JP3169013B2 - Data output device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data output device which converts outline data representing the outline of a character such as a character or a symbol into dot data and outputs the dot data. It is about securing.

[0002]

2. Description of the Related Art When data representing characters such as characters and symbols are processed using a computer and displayed in any form such as printing or display, dot data is created for each pixel which is the minimum processing unit. Widely used. At this time, if dot data is created in advance for all the characters to be displayed and stored in the memory, an extremely large memory is required.
As described in Japanese Patent Publication No. 17, it is desirable to store a character as outline data representing its outline, and to convert the character into dot data at the time of display such as printing or display by a device provided with data conversion means.

[0003] To convert the outline data into dot data, a pixel screen is used. The pixel screen defines pixels by a plurality of definition lines parallel to the X axis and the Y axis, respectively, which are orthogonal to each other in one plane, and the data conversion unit superimposes the outline of the character on the pixel screen. In such a case, the dot data corresponding to the pixels whose outline includes a portion equal to or greater than a predetermined reference is set as data representing the presence of a character constituent line, and the outline data is converted into dot data.

[0004]

However, when the outline data is converted into dot data and a character is displayed in this manner, even if the same character constituent line is displayed inside the character line depending on the position where the character is displayed, , The number of pixels included in the character, the position, and the like included therein are different, and the width of the character constituent line, that is, the number of pixels included in the width direction in two outlines defining the character constituent line in the width direction is always the same. Not necessarily. The width of the character composition line is determined by the size that the character is displayed with good appearance when designing by the designer,
The width of the character constituent line differs depending on the display position, and when the expected width cannot be obtained, the balance of the entire character is lost and the appearance is deteriorated. When the number of pixels in the width direction is large, the deviation of the width is inconspicuous, but when the number of pixels is small, it becomes remarkable, causing a problem that the display quality is deteriorated.

It is an object of the present invention to provide a data data output device capable of setting and outputting dot data such that the width of a character constituting line has a size corresponding to outline data. .

[0006]

In order to solve the above-mentioned problems, the present invention provides: (a) a character ring composed of a plurality of character constituent lines;
Outline data indicating the guo is provided for each character.
Stored and character storing means has a configuration plurality of characters constituting the (b) the character
Specify at least one of the lines and the width of its constituent lines
Line width setting data indicating the number of pixels corresponding to
Character indicating the line width setting storage means for storing for each data, a character that is input from (c) External
Storage means for storing data; (d) reading character data from the storage means;
Of the character corresponding to the read character data
Reading outline data from the character storage means
And outputting the line width setting data to the line width setting storage means.
It is assumed that the outline of the character represented by the read outline data is superimposed on a pixel screen that defines pixels by a plurality of definition lines parallel to each other in the X-axis direction and the Y-axis direction that are orthogonal to each other. Data conversion that sets the dot data corresponding to the pixels included in the character configuration line that composes the character in a state that satisfies a certain criterion to the data representing the existence of the character configuration line, and converts the outline data to dot data Means , the data converting means of which is read out
When the number in the width direction of the pixels included in the two outlines defining the character configuration line specified by the line width setting data in the width direction is not the number corresponding to the line width setting data. And a contour moving means for moving the contour relative to the pixel screen in a direction and an amount in which the number of the pixels is a number corresponding to the line width setting data, and by moving the contour moving means. Convert obtained outline data to dot data
And it is configured, it is an summarized in that further comprising an output means for outputting the dot data converted by (e) said data conversion means.

The character storage means includes a plurality of character structures.
Outline data showing the outline of the character consisting of lines
Are stored for each of a plurality of characters. Also, line width
The setting storage means stores a plurality of characters constituting the character.
Specify at least one of the
Line width setting data indicating the number of pixels corresponding to the width of the line
It is stored for each of the characters. Storage means outside
Character data indicating the character input from the
Remember. Then, the data conversion means reads from the storage means
Read character data, read character
Before the outline data of the character corresponding to the data
Read from the character storage means and set the line width.
Reading data from the line width setting storage means,
Of the character represented by the outline data
The contour is drawn in the X-axis direction and the Y-axis direction
A pixel screen that defines pixels with multiple parallel definition lines
Character is formed assuming that
Included in the character configuration line that meets certain criteria
The dot data corresponding to the pixel to be
Set the data to indicate presence, and drop the outline data.
To the data. Here, the data conversion means is provided with
Character specified by the extracted line width setting data
Within the two contours that define the component line in the width direction
The number of pixels included in the width direction is determined by the line width setting.
If the number does not correspond to the data,
The direction in which the number of pixels is the number corresponding to the line width setting data
Relative to the pixel screen by and amount
A contour line moving means, and moving the contour line moving means.
Convert the obtained outline data to dot data
You. The output means outputs the data converted by the data conversion means.
Output the cut data. In other words, external storage
When character data is input, the input character
Character outline data and line corresponding to data
The width setting data is read. If the outline defining the character constituent line is moved relative to the pixel screen, the number of pixels included in the character constituent line changes.
Therefore, the key corresponding to the input character data
If the number of pixels in the width direction included in the character constituent line of the character is different from the number obtained by the line width setting data, the outline is moved in the direction and amount by which the number is obtained (by the outline moving means). Move). The outline data is converted into dot data by the movement of the outline, and the output means outputs the dot data. For this reason,
Character composition always for the input character data
The line width is output from the output unit with the specified width.
You.

[0008]

Embodiments of the present invention will be described below with reference to the drawings.

[0009] There are data conversion apparatus capable of securing the width of the key Yarakuta configuration lines. In this data conversion apparatus, for a line of which the width is set among the character constituent lines, the line is designated and line width setting data indicating the width is stored, and the designated character constituent line is defined in the width direction. When the number of pixels included in the outline in the width direction is not the set number, at least one of the two outlines is moved so that the set number of pixels is included in the outline. ing.

However, in the case of maintaining the line width of the character constituting line by moving the contour line as described above, the following problem occurs. As shown in FIG. 12, a case will be described as an example in which a kanji "mouth" and an alphabet "H" are displayed side by side in the X-axis direction. Line width setting data is "mouth"
Is specified so as to maintain the line width of the horizontal lines 100 and 102 parallel to the X-pong, and is created so as to maintain the width at 2 pixels. For "H", the horizontal line 104 is specified and the width is set to 2 pixels. Let's say that it is created to maintain. Then, when the word “mouth” is superimposed on the pixel screen, as shown in FIG. 13, the horizontal line 100 on the upper side (the side having the larger coordinate value in the Y-axis direction) includes only one pixel in the width direction. However, of the two outlines 106 and 108 defining the horizontal line 100, the outline 106 having the larger Y coordinate value is moved as shown by a two-dot chain line in FIG. It is assumed that two pixels are included. However, the coordinate value at the upper end of the vertical lines 110 and 112 parallel to the Y-axis direction has the maximum value in the Y-axis direction, and the length of the vertical lines 110 and 112 in the Y-axis direction is not corrected. Therefore, when “mouth” and “H” are displayed, a shift a occurs at the upper end position (the maximum value of the Y coordinate value) as shown in FIG.

[0011] In addition, even in a single character, display appearance may be deteriorated. A description will be given taking the kanji “member” shown in FIG. 16 as an example. The line width setting data for “member” includes six horizontal lines 110, 112, 114, and 11.
6, 118, and 120 are designated to maintain the line width, and are created so as to maintain the width at 2 pixels. In this case, when the outline of the “member” is superimposed on the pixel screen, as shown in FIG.
Assuming that only one pixel is included in each of the contour lines 122 and 124, one of the contour lines 122 and 124 defining the horizontal lines 112 and 114, and the contour line 1
The line width is corrected by moving either one of 26 and 128, respectively. At that time, with respect to the horizontal line 112, the outline 124 having the smaller Y coordinate value is moved,
Regarding the horizontal line 114, the contour line 12 having the larger Y coordinate value
If each of the lines 6 is moved, the horizontal lines 112 and 114 may come into contact with each other as shown in FIG.

Therefore, the following may be performed. That is ,
( a ') A character is divided into one or more groups each having one or more character constituent lines as constituent units, and outline data of character constituent lines included in each group and at least one of the character constituent lines are designated. A grouping outline data storage unit in which line width setting data indicating the width of the constituent line is stored for each group;
(b ′) When the number of pixels in the width direction included in the two outlines that define the character configuration line specified by the line width setting data in the width direction is not the number corresponding to the line width setting data. If the character constituent line is the outermost constituent line in the width direction in the group, the inner contour line of the two contour lines defining the constituent line is represented by the number of pixels. It provided a contour moving means which moves relative to the pixel screen with orientation and an amount containing a number corresponding to the width setting data, and the data conversion hand stage <br/>, obtained by the movement of the contour line moving means the outline data may be assumed to be converted to dot data.

[0013] In constructed equipment as described above,
If the character component line for which the line width needs to be corrected is the component line located at the outermost side in the width direction within the group, the inner contour defining the component line is moved, and the outer The contour is not moved. Therefore, if a character is divided into one group, in other words, if the character is not divided, the outline that defines the outer shape, such as the height and width of the entire character, cannot be moved. Dot data will be maintained in the positional relationship planned at the time of the creation of the day and evening, and the balance will not be disrupted, and the dot data that is displayed well
Data is obtained.

When the character is divided into a plurality of groups, the outermost contour in the width direction in each group is not moved. Therefore, even if it is necessary to correct the line width of the outermost character constituent line in one group, a gap between the character constituent lines of the adjacent group is secured, and
Dot data that is displayed with good appearance without touching the character constituent lines of the book is obtained.

Hereinafter, an example in which the present invention is applied to a laser printer which converts outline data into dot data and outputs the dot data will be described in detail with reference to the drawings.

FIG. 1 shows a control circuit of a laser printer.
FIG. 3 is a diagram mainly showing a portion related to data conversion. The microcomputer unit 10 which forms the main part of the control circuit includes:
CPU 12, character ROM (character storage means)
14, program ROM 16, text memory (memory
18 ) , a working memory 20, a dot data memory 22, a line width correction data memory 24, and a grouped outline data memory (line width setting storage means) 26. The CPU 12 and the like are connected by a bus 28, and the bus 28 has an input device 30 and a printing unit (output device).
Stage) 32 are connected. The input device 30 inputs necessary data to the microcomputer unit 10, and the printing unit 32 as an output unit is a unit that performs printing by a laser printer system based on a command from the microcomputer unit 10. The resolution of this laser printer is 300 dots / inch.

As shown in FIG. 2, the CPU 12 has a data reading unit 36 and a line width correcting unit 3 for correcting the line width.
8. A data conversion unit 40 for converting outline data into dot data is provided. Text memory 18
Is for storing character data composed of code data inputted from the input device 30, and the working memory 20 is for temporarily storing data necessary for executing a program. Also, the line width correction data memory 2
4 stores data relating to the correction of the line width obtained by the line width correction unit 38, and the dot data memory 22 stores the dot data obtained by the conversion of the data conversion unit 40. The character ROM 14 stores outline data of characters such as alphabets and other characters and symbols. The character is the kanji “member” in FIG.
As an example, each character constituting line 44 is defined by two outlines 46, and each character constituting line 44 is defined by two outlines 46. The length direction is also defined by two lines. This is performed by the contour line 46, and these contour lines 4
6 make up the outline of the character. Contour 46
Form a closed loop, and the "member" includes eight closed loops L1 to L8 as shown in FIG. The outline data includes a group of data representing coordinates of a plurality of points necessary to define the closed loop for each closed loop.
As shown in FIG. 5, the coordinate plane for determining the outline of the character has a vertical (Y-axis) and a horizontal (X-axis) of 1000 × 10
00, and the capital letter of the alphabet is drawn between 200 and 1000 of the Y-axis coordinate value,
Lowercase letters are drawn using between 0 and 200. In this coordinate plane, for a character composed of a plurality of straight lines, such as the kanji “member”, the coordinates of each corner are stored for each of the loops L1 to L8 to form outline data. Also, the letter "D"
For a curve including a curve, a plurality of points required to define the curve are stored for each closed loop, and outline data is formed. At the head of each of the coordinate groups stored for each of these closed loops, the X of the first coordinate of each group is set.
An address at which the coordinate value is stored is stored so that it is possible to distinguish which closed loop is the coordinate group.

The grouped outline data memory 26
When a character is divided into one or more groups having at least one or more character constituent lines as constituent units, line width setting data and outline data of character constituent lines included in the group are stored for each group. Is done. Taking "member" as an example, a first group G1 including a "mouth" composed of four character constituent lines and a second group G including a "shell" composed of eight character constituent lines
2 and the line width setting data is created to maintain the line width of the horizontal line parallel to the X axis. As shown in FIG. 6, the grouping outline data memory 26 stores, for each character, the number of groups NG (2 in the case of “member”) at the beginning of the storage area for the character, and sets the line width. First group G1 as data
The direction of the width of the character constituting line 44 to maintain the middle line width, the coordinate value and the width of the outline 46 are stored.
The width direction is the Y-axis direction in the case of a horizontal line parallel to the X-axis, and is the X-axis direction in the case of a vertical line parallel to the Y-axis,
They are represented by X and Y, respectively. Also, the coordinate values are defined by two outlines 4 defining the character constituent line 44 in the width direction.
6, which is the Y coordinate value for the horizontal line, the X coordinate value for the vertical line, and the larger or smaller coordinate value depending on the position of the character constituent line in one group. Is stored. In the present embodiment, for the character constituent line having the largest coordinate value among the plurality of character constituent lines 44, the coordinate value of the contour line having the larger (outer) coordinate value is stored, and the character constituent line having the smallest coordinate value is stored. For the line 44, the coordinate value of the contour line with the smaller coordinate value (outer side) is stored, and for the character constituent line 44 located therebetween, the character constituent line 44 having the smallest coordinate value and the character constituent line 44 having the largest coordinate value Coordinate values are stored in the same manner as the character constituting line 44 which is closer to the line 44. The width is a distance in the width direction between two outlines 46 that define the character constituting line 44,
When the larger coordinate value of the two contour lines 46 is stored, it is represented by a negative value, and when the smaller coordinate value is stored, it is represented by a positive value. Further, for each group, data specifying a closed loop included in the group after the line width setting data, that is, an address stored for each coordinate group defining the closed loop is stored. In addition,
As shown in FIG. 5, the horizontal lines for which the line width is ensured in the "members" are distinguished by reference numerals H3 to H8. The coordinate value and the width stored as the line width setting data are hereinafter referred to as a set coordinate value and a set width.

In this laser printer, conversion of outline data into dot data is performed using a pixel screen 52 shown in FIG. The pixel screen 52 is a computational one for converting outline data into dot data, but is shown here as an actual one for easy understanding. The pixel here is a minimum printing unit when printing is performed by the laser, and the pixel screens 52 are orthogonal to each other in one plane, and are respectively parallel to the X-axis direction and the Y-axis direction. , Pixels are defined by a plurality of pixel division lines p provided at equal intervals. In the present embodiment, the pixels are square, and dot data is generated for each pixel to determine whether or not to print. Further, an x-direction defining line x and a y-direction defining line y passing through a center point of each pixel (hereinafter, referred to as a pixel center point) and being parallel to the X-axis direction and the Y-axis direction, respectively, are set. The position of the pixel is represented by the coordinates of the pixel center point. Note that the pixel may have a rectangular shape or another shape.

The pixel screen 52 is assumed to correspond to the printing surface of the printing paper, but FIG. 7 shows a part of one character for easy understanding. Therefore, x in the entire pixel screen 52
The scale values actually applied to the direction defining lines x and y-direction defining lines y are values obtained by adding appropriate integers to the scale values given to the x-direction defining lines x and y-direction defining lines y in FIG. However, here, only one character is considered.

The conversion of the outline data into dot data is performed on the assumption that the outline of the character is superimposed on the pixel screen 52. In this embodiment, dots are formed at each pixel within the outline of the character. And the bit data of the pixel is set to 1. The outline includes all or a part of one pixel. In the present embodiment, the bit data of the pixel including the pixel center point in the outline is set to 1.

The present laser printer can print a character in an arbitrary size such as 4.8 points, 10 points, 12 points, 20 points, 24 points, and 30 points.
The coordinate values of the contour created on the 0 × 1000 coordinate plane are converted. The conversion of coordinate values is performed by assuming a coordinate plane representing the length of one side of one pixel as 1 on the pixel screen 52. If a character at a certain point is represented by C × C, 1000 If C / 1000 is multiplied by the coordinate value of each point that determines the contour on the coordinate plane of × 1000, the coordinate value on the coordinate plane assumed on the pixel screen 52 can be obtained. When the outline of the character is superimposed on the pixel screen 52, the coordinate value of the reference point of each character on the pixel screen 52 is also determined based on the print position data. Superposition is performed using the converted coordinate values.

As described above, since the position of the outline of the character on the pixel screen 52 is affected not only by the size of the character but also by the printing position, the character configuration line 44 constituting the same character is also included in the outline in the width direction. The number of pixels included may differ and the width may differ. For example, if a dot formed in one pixel is represented by a circle, FIG.
As shown in (a), the character configuration line whose outline is designed so that the number of pixels in the width direction is 4 pixels is
Depending on the printing position, the width may be 3 pixels as shown in FIG. 8B, and this difference is not so noticeable when the printing size is large, but becomes noticeable when the printing size is small. In the drawing, the mark x indicates the pixel center point.

On the other hand, in the present laser printer, when the print size is 12 points or less, if the line width is different from the set width, the outline data is corrected to set the dot data, and the character constituent line is set at the set width. The program ROM 16 stores various programs necessary for printing, including a dot data conversion program having a line width correction function shown in the flowchart of FIG. The following is an example of printing kanji “member” at 4.8 points.
Conversion of outline data to dot data will be described. Since the printing is not essential for understanding the present invention, a detailed description thereof will be omitted. However, in this laser printer, printing is performed for each page. Data of one page is read out of the document data stored in the text memory 18, and outline data of a large number of characters corresponding to the data is converted into dot data and printing is performed.

First, outline data, grouped outline data, and print size of a character to be processed in step S1 (hereinafter abbreviated as S1; the same applies to other steps) are read out and stored in the working memory 20. You.

Next, in S2, it is determined whether or not the print size is 12 points or less. It is determined whether or not the line width needs to be corrected. If the print size is 20 points, 24 points, 30 points, etc.
If it is larger than 2 points, the judgment result is NO,
In S23, setting of dot data is performed. The outline of the character is superimposed on the pixel screen 52 as it is, and the dot data corresponding to the pixel including the pixel center point in the outline is set to 1 and stored in the dot data memory 22.

On the other hand, if the print size is 12 points or less, S2 becomes YES, and in S3, N1 is set to the number of groups NG (here, 2).
The count value C1 of the first counter is set to 1. The first counter counts the number of groups that have been subjected to the line width correction processing. In S4, it is determined whether or not the count value C1 is greater than N1, that is, whether or not the line width correction processing has been completed for all the groups. However, since C1 is set to 1, the determination is NO and S5 is executed.
In S5, the number NS of character configuration lines (referred to as the number of width configuration components) included in the line width configuration data in the first group G1 is searched, and N2 is set to the number Ns of width configuration configuration lines. This search is performed based on how many character constituent lines are set between the group number data and the outline designation data in the case of the first group G1, and in the case of another group, the data is set adjacently. This is performed depending on how many character constituent lines are set between the group outline specifying data and the data. N2 is a value to be compared with the count value C2 of the second counter that counts the number of character constituent lines of one group, and the processing of S8 to S11 described later for all the character constituent lines of one group by the comparison. Is determined.

After the count value C2 of the second counter is set to 1 in S6, C2 is set to N2 in S7.
A determination is made as to whether the value is greater than
In S8, it is determined whether or not the width of the character constituent line designated by C2, that is, the width of the first character constituent line H3 included in the first group G1 is a negative value. The determination is YES because the width is -75.
Then, in S9, a value obtained by adding the set width (−75) to the set coordinate value (1000) of the character constituent line H3 is calculated, and in S10, the absolute value | 75 | of the width is calculated, and each calculated value is calculated. The values are replaced with the previous set coordinate values and the set width, respectively, and stored in the working memory 20. Next, after the count value C2 is increased by 1 in S11, the execution of the routine returns to S7. Since the first group G1 includes two character constituent lines, S
7 is NO, and since the set width stored for the character constituting line H4 is a positive value, S9 and S10 are not executed, and the set coordinate value and the set width are not corrected.

Next, when S7 is executed, the determination becomes YES and S12 is executed, and the line width setting data in the first group G1 is rearranged in ascending order of the set coordinate values of the character constituent lines. Subsequently, after the count value C2 of the second counter is set to 1 in S13, it is determined in S14 whether C2 is greater than N2. 1st group G
The determination of the line width correction and the determination as to whether or not the line width has been corrected are performed for all of the character constituent lines specified in 1. This determination is NO, and S15 is executed. In S15, it is determined whether or not the count value C2 is 1. Since the count value C2 is set to 1 in S13, the determination in S15 is YES
S16 is executed, and it is determined whether the line width correction is necessary for the first character constituent line among the character constituent lines rearranged in S12, that is, the character constituent line having the smallest set coordinate value in the width direction. Is determined.

In this judgment, the set coordinate value and the set width are determined based on the print size and the print position data by the pixel screen.
This is performed by converting the coordinate value on the button 52. The coordinate value and the width constituting the line width setting data are 1000 × 10
Since the value is set on the coordinate plane of 00, the conversion is performed. The width is 1000 × 1 side of one pixel.
It is converted by dividing by the value at 1000 coordinates (50 when the print size is 4.8 points). Regarding the width, if a value of the first decimal place or less appears, the value of the first decimal place or less is rounded off to obtain an integer value. This integer value is the number of pixels to be included in the width direction of the character constituting line, and is stored in the working memory 20 together with a value that is not rounded off (the distance between two contour lines in the width direction). The coordinate value of the coordinate group defining the closed loop is also 1
This value is set on the 000 × 1000 coordinate plane, and this value is converted when the coordinate values of the coordinate group are simultaneously corrected for line width correction in S21 described later.

After the conversion of the set coordinate value and the set width, it is determined whether or not the calculated number of pixels is included between the converted coordinate value and the coordinate value obtained by adding the converted width from the coordinate value. Is determined, and if it is included, the line width is not corrected,
If the number of pixels is insufficient or excessive, one of the two outlines is moved to include a predetermined number of pixels. When correcting the width of the character constituent line H4 having the smallest set coordinate value in one group, the contour having the coordinate value obtained by adding the set width to the set coordinate value is moved to correct the line width. With respect to the character component line located on the outermost side in the width direction within one group, the inner contour line is moved so that the set number of pixels is included in the character component line. The inner contour is moved by a minimum amount necessary to include a predetermined number of pixels, and the coordinate value obtained by the movement is set as a corrected coordinate value, together with the uncorrected coordinate value of the coordinates before correction. It is stored in the line width correction data memory 24.

After that, after the count value C2 of the second counter is increased by 1 in S20, the execution of the routine is executed in S20.
Return to 14. Since the first group G1 includes two character configuration lines, S14 becomes NO, and S15 also becomes NO, and S17 is executed. In S17, C
It is determined whether or not 2 is the number NS of the width setting constituent lines, that is, whether or not to perform the line width correction determination for the character constituent line having the largest set coordinate value within one group. Since the count value C2 is 2, and the number NS of the width setting constituent lines in the first group G1 is 2, S17 becomes YES and S1 becomes
Step 18 is executed to determine whether or not the line width of the Ns (2) -th character constituent line (H3) needs to be corrected. If necessary, the line width is corrected. This determination is made after the set coordinate value and the set width of the character constituting line H3 are converted based on the print size and the print position data as in S16, and if the line width needs to be corrected, the set coordinate value is set. The contour line with the value is moved. This set coordinate value is the value corrected in S9. Even in the case where the set coordinate value is the largest and the outermost character constituent line H3 in one group, the character constituent line H3
Of the two contours that define, the inner contour is moved to correct the line width.

When S14 is executed next after execution of S20, S14 becomes YES, and the first group is set in S21.
Based on the specified data of the closed loops L1 and L2 included in the loop G1, the coordinate values defining the closed loops L1 and L2 are read from the outline data, and the uncorrected coordinate values (set coordinate values) are selected from the coordinate values. The same Y coordinate values as in (1) are searched, and these Y coordinate values are simultaneously replaced with corrected coordinate values and stored in the working memory 20. Closed loop L
The coordinate values defining 1, L2 are 1000 × 1000 coordinate values, which are converted into coordinate values on the pixel screen 52 based on the print size and print position data, and then corrected. Thereafter, in S22, the count value C1 of the first counter is increased by 1, and the execution of the routine returns to S4.

Now, C1 = 2, N1 = 2 and S4
Is NO, and thereafter, S5 to S11 are executed as described above, and the character configuration line H5 included in the second group G2 is included.
If necessary for .about.H8, the set coordinate value and the set width are corrected. After the correction, S12 to S20 are executed, and the line width is corrected. Since the second group G2 contains four character constituent lines and NS = 4, when the number NS of width setting constituent lines is 2 or 3, respectively, and the character constituent lines H6 and H7 are designated, S17 is executed. NO, S
Step 19 is executed to determine and correct the line width. The character constituent lines H6 and H7 are not the character constituent lines located in the outermost part in the width direction within one group, and even if any one of the two contours defining the constituent lines is moved to correct the line width. Although it is good, in the present embodiment, it is assumed that the contour having the set coordinate values, that is, the contour having the smaller coordinate value is moved to correct the width. Then, the set coordinate value and the corrected coordinate plant are stored in the working memory 2.
0, and in S21, among the coordinate values defining the closed loops L3 to L6, the same coordinate values as the set coordinate values are replaced with the corrected coordinate values.

When the correction of the line width is completed for all the character constituent lines H5 to H8 specified in the second group G2, the determination in S4 becomes YES, and the step S23 is executed to convert the outline data into dot data. . The coordinate value of the converted outline data is a value corrected so that the width of the character constituent line becomes the set width,
A character printed based on the converted dot data has a good appearance with a secured line width. In addition, the characters are divided into groups, and for the character component lines located on the outermost side in the width direction of each group, the inner outline is moved and the line width is corrected,
Due to the correction of the line width, the outermost character constituent lines of the adjacent group do not touch each other, and as shown in FIG.
It is possible to obtain a good-looking print in which the space between the character constituent lines is secured while the line width is secured.

The case where the character is divided into a plurality of groups has been described above. However, as in the case of the kanji character "mouth" shown in FIG. is there. In this case, the horizontal lines (H10, H1
It is assumed that the line width is secured for 1), and the grouping outline data is created as shown in FIG. Then, in the data conversion routine, S5 to S11 are executed in the same manner as in the case where the data is divided into a plurality of groups. The absolute value of the set width is obtained. The determination and correction of line width correction are performed by executing steps S12 to S22. Character constituent lines H10 and Hll are constituent lines located at the outermost side in the width direction in one group, and are respectively set. The inner contour is moved to correct the line width. Therefore, even if the line width is corrected, the outer shape of the “mouth” does not change.
A good-looking print can be obtained without losing the balance with the adjacent character. In this way, dividing the character into one group and moving the inner outline for the outermost character component line means that the outline that defines the outermost shape of the character is moved when correcting the line width. This is the same as setting a regulation not to let them.
When the character is divided into one group, if S5 to S22 are executed once, S4 becomes YES, and S23 is executed to convert the outline data into dot data.

As is apparent from the above description, in the present embodiment, the portion for storing S23 of the program ROM 16 and the portion for executing S23 of the CPU 12, that is, the dot data conversion section 40 constitute data conversion means. Character ROM 14 constitutes character storage means
And the grouped outline data memory 26 sets the line width.
The text memory 18 constitutes a fixed storage means.
Since the portion that stores S3 to S20 of the program ROM 16 and the portion that executes those steps of the CPU 12, that is, the line width correction unit 38 constitutes the contour moving unit, and the printing unit 32 constitutes the output unit, is there.

In the above embodiment, the case where the width of the horizontal line is corrected among the plurality of character constituent lines constituting the group has been described, but the width of the vertical line may be corrected.

In the above embodiment, the outline data is stored in the grouped outline data memory 26 by the closed loop designation address.
The coordinate value itself defining the closed loop may be grouped and stored.

Furthermore, in the above-described embodiment, the character is divided so that one group includes a plurality of independent character constituent lines. However, the character division is performed so that one character constituent line belongs to a different group. The character may be divided.

In addition, without departing from the scope of the claims, the present invention can be carried out in various modified and improved forms based on the knowledge of those skilled in the art.

[0042]

As is apparent from the above description,
In the data output device according to claim 1, a character
A character whose storage means is composed of a plurality of character constituent lines
Outline data showing the outline of
Is stored for each character , and the line width setting storage means constitutes the character.
Specify at least one of multiple character composition lines
Line width indicating the number of pixels corresponding to the width of the constituent line
Setting data is stored for each of the characters,
When character data is input to the storage means from the
The data conversion means is character data input to the storage means.
Outline data and line width setting of character corresponding to
And read the data. If the contour defining the character constituent line is moved relative to the pixel screen, the number of pixels included in the character constituent line changes. Therefore, when the number of pixels in the width direction included in the character configuration line is different from the number obtained by the line width setting data, the outline is moved in the direction and amount by which the number can be obtained (the outline moving means). Move). The outline data is converted to dot data by moving the outline, and the dot data
Is output from the output means. Therefore, any input from outside
Character composition lines are always
It is possible to output with a width corresponding to the line width setting data , and there is an extremely excellent effect that a character can be output with good visibility by eliminating unevenness in width due to a difference in output position.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a control circuit of a laser printer including a data conversion device according to an embodiment of the present invention.

FIG. 2 is a diagram conceptually showing a CPU which is a component of the control circuit.

FIG. 3 is a flowchart showing a data conversion routine among routines stored in a program ROM of the control circuit.

FIG. 4 is a diagram showing “members” of kanji converted by the data conversion device.

FIG. 5 is a diagram for explaining setting of line width setting data of “member”.

FIG. 6 is a diagram showing a grouping outline data set by dividing the “member”.

FIG. 7 is a diagram showing the “members” superimposed on a pixel screen.

FIG. 8 is a diagram illustrating a difference depending on a print position of an outline defining a character constituent line.

FIG. 9 is a diagram illustrating printing when the outline data of the “member” is converted based on the data conversion routine.

FIG. 10 is a diagram showing a “mouth” converted by the data conversion routine.

FIG. 11 is a table showing grouping outline data set for the “mouth”.

FIG. 12 is a diagram illustrating conversion of outline data into dot data.

FIG. 13 is a diagram illustrating conversion of outline data into dot data.

FIG. 14 is a diagram illustrating conversion of outline data into dot data.

FIG. 15 is a diagram illustrating conversion of outline data into dot data.

FIG. 16 is a diagram illustrating conversion of outline data into dot data.

FIG. 17 is a diagram illustrating conversion of outline data into dot data.

FIG. 18 is a diagram illustrating conversion of outline data into dot data.

[Explanation of symbols]

 10 Microcomputer section 44 Character composition line 46 Contour line 52 Pixel screen X X direction specified line Y Y direction specified line

Continuation of front page (56) References JP-A-4-104295 (JP, A) JP-A-3-38691 (JP, A) Patent 3038840 (JP, B2) (58) Fields investigated (Int. Cl. ⁷⁾ , DB name) G09G 5/24 B41J 2/485 G06T 5/00 G06T 9/20 G06T 11/20

Claims (1)

(57) [Claims] 1. A character comprising a plurality of character constituent lines.
Outline data showing the outline of the data
Character storage means for each character, and a plurality of character constituent lines constituting the character.
Specify at least one and correspond to the width of its constituent lines
Line width setting data indicating the number of pixels to be
Line width setting storage means for storing each character, and character data indicating a character input from outside
Storage means for storing character data, and character data is read out from the storage means and read out.
Out of the character corresponding to the input character data
When line data is read from the character storage means,
In both cases, the line width setting data is read from the line width setting storage means.
It is assumed that the outline of the character represented by the outline data read and read is superimposed on a pixel screen that defines pixels by a plurality of definition lines parallel to each other in the X-axis direction and the Y-axis direction that are orthogonal to each other. If you do
Data conversion means for setting dot data corresponding to pixels included in a character configuration line constituting the character in a state satisfying a certain standard to data representing the presence of the character configuration line, and converting outline data to dot data ;
The provided, the data conversion means, the number in the width direction of the pixels included character configuration line designated by the line width setting data to which the read in two contour lines defining the direction of the width When the number of pixels is not the number corresponding to the line width setting data, the outline is moved relative to the pixel screen in the direction and the amount in which the number of the pixels corresponds to the number corresponding to the line width setting data. Means for converting outline data obtained by the movement of the contour line moving means into dot data .
It and the data output apparatus characterized by comprising the further and output means for outputting the converted dot data has been by the data conversion unit.