32) which indicates that only the code designated in the code designation menu (X-34) is to be deleted, and a delete other than code designation menu (X-33), which is the reverse. X-35 indicates processing for the original, and is an original menu for selecting three processing: no deletion of the original, deletion of the original and outline, and deletion of only the original. X~36, X-37 has copy function X-9
, the same processing as X-10.

This is the X-38 to X-41 beam size function menu.

X-38 is a font code menu for inputting the font code of the file to be compared, X-39 is a compression designation area, and X-40 is an expansion area where you can designate the number of characters. x-41 is a display menu, and x-42 is an execution menu.

X-43 is X-9, X-20, X-28, X-36, X
This is a message menu in the area where processing coats, etc. are displayed when the display menu of -41 is specified.

The X-44 can return to FIG. 8 in the exit menu.

The utilities will be explained below with reference to the numbers in FIG.

Copy First, the copy function will be explained with reference to FIG. 106. For step numbers, refer to FIG. 106(a). Pick the font code (X-1) of the file to be copied (Fig. 106(b)) with P D ]-2 and enter it from the keyboard 11 S4゜Target file (Fig. 106(b)) ) is the target font code (
X-6) with the PD12 and input S5o Determine whether copying is complete S8 If Yes, end; if No, determine whether the copy code specification is all characters S9゜If all characters are specified, As shown in FIG. 106(b), select the all-character menu (X-2) by clicking, enter the character code 2921 of the target file D in the target code menu (X-3), and select the execution menu. (X
-10), S10 copies all characters to character code 2921 and later. In the case of S12° code specification, copy to the left of the code specification menu (X-4) as shown in Figure 106(c). Enter the start code, the copy end code to the right, and enter the target start code in the code specification target code menu (X-5).
Execute the copy by picking the execution menu (X-10) S12゜If you want to specify a target code outside the character code range specified when creating the file, press S
6.S7゜You can specify this using the character code menu (X-7).Also, you can specify whether or not you want to make a similar copy of the original using the original menu (X-8). , To display the processing code, select the display menu (X-9), then select the message menu (X-9).
42).

Merge Next, the merge function will be explained using FIG. 107. Step numbers are those in figure (a). File, 2.3, see Figures (b) and (c).

To display the processing code by merging, pick the display menu (X-20) and check whether it is turned on. If the result of the judgment is Yes, process the message menu (X-43). Display the coat and execute. Pick the font code menu (X-11, X-12) for each file and file2 to be merged and input them S3 and S4゜File created as a result of merging
Select the e3 font code from the font code menu (X-
17) and input S5゜If file3 is to be merged outside the character code range specified at "Create file", select S6, S7゜Merge that can be specified with character code menu 1-(X-18). Determine the end and go to S8, Y
If es, end, if No, determine whether to merge all characters59oIf Yes, file, all characters of file2: ] - (X-13, X14) and select and specify51
If 0°NO, pick the code designation menus (X-15, X16) for each of file and file2 and designate the start and end codes. Execution menu (X-21)
Pick remersion is performed, but it is determined that the code is redundant and S1
2. Merge considering the priority 513, S14 Perform a merge like the character code 2452 in the diagram (b). It is determined whether the original is also to be merged, S15; if Yes, a similar merge is performed; if No, the process ends.

L ki.” Next, the append function will be explained using FIG. 108.

The number of steps is the number in the figure (a).

First, in order to display the processing code using the append function,
Pick the display menu (X-28) and judge whether it is turned on.If the result of Slo judgment is Yes, display the processing code etc. on the message menu (X-43) and execute it.S2゜Next, select the append source. S3゜Pick the font code menu (X-22) and input file2.
-25) and input S4゜At this time, prioritize the file S5゜If you want to append outside the character code range specified when creating the file, you can specify it in the character code menu (X-26). Step S6.878 Next, it is determined whether the append has been completed or not, and S8 is completed.

If so, the append code determines whether all characters are specified.
9. If Yes, pick the all character menu (X-23) and specify. 5IOONo, select file and select the start and end codes of the code you want to append. Pick the specification menu (X-24) and specify Sll.

When the specification is completed, pick the execution menu (X-29) and append S] 2゜ Determine whether to perform the same process on the original by picking the original menu (X-27), S13, Y e If it is s, the same process is performed, and if it is no, it ends.

The tachi-hi-ni-jo delete function will be explained using FIG. 109. Step numbers are those in figure (a).

I want to display the processing code etc. by the delete function on the message 221 (X-36), but I decided 5loYes.
If so, display it S2゜Pick the font code menu (X-30) and input the font code of the file to be deleted S3゜Next, decide what to do with the original 54oIf NO, delete the original. If no, S5, delete only the original S6゜Also, if Yes, delete the original as well S7゜Next, determine whether the code to be deleted is all characters S8゜If all characters, select All Characters Menu (X -3
1) and specify it in step S9, and delete it by picking the execution menu in step S10. If no, select the code specification menu (X-34) to specify the start and end codes of the deletion code. Delete specified code only menu (X-32), Delete other than specified code menu (X-3
3) Determine the deletion method based on 0N-OFF, and proceed to S12.
If the Delete only specified code menu (X-32) is ON, delete only the specified code S13゜If the Delete other than specified code menu (X-33) is ON, delete codes other than the specified code S14゜Ikuritsu Enjin Next, we will explain the resizing function. Refer to FIG. 110 for step numbers.

First, a file name to be compared is input (Sl).

Next, the display of the processing code is set in step S2.Finally, a function is selected and executed in step S3.

Features include compression and expansion. As shown in FIG. 111, compression is performed by first rearranging the data in state A in code order so that there is no gap, and putting it in state B. Finally, the unused area is released, and the file is compressed as shown in C. Expansion changes the size of the data section. As with compression, set it to state B and specify the size of the expansion using the number of characters. If the number of characters is positive, it is 1 in the state of C.
Expand by the average number of blocks of characters x number of characters. If it is negative, the size will be reduced from the state of B by the average number of blocks x number of characters. However, it does not become smaller than state C.

(The following is a blank space) [Effects] As detailed above, according to the present invention, it is possible to automatically determine the attribute of the position where a sample point should be inserted, and by extension, it is possible to generate an appropriate graphic pattern. It has become possible to provide a graphic processing method that allows

(Margin below)

[Brief explanation of drawings]

Fig. 1 is a block diagram of the figure editing device in this embodiment, Fig. 2 is a configuration diagram conceptually representing each function of the figure editing device in this embodiment, and Fig. 3 explains the digitizing function in this embodiment. FIG. 4 is a block diagram explaining the character production function in this embodiment. FIG. 5 is a block diagram explaining the tube surface inspection function in this embodiment. FIG. 6 is a block diagram explaining the printer in this embodiment. FIG. 7 is a block diagram explaining the function of the output, FIG. 7 is a block diagram explaining the function of the utility in this embodiment, FIG. 8 is a diagram showing an example of the initial screen of the figure editing device in this embodiment, and FIG. A diagram for explaining the font data in this embodiment, FIG. 1O is a diagram for explaining the outline data storage unit in this embodiment, FIG. 11 is a diagram for explaining the coordinate system in this embodiment, FIG. 12 is a diagram for explaining file creation in this embodiment, FIG. 13 is a diagram showing the structure of a font data file in this embodiment, FIG. 14 is a diagram for explaining digitizing in this embodiment, FIG. 15 is a flowchart for explaining the digitizing in this embodiment, FIG. 16 is a diagram for explaining scanning in this embodiment, FIG. 17 is a diagram for explaining scanning in this embodiment, Figure 18 is a flow diagram for explaining scanning in this embodiment, Figure 19 is a diagram for explaining code settings in this embodiment, and Figure 20 is a flow diagram for explaining code settings in this embodiment. , Fig. 21 is a diagram for explaining center setting in this embodiment, Fig. 22 is a flow diagram for explaining center setting in this embodiment, and Fig. 23 is for explaining noise removal in this embodiment. Figure 24 is a diagram for explaining noise removal in this embodiment, Figure 25 is a flow diagram for explaining noise removal in this embodiment, and Figure 26 is a diagram for explaining contour line generation in this embodiment. FIG. 27 is a diagram for explaining contour line generation in this embodiment. FIG. 28 is a diagram for explaining contour line generation in this embodiment. FIG. 29 is a diagram for explaining contour line generation in this embodiment. Flowchart for explaining outline generation. Figure 30 is a diagram showing an example of a screen when creating characters in this embodiment. Figure 31 is an undo/r diagram when creating characters in this embodiment.
edo, Figure 32 is a flow diagram to explain interrupt control during character creation in this embodiment, Figure 33 is a block diagram showing display control during character creation in this embodiment, FIG. 34 is a flowchart for explaining display control during character production in this embodiment, FIG. 35 is a diagram for explaining the outline data storage unit during character production in this embodiment, and FIG. 36 is a flow diagram for explaining display control during character production in this embodiment. A diagram for explaining display control during character production in this embodiment, FIG. 37 is a flow diagram for explaining scrolling in this embodiment, FIG. 38 is a diagram for explaining scrolling in this embodiment, 39 is a diagram for explaining scrolling in this embodiment, FIG. 40 is a flowchart for explaining zooming in this embodiment, FIG. 41 is a diagram for explaining zooming in this embodiment, Fig. 42 is a diagram for explaining zoom in this embodiment, Fig. 43 is a diagram for explaining sample point 0N-OFF in this embodiment, and Fig. 44 is a diagram for explaining outline/filling in this embodiment. Figure 45 is a diagram for explaining line 0N-OFF in this embodiment, Figure 46 is a diagram for explaining cursor ON-OFF in this embodiment, and Figure 47 is a diagram for explaining line 0N-OFF in this embodiment. Figure 48 is a diagram to explain point insertion in this embodiment. Figure 49 is a diagram to explain point insertion in this embodiment. Figure 50 is a diagram to explain point insertion in this embodiment. 51 is a flowchart for explaining point insertion in this embodiment, FIG. 52 is a diagram for explaining point attribute inversion in this embodiment, and FIG. 53 is a diagram for explaining point deletion in this embodiment. A diagram for explaining point attribute reversal in this embodiment, FIG. 54 is a flow diagram for explaining point attribute inversion in this embodiment, FIG. 55 is a diagram for explaining point movement in this embodiment, FIG. 56 is a diagram for explaining point movement in this example. FIG. 57 is a diagram for explaining point movement in this example. FIG. 58 is a diagram for explaining point movement in this example. , Fig. 59 is a diagram for explaining point movement in this embodiment, Fig. 60 is a flow diagram for explaining point movement in this embodiment, and Fig. 61 is a diagram for explaining point alignment in this embodiment. Figure 62 is a diagram for explaining point alignment in this embodiment, Figure 63 is a diagram for explaining point alignment in this embodiment, Figures 64-1, 64-2, and Figure 64-3 is a diagram for explaining point alignment in this embodiment. Figure 65 is a diagram for explaining contour line deletion in this embodiment. Figure 66 is a diagram for explaining contour line deletion in this embodiment. FIG. 67 is a diagram for explaining contour line movement in this embodiment. FIG. 68 is a diagram for explaining contour line movement in this embodiment. FIG. 69 is a diagram for explaining contour line movement in this embodiment. Figure 70 is a flowchart for explaining line movement in this embodiment. Figure 7j is a diagram for explaining generation of virtual lines in this embodiment. Figure 72 is a flowchart for explaining line movement in this embodiment. Figure 73 is a flowchart for explaining virtual line generation in this embodiment. Figure 74 is a diagram for explaining virtual line generation in this embodiment. , Fig. 75 is a diagram for explaining the formation of a regular arc in this embodiment, Fig. 76 is a diagram for explaining the formation of a regular arc in this example, and Fig. 77 is a diagram for explaining the formation of a regular arc in this embodiment. Figure 78 is a flow diagram for explaining the formation of a regular arc in this embodiment, Figure 79 is a diagram for explaining figure generation in this embodiment, and Figure 80 is a flow diagram for explaining the formation of a regular arc in this embodiment. FIG. 81 is a diagram for explaining the center movement in this embodiment. FIG. 82 is a diagram for explaining the center movement in this embodiment. FIG. 83 is a diagram for explaining the center movement in this embodiment. FIG. 84 is a flowchart for explaining the center movement. FIG. 84 is a flowchart for explaining the point coordinate display in this embodiment. FIG. 85 is a flowchart for explaining the point coordinate display in this embodiment. is a diagram for explaining point coordinate display in this embodiment, FIG. 87 is a diagram for explaining list display in this embodiment, FIG. 88 is a diagram for explaining character information input in this embodiment, Figure 89 is a flowchart for explaining character information input in this embodiment, Figure 90 is a diagram for explaining line settings in this embodiment, and Figure 91 is a diagram for explaining line settings in this embodiment. Figure 92 is a flowchart for explaining line setting in this embodiment, Figure 93 is a diagram for explaining character data registration/termination in this embodiment, and Figure 94 is a flowchart for explaining character data registration/termination in this embodiment. Flowchart for explaining data registration/termination, Figure 95 is a diagram for explaining tube surface inspection in this embodiment, Figure 96 is a diagram for explaining tube surface inspection in this embodiment, and Figure 97 is a diagram for explaining tube surface inspection in this embodiment. 98 is a diagram for explaining printer output in this embodiment. FIG. 99 is a diagram for explaining blink output in this embodiment. Figure 100 is a diagram for explaining printer output in this embodiment, Figure 101 is a flow diagram for explaining printer output in this embodiment, and Figure 102 is a diagram for explaining printer output in this embodiment. , Fig. 103 is a flowchart for explaining printer output in this embodiment, Fig. 104 is a flowchart for explaining printer output in this embodiment, and Fig. 105 is a flowchart for explaining printer output in this embodiment. A diagram showing an example. Figure 106 is a flow diagram for explaining copy in this embodiment. Figure 107 is a diagram for explaining merging in this embodiment. Figure 108 is a diagram for explaining append in this embodiment. Figure 109 is a diagram for explaining delete in this embodiment. Figure 110 is a flow diagram for explaining resizing in this embodiment. Figure 111 is a diagram for explaining resizing in this embodiment. , FIG. 112 is a diagram showing the display of sample points in this embodiment, FIG. 113 is a diagram showing an example in which sample point Pi is deleted in this embodiment, and FIG. 114 is a diagram showing the display of sample points in this embodiment. FIG. 115 is a flowchart of point deletion in this embodiment. ■... Control unit C 2... Input/output interface 3... External storage device 4... Interface with image input device 5.2. Printer interface 6...Program memory 7...Image input device 8-Image input section 9...Printer IO...Image output section 11...Keyboard 12...PD 13...CRT 14 ・= VRAM 15...CPU

Claims (3)

[Claims] (1) Instruct to insert a sample point into a sample point sequence that has attributes for expressing a graphic pattern, and according to the instruction, based on the attributes of adjacent sample points,
A graphic processing method characterized by determining an attribute of the sample point to be inserted. (2) The graphic processing method according to claim 1, wherein the instruction is to insert a sample point between two adjacent points in the sample point sequence by specifying two adjacent points. (3) The graphic processing method according to claim 1, wherein the determination process is performed as an interrupt process for other graphic processes.