JPH03259193A - Gray scale character display device - Google Patents

Abstract

PURPOSE:To economically generate and display high-definition gray scale character by providing a filter means which smooths a character font read from a storage device. CONSTITUTION:This device is provided with a multileveling means 21, a smoothing means 22, and a size converting means 23. The multileveling means 21 converts a binary character font read from binary font memory into a multilevel signal of 256 gradations; the smoothing means 22 is the filter means which smooths a character font converted into the multivalue signal of the 256 gradations by the multileveling means 21, and which generates a gray scale character signal; and the size converting means 23 alters the size of the gray scale character signal generated by the smoothing means 22. The size-converted picture signal at every page is outputted to a CRT display device 4 to accomplish display. Thus, the generation and display of gray scale characters are achieved at a low cost when disk top parallelling is carried out, and also when its state is previewed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention is applied to a character font display device in an information processing device. The present invention is particularly useful for information processing devices capable of fine printing, in which the printing status can be previewed and displayed on the display device.
- Concerning means for converting the desired character font.

〔overview〕

In the display control of an information processing device that displays stored character fonts on a display device, the present invention smoothes and displays the character fonts to make it easier to see and preview the printed output on the display. This makes it easier to do so.

[Conventional technology]

Desktop publishing (hereinafter referred to as DTP), which performs minute printing using a small information processing device, has become possible. This DTP uses an output device such as a laser printer capable of fine printing at 240 to 400 dpi to print documents, etc., including drawings created by an information processing device in a form similar to type printing.

By the way, in order to perform DTP using such an information processing device, it is necessary to perform a preview on a display device such as a CRT display device before printing to check the state of the layout etc. after output.

However, as shown in FIG. 8, the display control of a conventional CRT display device is limited to character code strings for outputting binary character font image data stored in the memory 1, such as R, OM, etc. Correspondingly, the image data is read into the binary image display device 3, converted into a binary image signal, and displayed on the CRT display device 4 page by page. Note that when DTP is performed using a printer or the like, the binary image display device 3 converts the image into a bitmap font or the like and prints it on an output device (not shown).

[Problem to be solved by the invention]

However, in a CRT display device, the number of display dots is naturally limited, and the amount of character pattern data that can be displayed is small, resulting in poor resolution and poor image quality.

For this reason, it was insufficient to preview for DTP.

By the way, CRT display devices for workstations, which are capable of highly detailed display, can display 1280 x 1024 pixels and have good image quality, so it is difficult to display character fonts to be printed on such CRT display devices. It is considered to do.

For such a display, data obtained by converting bitmap data in a format to be printed into a binary signal is simply thinned out to, for example, 1/3 in accordance with the number of display pixels of a CRT display device.
If ×3 pixels correspond to one pixel and are displayed on the CRT display device, it becomes possible to view the printed data as is on the screen even on the CRT display device. However, the image data obtained by simply converting the character font into a binary signal can be converted into a C
Even when displayed on an RT display device, the font was awkward and inconvenient for humans to read, and was insufficient to realize the preview function of DTP.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned drawbacks, and aims to provide a display device that can economically generate and display high-quality grayscale characters that are close to natural fonts and can preview the printing state of DTP. shall be.

[Means to solve the problem]

The present invention provides a character display device for an information processing device that includes means for reading out a character font corresponding to a character code to be output from a storage device and outputting it to the display device, wherein the character font read out from the storage device is smoothed. It is characterized by comprising a filter means.

Note that this character display device includes a multi-value converting means for converting the read binary character font into a multi-value font, a filter means for smoothing the multi-value font converted by the multi-value converting means, It is preferable to include resampling means for changing the size of the character font smoothed by the filter means.

The present invention also provides a character display device for an information processing device that includes means for reading a character font corresponding to a character code to be outputted from a storage device and outputting it to the display device, wherein a binary character font read from the storage device is provided. The present invention is characterized in that it includes means for simultaneously smoothing character fonts and converting their size by performing linear interpolation of neighboring points.

Note that it is preferable that the smoothing applied to the character font be performed more strongly in the w, 17 direction than in the horizontal direction.

[Effect]

The binary character font image to be displayed on the display device is read out from the storage device and converted into a multi-value signal of 1 pixel and 1 byte. against 3
Smoothing processing such as ×3 pixel smoothing local processing is performed to generate gray scale characters. Then, this smoothed character signal is resampled by interpolation and character size conversion is performed to change the size of the character font.
Send and display on a display device.

It is also possible to simultaneously generate grayscale characters by smoothing the character font and converting the character size using neighborhood linear interpolation processing.

〔Example〕

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

FIG. 1 is a diagram 11112 showing the configuration of a grayscale character display device according to an embodiment of the present invention.

In this embodiment, an image of a binary character font ('11111) stored in a memory 1 storing a binary character font (corresponding to a character code string to be outputted) is read out with [,1,
A multivalued image display device 2 converts the signal into a gray scale character signal and outputs it to a CRT display device 4. This multi-value image display device 2 is characterized by a multi-value converting means 21 for reading from the memory 1 7' and converting a binary character font into a multi-value signal of 256 gradations; This filter means generates a clay scale character signal by performing a smoothing process on the character font converted into a 256256 gradation signal by the multivalue conversion means 21; The conversion means 22C is provided with snow size conversion means 23 and 4 for changing the size of the generated clay scale character signal.
The image signal corresponding to the number of pixels is outputted to the CRT display device 4 and displayed.

Next, FIG. 2 shows the processing operation procedure of the first embodiment of the present invention, and its operation will be explained.

The image data of the binary character font stored in the memory 1 is read in accordance with the character code string to be output that is input to the multivalued image display device 2 (step 511).
. This binary character font image is subjected to double size conversion (step 512). , this double size conversion is necessary because in normal character fonts, the horizontal line consists of one dot, so there is a risk that the horizontal line will be lost when converting the character size by re-symbling. to make two horizontal lines. However, this processing is not always necessary, and the double size conversion may not be performed.

This double size conversion process includes a simple double size process or a 4-point neighborhood linear interpolation enlargement process. During.

Pure double size conversion processing, for example, when smoothing a 12 point character font, simply doubles the 6 point character font to generate a virtual 12 point binary character font with two -C horizontal lines. It is something. This process produces clear horizontal lines, but the diagonal lines become jagged.
The entire text becomes awkward. The 4-point neighborhood linear interpolation enlargement process is a method of enlarging while performing linear interpolation, and is able to remove jaggedness in the diagonal line parts better than the simple double size process.

The binary character font size-converted or not size-converted in this way is processed by the multi-value converting means 21, where each pixel is 1.
It is converted into a high-level multi-level signal (step 513). In this case, set the text font black to "255" and white to "0".
”. Conversion to multi-values from O to 255 is necessary because current CRT display devices have a display function of 256 gradations.
, which allows grayscale character display to be performed at 256 gradations.

Smoothing processing is performed on the image of the multivalued character font converted into a 256-level multivalued signal in Slap S13 to generate a gray scale character font (step 514).
. This smoothing processing is performed by known image smoothing processing means such as linear smoothing processing, 3x3 pixel smoothing processing, and 5x5 pixel smoothing processing.

The grayscale character image signal generated by the smoothing process is resampled to convert the character size, and is output to the CRT display device 4 (step 315).
．． 16).

Here, the smoothing process will be described in detail.

This smoothing process includes linear smoothing, 3x3 pixel smoothing,
Alternatively, there is a method such as 5×5 pixel smoothing.

First, we will discuss the linear smoothing method.

In this linear smoothing, the entire image is weighted 1.2.1, and each pixel is weighted 1.2.2 in rask order (horizontal direction).
．． Multiply the weight by 1, write this multiplied value in the vertical direction, and repeat this process. Then, this means that the vertical and horizontal sides of the image are multiplied by a weight of 1.2.1, and this linear smoothing for the character font pixels is equivalent to smoothing the horizontal lines of the character font by applying more smoothing in the vertical direction. This has the advantage that horizontal lines will not be missing during resampling. However, although this linear smoothing has simple parameters and is fast to process, it is necessary to adjust the number of times of vertical and horizontal multiplication, making setting parameters troublesome and making the process complicated.

Next, 3×3 pixel smoothing processing will be described with reference to a processing flowchart shown in FIG.

This 3 x 3 pixel smoothing is a local processing method used in image processing, in which 3 x 3 = 9 pixels are extracted, each pixel is multiplied by the smoothing parameter shown in the table below, and the sum is calculated and averaged. It is something.

This is equivalent to performing smoothing. In addition, in this table, the denominator of the weighting number is omitted.

At this time, by setting the value of the smoothing parameter a-i to a value that emphasizes the horizontal line, it is possible to prevent the horizontal line from being missing during resampling. Further, by adjusting the value of e, the density of the line can be adjusted, and it is possible to prevent the black from becoming lighter due to smoothing.

This will be explained in detail with reference to a flowchart.

First, one pixel is pasted around the image area A of the multi-valued character font to make it the width of the image area.

This process corresponds to preprocessing for 3×3 pixel smoothing. The value of this pasted pixel is set to "0", which corresponds to white (step 531). Next, extract 3×3 pixels centered on one pixel in image area A, which corresponds to the character font area (
Step 532). Then, it is determined whether the value at the center of these 3×3 pixels is “255” (ff in hexadecimal) (step 533).

If it is "255", the value is set to "255" without being multiplied by the smoothing parameter (step 534).

This is to adjust the density of the text font, and if you multiply the black text font by the above smoothing parameter, it will become lighter.
This is because black character fonts need to have black values as they are.

If the value at the center of 3×3 pixels is not “255”, 3×
The three pixels are each multiplied by the corresponding smoothing parameter, and the sum is taken as the average value of the pixels (step 535).

An example of this smoothing parameter is given below.

The smoothing parameter in this table is to strengthen the horizontal line, and is 3
By changing the value of the middle row of ×3 pixels, the horizontal line can be emphasized. As the smoothing parameter for this 3×3 pixel smoothing, the following can be used, and the value of the smoothing parameter can be freely set depending on the degree of horizontal line emphasis and black emphasis.

The sum obtained by the process of step S34.35 described above is written in the image area C (step 536), and the process of step 5 described above for the multivalued character font image area A is performed.
32-33 [Repeat the process of i, and when the desired number of smoothing is completed, judge 11rL (step S37.38),
Furthermore, i,, - when performing smoothing processing; second, the sum image area (゛蓓3
At step 539, the 3×3 pixel smoothing process is performed again, and when the situation processing is completed, the process moves on to the next resampling process.

In the case of 5 x 5 pixel smoothing, two pixels S are pasted around the multivalued character font image area to be smoothed, and a 5 x 5 pixel smoothing parameter is applied to all pixels of image area A. Multiply the meter, take the sum, and smooth.

An example of this smoothing Paragraph 7 is shown below. Note that the denominator is omitted in this table.

-1- The 3 x 3 pixel smoothing described above simplifies this 5 x [) pixel smoothing, and the 5 x F) pixel smoothing described in \,2, provides even stronger smoothing. '4ru1,5 is iq
It is Noh.

Also, in the resembling jig, when J'n°) size conversion is performed, :3>, :3 pixel flattening, 04(] times more than 4 bits are leaked. But ;1×
With 5-pixel smoothing, there is no risk of bit smearing due to resemblance up to 0.250'1.

Next, I will explain the re-zampling process.
This is because it is necessary to change the character size to display the divine size characters on the display device 4 in response to the printing mode of ',''P. In this embodiment, the conversion of the character size of V:l is performed in line-7 by resampling processing using four-point interpolation in the vicinity.

This resampling process is used for the fourth flash.
As shown in 1., the size of the sampled gray and /-scale character fonts is set to SN7:E, and the size of the brace wool multivalued character font to be output is set to 5IZe, Zan'.
When the printing interval is 5 tep, the interval is set to 5 tep over the entire image, but resampling is performed.

, "°6" is, for example, when trying to reduce 12 dots vertically and horizontally to 173, the gambling interval is usually set to 3. Therefore, as in the above equation, (12-1) /' (4-1) 11/
3! If you sample at the gambling interval of i3.67, the gambling interval will widen and there is a risk of missing bits, but if the character font is missing, the 5T-ro will disappear.

In this way, by resampling -, -2
A grayscale character font of a desired size can be generated and output to the CRT display device 4.

The output results according to the above embodiment are shown in FIG.

This figure 5 uses a 12 point dpi font of 0.8
This is displayed at 8 times the original size for explanation purposes. Figure 5 (a) shows the result obtained by linear interpolation after smoothing once, ([)] shows the result obtained by linear interpolation after smoothing 3 times, and (C) shows the result obtained after smoothing once. 1. Perform linear interpolation 2.
It is a value. As a result, there is a correlation between the magnification of the font size and smoothing, and for 12 point characters, 3 times at 014 times, 2 times at 0.5 times, and 2 times at 0.5 times.
At 0.8x, smoothing is performed about once ↓b) It was found that the highest quality font can be obtained.

Next, FIG. 1 shows the configuration of the second embodiment.

In this second embodiment, multi-value character font data is smoothed to scale and re-gumbled simultaneously. 3. The smoothing process of multi-value character font data in this second embodiment is Crew scaling and character rise conversion are performed simultaneously by linear interpolation reduction in the vicinity of points.The gambling interval is determined according to the target grayscale character font size, 10 sampling points are determined, and 4 points near the sampling point are This method determines the value of a multivalued character pixel in proportion to the distance between the two pixels. By smoothing the values of a multivalued character font using this linear interpolation, it is possible to achieve a desired reduced size.

However, 2) this method requires a separate density adjustment process because there is bit leakage when the magnification is low, and if left as is, the image will become thinner.

The most appropriate method for this four-point neighborhood linear interpolation reduction process is to reduce the original character font by a factor of 7 and 0.7.

As for the density correction when each image is reduced exactly, it is preferable to perform density correction that emphasizes black using a correction curve in which a broken line is changed to a solid line as shown in the graph of FIG.

[Effects of the Invention] As explained above, the present invention can display grayscale characters of various sizes from binary character fonts on a display device, so when performing DTP, Even when the output mode is blurred or -, easy-to-read characters can be displayed.

Further, since the present invention can utilize a well-known image filtering means, there is no need to specially create a grayscale character font, and therefore grayscale characters can be generated and displayed at low cost.

[Brief explanation of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention; FIG. 2 is a procedural diagram of the first embodiment of the present invention. Figure 3 is a flowchart 1 showing the 3x3 pixel smoothing process.
. FIG. 4 is a diagram showing character size conversion processing. Figure 5 shows an example of grayscale character output. FIG. 6 is a procedure diagram of the first embodiment of the present invention. Figure 7 is a small graph of the density correction curve. FIG. 8 is a configuration diagram of a conventional example. l...Memory, 2...Multi-valued image display device, 3...
Binary image display device, 4... CRT display device, 21...
- Multi-value conversion means, 22... Smoothing means, 23... Size conversion means.

Claims (1)

[Scope of Claims] 1. In a character display device of an information processing device comprising means for reading a character font corresponding to a character code to be output from a storage device and outputting it to a display device, the character font read from the storage device; What is claimed is: 1. A grayscale character display device comprising filter means for smoothing the gray scale character display device. 2. Multi-value converting means for converting the read binary character font into a multi-value font; filter means for smoothing the multi-value font converted by the multi-value converting means; 2. The grayscale character display device according to claim 1, further comprising resampling means for changing the size of the character font. 3. In a character display device of an information processing device that is equipped with means for reading a character font corresponding to a character code to be output from a storage device and outputting it to a display device, the neighborhood point linearity of the binary character font read from the storage device A grayscale character display device comprising means for simultaneously smoothing a character font and converting its size by performing interpolation. 4. The gray scale character display device according to claim 1, wherein smoothing of the character font in the vertical direction is performed more strongly than smoothing in the horizontal direction.