JPS62195979A - Facsimile code converter - Google Patents

Abstract

PURPOSE:To perform the processing of a decoder or an encoder at high speed and to simplify the enlargement and the reduction at high speed by decoding encoding data to the change point address from a white picture element to a black picture element and from the black picture element to the white picture element, applying the operation to this change point address data and encoding the enlarged and reduced change point address. CONSTITUTION:The change point address data is decoded by the change point address decoder 1 and stored in a change point address memory 2. The change point address data from the change point address memory 2 is initially inputted to the scanning line enlarging and reducing circuit 6 of an enlargement and reduction device 3. A change point address arithmetic circuit 7 multiples the change point address data inputted from the scanning line enlarging and reducing circuit 6 by the coefficient data of the multiplying factor for the enlargement and the reduction or the like outputted from a coefficient device 9 by a multiplier 8 and the multiplied result is half adjusted to an integer by a half adjust circuit 10. Finally, the enlarged or reduced change point address data is encoded according to a designated facsimile encoding system by the change point address encoder 4.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention provides pixel density conversion, pixel density conversion, The present invention relates to a facsimile code conversion device that converts facsimile coded data, such as paper size conversion or encoding method conversion.

[Conventional technology]

A conventional facsimile code conversion device of this type is, for example,
As shown in the figure, a decoder 11 that restores input encoded data to pixel data, an image memory 12 that stores the restored pixel data, an enlarger/reducer 13 that enlarges or reduces the stored pixel data, and an enlarger 13 that enlarges or reduces the stored pixel data. Alternatively, it is composed of an encoder 14 that encodes the reduced pixel data, and a controller 15 that controls each of the above functional blocks. SPC method (method for selecting one close to the output scanning line from among multiple input scanning lines) shown in ``A method of facsimile linear density conversion'' in Proceedings Na 10 - 5ele
active processing conversi
FIG. 10 shows an example of this circuit. In the figure, the enlarger/reducer 13 is connected to a scanning line enlarger/reducer circuit 16 that thins out or inserts scanning lines, and a scanning line enlarger/reducer circuit 16 that thins out or inserts scanning lines. It is composed of a pixel enlargement/reduction circuit 17 that performs thinning or insertion.

For example, when the screen is to be reduced by 3/4 times vertically and horizontally, the scanning line enlarging/reducing circuit 16 thins out the scanning line once every four lines as shown in FIG.
The reduction circuit 17 is connected to the image memory 1 as shown in FIG.
As shown in FIG. 12, the pixel data stored in No. 2 is thinned out by one pixel every four pixels.

[Problem that the invention seeks to solve]

The enlarger/reducer 13 in the conventional facsimile code converter is constructed as described above.

It is difficult to enlarge or reduce the screen, especially in the scanning line direction. That is, image memory 1
2 is usually a byte (8 octets) or a word (16
Because it is configured so that reading and writing can be performed in units of octets, it is possible to thin out specific bits from the read word data and reconstruct new word data as shown in Figure 3. It takes a lot of time. Moreover, if this processing is performed by software, there is a problem that the processing speed is slow, and if it is performed by dedicated hardware, it is possible to use an arbitrary enlargement/reduction ratio (m/n times, where m and n are natural numbers). ) requires large-scale hardware.

As described above, the conventional facsimile code conversion device d has problems with processing speed, device scale, and scaling ratio limitations when enlarging/reducing, as well as the problem of storing one page's worth of pixel data in the image memory 12. However, there was a problem in that a large memory capacity was required.

This invention was made to solve the above-mentioned problems, and allows conversion processing of facsimile encoded data to be performed at high speed with a relatively small scale device.
It is an object of the present invention to obtain a facsimile code conversion device capable of enlarging and reducing at an arbitrary magnification.

[Means for solving problems]

The facsimile code conversion device according to the present invention has a function of decoding a change point address from a white pixel to a black pixel and a change point address from a black pixel to a white pixel from input facsimile encoded data, and a function of decoding the change point address from a white pixel to a black pixel and a change point address from a black pixel to a white pixel. It is equipped with a memory function for storing information, a function to perform calculations on the change point address stored in the memory function to enlarge or reduce it, and a function to perform facsimile encoding from the expanded or reduced change point address. be.

[Effect]

The facsimile code conversion device of the present invention decodes the change point address data from white pixel to black pixel and the change point address data from black pixel to white pixel at an intermediate stage of restoring encoded data to pixel data, and After performing arithmetic operations on address data, the enlarged/reduced change point address is encoded.

〔Example〕

Hereinafter, one embodiment of the present invention will be described based on the drawings. In Figure 1, 1 is a change point address decoder that decodes input encoded data into a change point address, 2 is a change point address memory that stores the decoded change point address, and 3 is stored in the change point address memory 2. 4 is a change point address encoder that encodes the expanded or reduced change point address, and these change point address decoders 1
, change point address memory 2, enlarger/reducer 3 and change point address encoder 4 are controlled by 5.

As shown in FIG. 2, the enlarger/reducer 3 has a scanning line enlarging/reducing circuit 6 for thinning out or inserting scanning lines, and a change point address calculation circuit 7 for enlarging or reducing the scanning line direction. It is composed of

Next, in explaining the operation, first, the encoding method of the image processing section, which is one of the main components of the facsimile terminal, will be explained. The facsimile encoding method is one-dimensional encoding method (MH method/Modified) 1uffman c
ode) and two-dimensional coding method (MR method/Mod-ifie
d RIEAD code). Among these, the MH code is an encoding method that encodes the number of consecutive pixels of the same color on a scanning line (this is called a run length). For example, in the case of pixel data as shown in FIG. 3, it is encoded in the order of white run length 4, black run length 3, white run length 4, black run length 1, and so on. Therefore, when the MH code is decoded, the run length can first be restored. It is easy to calculate the change point address from the restored run length. In the case of FIG. 3, the change point address 4 is first obtained from the white run length 4, and then the next change point address 7 is obtained by adding the decoded black run length 3. Change point addresses 11 and 12 can be easily obtained by a similar procedure.

On the other hand, in the case of MR code, in principle, the change point address of the line to be encoded and the line directly above it (referred to as the reference line)
encodes the relative difference between change point addresses. For example, in the case of pixel data as shown in Figure 4, first the difference between the first change point address of the encoded line and the first change point address of the reference line is encoded, but the two change point addresses are the same. 4, the difference O will be encoded after all. The next change point address of the encoded line is 8, and the next change point address of the reference line is 7, so the difference +1
is encoded. Thereafter, differences -2 and -3 are sequentially encoded in the same manner.

Therefore, it can be seen that even in the case of the MR code, the change point address can be easily obtained by sequentially decoding the differences. The change point address decoder 1 decodes the change point address data and stores it in the change point address memory 2. Figure 5 is a diagram showing the state in which the change point addresses of the pixel data in Figure 3 are stored in memory. Each change point address is expressed as a 16-bit binary number, and up to 65535 change point addresses Since the number of pixels in a scanning line of a typical facsimile machine is several thousand at most, 16 bits is sufficient. Now, the stored change point address is enlarged or reduced by the enlarger/reducer 3. That is, the change point address data from the change point address memory 2 is first enlarged by the scanning line of the enlarger/reducer 3. The signal is input to the reduction circuit 6. As shown in FIG. 6, when reducing the change point address by 3/4 times, one scanning line is thinned out every four lines.

By the way, in the case of change point address data, since the amount of data in one line is variable, it is necessary to know the break in data of each line. Therefore, line breaks are recognized by writing a unique data word (for example, 16 bits 111...1') at the end of the change point address data of each line. .

Further, the changing point address calculation circuit 7 shown in FIG. The multiplication result is rounded off to an integer by a rounding circuit 16. Now, for example, if you want to reduce the pixel data in Figure 4 by 374 times, if you set the magnification of the coefficient 9 to 3/4 and perform the calculation, the 7th
The reduced data shown in the figure will be obtained.

In this case, when the conventional facsimile code conversion device reduces the pixel data by 3/4 as shown in FIG. 3, the thin line disappears as shown in FIG.
In the facsimile code conversion apparatus of this embodiment, thin lines are preserved as shown in FIG.

Finally, the expanded or reduced change point address data is encoded by the change point address encoder 4 using a designated facsimile encoding method.

In the above embodiment, the case where the magnification is 3/4 is used for reduction, but it is of course possible to perform enlargement and reduction at any other magnification.

〔Effect of the invention〕

As described above, according to the present invention, encoded data is decoded into change point addresses from white pixels to black pixels and from black pixels to white pixels, and operations are performed on this change point address data to enlarge or reduce the data. Since the encoded data is not restored to pixel data as in the conventional method, processing of the decoder and encoder can be made faster, and expansion and reduction can be done using simple multiplication. This can be done at high speed using a circuit, and since the change point address requires less data than the pixel data, the memory capacity required to store one page is also small, further expanding the pixel data. When scaling down, a value of 0 or more can be entered in the coefficient, so the scaling ratio in the scanning line direction is freed from the constraints of discrete numerical values such as m/n times, and it is possible to obtain any scaling ratio. In conventional facsimile code conversion devices, thin lines disappear due to thinning and sampling of pixel data, but in the case of the present invention, vertical thin lines do not disappear in principle, and there are various effects. There is.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing a facsimile code conversion device according to an embodiment of the present invention, FIG. 2 is a block diagram showing the configuration of the enlarger/reducer shown in FIG. 1, and FIG. 3 is a configuration showing an example of pixel data. 4 is a configuration diagram showing an example of pixel data for explaining the binary encoding method, and FIG. 5 is a configuration diagram showing an example of pixel data for explaining the binary encoding method. FIG. 6 is a diagram showing an example of scanning line thinning by the apparatus of this embodiment. FIG. 7 is a diagram explaining the configuration and operation of the change point address calculation circuit in FIG. 2. FIG. 8 is a diagram showing the case where the pixel data shown in FIG. 3 is reduced by 3/4 times using the apparatus of this embodiment.
FIG. 9 is a block diagram showing a conventional facsimile code conversion device, FIG. 10 is a block diagram showing the enlarger/reducer shown in FIG. 9, and FIG. FIG. 12 is a diagram showing an example of scan line thinning using a conventional device. FIG. 13 is a diagram showing a case where the pixel data shown in FIG. 3 is reduced to 3/4 times by a conventional device. . In the figure, 1 is a change point address decoder, 2 is a change point address memory, 4 is a change point address encoder, and 6 is a scanning line expansion/controller.
The reduction circuit 7 is a change point address calculation circuit. In the drawings, the same or corresponding parts are designated by the same reference numerals. Patent applicant Mitsubishi Electric Corporation Figure 6 Y-283/1/1-2 Procedural amendment (voluntary)

Claims (1)

[Claims] In a facsimile code conversion device that converts the pixel density, paper size, or encoding method of facsimile coded data according to instructions from an external device, the input facsimile coded data is converted to a change point address from a white pixel to a black pixel, and Scanning line expansion in which the change point address from a black pixel to a white pixel is decoded by a decoder, the decoded change point address is stored in memory, and the stored change point address is thinned out or inserted into a scan line.・Supplied to the reduction circuit, the change point address data from the scanning line enlargement/reduction circuit is operated by the change point address arithmetic circuit to be enlarged or reduced, and facsimile encoding is performed from this enlarged or reduced change point address. A facsimile code conversion device characterized in that the facsimile code conversion is performed by a converter.