JPS62106495A - Character font smoothing apparatus - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a character phono 1-smoothing device.

[Prior art] With the expansion of computer use, processing of Japanese including kanji has become commonplace, and when a character font based on R(lM) is enlarged and displayed, the roughness of the dot pitch becomes noticeable, making it difficult to smooth the text. There is a strong demand.

Large-scale methods that take into account the origin of the font itself, such as smoothing the generation of character fonts using large computers based on the origins of Japanese characters, are being considered at various locations.

Problems to be Solved by the Invention However, in the past, in line with Okawa, it was possible to use simple text phono sources, such as personal computers, to utilize them to quickly and easily There was no way to smooth it out.

The present invention solves the above-mentioned conventional problems, and utilizes the fonts of 11 Japanese characters, including kanji, which are possessed by so-called personal computers, which are rapidly becoming popular in many industrial fields. Another object of the present invention is to provide a character font smoothing device that can immediately perform double-precision smoothing processing and make it visually practical even during enlarged display.

In order to solve the problem described in "Means for Solving the Problem," the character font smoothing device of the present invention smoothes a character font C (m, n) composed of a lattice array consisting of m rows and n columns. Change any character in C(
i, j), regarding the component dot DOT(i, j) located at row 1, column j, DOT(i
+j, j+]) (j=]-(m-]), j=1-
(n-1)) is true, each matrix has double precision (
Smoothed character DC (2m, 2
n) in the driver 1-element r]DOT(2j, 2j
+ 1) and DDOT(2i+1.2j) are true, and DOTl+1. j-1)l=9-(m-])
.

j=2 to n) is true, the smoothing character 1
dot in 1C(2m, 2n) - element DDOT(
2i, 2(j −1)) and DDOT(2i+1.2
This configuration includes means for determining the value of j-1) to be true.

Operation According to the above configuration, any dot DOT (i
.

Regarding j), while comparing and judging the situation of the dots before and after,
Facilitation can be done in real time. Furthermore, the configuration of the device is extremely cylindrical.

Example Hereinafter, one embodiment of the present invention will be described based on the drawings.

FIG. 1(A) is an explanatory diagram showing font dots for explaining algorithm 11 of the font smoothing device in one embodiment of the present invention, and FIG.
, n), and (C) is a waveform diagram of the readout clock to form the double-precision smoothed font DC (2m, 2n).
), there is a dot D with [1].

Let r(i, j) represent the dot located in the i row and j column of a character font C(m, n) consisting of a grid-like dot configuration of m rows and n columns, and smoothed double precision. 2
F tsuh DDOT(
2i-1.

2j-1), DDOT(2i-1,2j), DDO
T(2i, 2j-1), 1)I)OT(2i, 2
It corresponds to 4 dots 1~ in j). D0T(j,
, i) and DOT (i+1, j+1) in the diagonal direction are both true, that is, the logical product is 1, then if these points are also placed in the font, then both dots 1
Filling the part sandwiched between ~ with 1/2 pits 1 to 1 has a great effect on smoothing out the font. That is,
In double precision fonts, DDOT (2i.

2j + ]), DDOT(2j +1, 2j)
is to make the dots of .

Similarly, DOT(j-+ J) and DOT(i+1,
j-1) is 1, then DDOT(2i, 2
(j-])) and DDOT (2i+1.2j-1) by setting the dots 1 to 1 to smooth the single-precision font.

FIG. 2 is a circuit block diagram of a character font smoothing device for realizing the above method. Here, to simplify the explanation, the original font C(m, n) is expressed as m ” n :1
It is composed of 6 dots 1~, so double precision font DC (2m
, 2n) is smoothed to have a 32×32 dot configuration.

In a simple so-called personal computer, a dictionary of Japanese character fonts is provided by a character generator ROM having a 16 x 16 dot structure, and this ROM is read out by row or column scanning and used for CRT display and other various purposes. In FIG. 2, 1 is a 15-bit shift register, 2 and 3 are 1-bit D-type flip-flops, 4 and 5 are AND circuits, 6 is a 30-bit shift register, 7 is a 3-bit shift register, and 8 is a 28-bit shift register, 9 is a 3-bit shift register,
10 is a doubler, H to 14 are OR circuits, and 15 to 17 are terminals. Serial data DA input to terminal 15
passes through a 15-bit shift register 1 and 1-pill D-type flip-flops 2 and 3. The data 15 bits ago and the current data pass through the AND circuit 4 and become the control signal (a), and the data 17 bits ago and the current data pass through the AND circuit 5 and become the control signal (b). becomes.

On the other hand, the dot read clocks C1 and KI for reading the original font consisting of 16×1.6 dots are input to the terminal 16, and the doubler 10 converts them into clocks CLK2 having twice the frequency. Also, serial data 1) Δ is 30
Bits, 3 bits, and 28 bits 1 to 28 bits are added to the 3-bit shift registers 6.7 and 8.9, and these shift registers 6.7 and 8.9 (3 to 9 are clocks C1, K2
The output of the shift register 6 corresponding to the 30th bit l-1-1 and the shift register 6 corresponding to the 61st bit
A control signal (a) is inserted into the output of the register 8 by the OR circuits II and 12, and a bit for double precision smoothing is set. Similarly, the control signal (b) is inserted by the OR circuit 1.3.14 into the output of the shift register 7 corresponding to the 33rd bit and the output of the shift register 9 corresponding to the 64th bit. Set up smooth pitch 1 for precision phono 1.

As described above, according to this embodiment, regarding the dot DOT (i, j) of the character C (m, n) assigned to the phono 1 in the original 16 x 16 dot configuration, the situation of the previous and subsequent dots is compared and determined. However, facilitation can be performed in real time. Also, the configuration of the device can be extremely simple.

Figure 3 shows the result of smoothing an actual 16x16 dot character using the above character font smoothing device. A small square with diagonal lines indicates the content of double-precision correction. Therefore, the final completed font is a figure shown by both dots by calculating the logical sum of these, and the smoothing effect can be visually confirmed.

Effects of the Invention As described above, according to the present invention, for any dot DOT (i, + j) of the character C (m, n) in the original mXnXn driver configuration font, the situation of the previous and subsequent drivers 1- can be determined. Smoothing can be done in real time while making comparative decisions. Also, the configuration of the device can be extremely simple.

[Brief explanation of drawings]

FIG. 1(A) is an explanatory diagram showing the font driver I to explain the algorithm of the character font smoothing device in one embodiment of the present invention, and FIG. 1(B) is an explanatory diagram showing the original font C(
(C) is a waveform diagram of the read clock to form a double-precision smoothed font DC (2m, 2n).
FIG. 2 is a circuit block diagram of a character font smoothing device according to an embodiment of the present invention, and FIG. 3 is a diagram of the character font smoothing device according to an embodiment of the present invention. It is a diagram. ■, 6-9・Shift register, 2, 3...D-type flip-flop, 4, 5...AND circuit, 1o...2 multiplier circuit, 11-14...OR circuit agent Morimoto Yoshihiro Figure 1 (column) ``' Left hand corner 1 copy l' 1st edition 2-106495 (4) Figure 3

Claims (1)

[Claims] 1, any character in the character font C(m, n) composed of a grid array consisting of m rows and n columns as C(i, j)
Then, regarding the component dot DOT (i, j) located in the i row and the j column, DOT (i+j, j+1
) (i=1~(m-1), j=1~(n-1)) is true, the smoothing character DC(2m , 2n), the dot elements DDOT(2i, 2j+1) and DDOT(2i+1
, 2j) is true, and DOT(i+1, j-1)
When the logical product with (i=9~(m-1), j=2~n) is true, the dot element DDOT(2i, 2(j-1)) in the smoothed character DC(2m, 2n) and DDOT(
2i+1, 2j-1) is true.