JP2791315B2 - Color image processing apparatus and method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a color image processing apparatus and method capable of processing a color image.

[0002]

2. Description of the Related Art Conventionally, there has been known a technique of compressing image data as a color image or a monochrome image and storing the image data in a memory or the like.

[0003]

However, conventionally, when there is a possibility that compressed data of an image may be used as a color image or a monochrome image, the color compressed data obtained by compressing an image as a color image and the same image as a monochrome image may be used. It is conceivable that monochrome compressed data compressed as an image is simultaneously stored in a memory, and color compressed data or monochrome compressed data is expanded and used according to a predetermined instruction.

[0004] However, the above data storage method has a problem that the memory capacity required for storage increases.

On the other hand, at the time of storing the compressed data of an image, it is determined in advance whether to use the compressed data representing the image as a color image or a monochrome image, and the color compressed data for each image is determined. Alternatively, a method of storing only one of the monochrome compressed data is also conceivable.

[0006] However, this storage method has a problem that it becomes impossible to use either color compressed data or monochrome compressed data.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and efficiently stores compressed data obtained by compressing an image in a memory, as well as color compressed data representing a color image and monochrome compressed data representing a monochrome image. It is intended that both can be used.

[0008]

According to the present invention, there is provided a color image processing apparatus for generating color image data, comprising: means for temporarily compressing all of the color image data as a color image; Storage means for storing the obtained color compressed data, and transmission for expanding the color compressed data stored in the storage means in accordance with a predetermined instruction, compressing it as a monochrome image, and transmitting the obtained monochrome compressed data. Means.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION

(First Embodiment) FIG. 1 is a diagram showing an example of a basic color separation apparatus in a color facsimile transmitting station. In this figure, 1 is a colored document, 2 is a light source, 3a, 3
b is a half mirror, 4a, 4b, 4c are lenses, 5a,
Reference numerals 5b and 5c denote red (R), green (G), and blue (B) filters, respectively, and reference numeral 12 denotes a color separation photoelectric conversion unit.

The original 1 is illuminated by the light emitted from the light source 2, and the reflected light is first partially branched in the direction of arrow a by the first half mirror 3a. The light passes through the red filter 5a to become red component light, is photoelectrically converted by the red sensor 6a, and is output to the terminal 7a as a red corresponding electric signal. Further, a part of the light transmitted through the half mirror 3a in the direction indicated by the arrow D is partially branched in the direction indicated by the arrow B by the second half mirror 3b, and passes through the green filter 5b to become green component light. The light is photoelectrically converted by the sensor 6b and output to the terminal 7b as an electric signal corresponding to green. The light that has passed through the second half mirror 3b and traveled in the direction indicated by the arrow C passes through the blue filter 5c, resulting in only blue component light, is photoelectrically converted by the blue sensor 6c, and is supplied to the terminal 7c as a blue-compatible electric signal. Is output.

Since all the color signal components obtained by the color separation in this way are analog quantities, for example, they are respectively passed through dedicated amplifiers 8a, 8b, 8c and then dedicated A / Ds. The signals are input to converters 9a, 9b, and 9c, and are digitized. Here it is shown the digitized signal V _R, V _G, as V _B.

These signals V _R , V _G , V _B are inputted to the color signal transmission control device 10 and, for example, as shown in FIG. For example, from the signal of the partial image at the left end of the row to the signal in the right direction,
The first bit, as shown as RGB, RGB,.
The second bit, the third bit,... Are formed into a time-series signal in order and transmitted to the line 11.

However, since the facsimile station apparatus which is already widely used at present is of the monochrome type, the partner station does not have a color reproduction function even if the color separation is performed in the above-described example. If the station is a monochrome station, there is a drawback that the image cannot be normally reproduced because the color discrimination ability is not provided, and the transmission and reception of the image becomes impossible as described above. However, it is not impossible to synthesize a facsimile signal and perform color reproduction itself. The signal transmission control device 10 of the transmission system shown in FIG. 1 is replaced with a signal reception control device, and the transmission path of each color signal is reversed. It is easy to perform the color signal synthesis by using the color signals. However, an obstacle is that most of the currently popular facsimile stations are of the monochrome type, which causes the above-mentioned inconvenience.

FIG. 3 is a block diagram of the image communication apparatus according to the present embodiment.

First, the overall flow of a color facsimile will be described with reference to the drawings.

At the time of transmission, an original is optically separated by a scanner unit 301 and converted into an electric signal by a photoelectric conversion element such as a CCD, and analog / digital converted by an A / D converter. The digitized three-color reflected original signal passes through a shading circuit for correcting variations in light sources, photoelectric conversion elements, etc., and enters an input color correction circuit for adjusting to, for example, NTSC spectral characteristics, using a 3 × 3 matrix or the like. Color corrected. Up to this point, each color signal is multi-valued data (for example, 24-bit data of 8 bits per color), but since the transmission path is currently narrow, the transmission time is too long, so that the resolution is set to 400 dpi and the binary data is transmitted. It is practical. Therefore, the image data is 2
It is assumed that the value is output from the scanner 301 as a value. Therefore, at the exit of the scanner 301, N
1 bit for each RGB of TSC signal, total 3 bits for 3 colors /
It is assumed to be output as a pixel.

Output data from the scanner 301 enters a buffer memory 311 in the controller 306.
Is a part for storing data for several lines. A circuit 312 determines whether the original is a black-and-white original or a color original.
Based on the result of automatic discrimination between a black-and-white document and a color document or manually set by a color / black-and-white switch button on the operation panel 303, switching between flowing the document color separation data to the color compression 313 and the black-and-white compression 315 is performed. The color / monochrome discriminating unit 312 includes a decision circuit 2 as shown in FIG.
01 and a selector 20 for selecting the data from the BVF 311 from the color / monochrome conversion unit 314 (A side) or the color compression unit 313 (B side) based on the determination result.
2. Operation unit 20 for manually setting color / black and white
3. When the output of the color / monochrome determination circuit 201 is 0 (monochrome), the selector 202 sets the A side to 2
When the output of 01 is 1 (color), the B side is selected.
When manual setting is performed, the determination circuit 201
Manual setting from the operation unit 203 in preference to determine is made, regardless of the value of S ₀ of the selector, the operation unit 20
When the setting from 3 is S ₁ = 0 (black and white), the A side has S ₁ =
In the case of 1 (color), the B side is selected.

Reference numeral 314 denotes a circuit for converting data determined as a monochrome original in the automatic / manual color / black / white determination in 312 from a three-color color signal to a monochrome signal.

The color compression section 313 compresses image data containing color information using a compression algorithm such as block coding or vector quantization. Also,
In the black-and-white compression unit 315, data compression is performed by a compression algorithm such as MH and MR, which is used in a normal black-and-white facsimile apparatus.

At this time, if the data is manually or automatically converted to black and white data, even if the other party is G3 or G4, the data can be transmitted if the standard compression of G3 and G4 is performed by the black and white compression unit 315. G4 is a digital line for ISDN and G3 is an analog line using a telephone line, so a modem is required.

Similarly, the black and white data sent from G4 and G3 is stored in a hard disk
Decoded via 17. In this case, since the data is only black, the ink jet printer 3 for simultaneously recording four colors is used.
In the case of 02, yellow (Y), magenta (M),
Do not print cyan (C) data 0, Y = M = C = 0
And sends it to the buffer memory 323. Black K is K = 1
Calculated as -Ye. Ye will be described later. As a result, the same treatment as in color recording can be performed.

When the transmitted data is color data, the data is transmitted from the hard disk 316 to the NT through the color decoder 319.
Color correction and black generation are performed at 320 corresponding to the color material of the printer 302 from the SC signal. Since the output from the color correction unit 320 is multi-valued, the density preserving type binarization circuit 32 is used.
According to 1, 4-bit / pixel data of four colors enters the output buffer memory BUF323.

The data from the BUF 323 is output at 4 bits / pixel for both monochrome data and color data. Reference numeral 302 denotes a color printer unit which arranges four heads of four colors of Y, M, C, and K by using, for example, ink jet recording, and simultaneously performs recording. Therefore, YMCK 4 bit / pixel data 3 from the controller 306
08 prints four colors by buffering the registration part of the head. Y = M for black and white
= C = 0 and printing is performed according to 0 or 1 of K.

The outline of the color facsimile of the present embodiment has been described above, and the black-and-white automatic discriminating means at the center of the present embodiment and a method of generating a black-and-white image signal from a color image signal will be described.

FIG. 6 shows an example of a color / black / white original automatic discrimination circuit. 401 is the binarized NTSC R
It is assumed that a GB 3 bit / pixel signal comes. The data values at a certain point (i, j) are r, g, and b. 402
Is a multi-level conversion unit, and when multi-level conversion is performed using, for example, 2n + 1, 2m + 1 pixels, Equation (1) is obtained.

[0026]

[Outside 1] Since the input signal of 401 is a binary signal of 0 or 1, it is difficult to calculate the color of each pixel, and there is no need to determine black and white / color for each pixel. What is needed is the color within a certain average area. If n and m are too large, an erroneous determination is made in a thin line portion with a color character such as a color character, so a value of n = m = 1 to 10 is appropriate. (1)
The multi-valued data is converted into R, G, B of NTS and XYZ of CIE in (2), and the lightness L and colors a, b are calculated by (3) using the result of (2). I do.

[0027]

[Outside 2]

The color component is given by (4).

[0029]

[Outside 3]

In FIG. 6, reference numeral 402 denotes the calculation of (1) as 40
Reference numeral 3 denotes a circuit for performing the calculation of (2), 404 denotes a circuit for performing the calculation of (3), and 405 denotes a circuit for performing the calculation of (4). Reference numeral 406 denotes a circuit for determining an achromatic color range, which is an achromatic color when l ≦ a (0 <a <255), that is,
When it is determined that the document is a monochrome document, the threshold th of 406 is a
Becomes Reference numeral 407 denotes an integrator which counts the amount of the color of each pixel that satisfies th> a. If the number of pixels is equal to or greater than a predetermined number, the color is determined. The reason why the predetermined number of pixels is used as a reference here is to prevent erroneous determination due to a reading error of the scanner 301 or the like.

In this manner, whether the original is color or black and white is determined for each page of the original. Therefore, at the time of automatic discrimination, the color original is once judged to be read, and only one page is read and the judgment circuit 312 judges the data. While the data is stored in the hard disk 316 in a color-compressed form through color compression, the count number of the integrator 407 is small at the end of one page, and the data stored on the disk is recognized by the color decompression unit 319 when it is determined that the document is a black and white original. The data is input to the color / monochrome discriminating unit 312 through. At this time, since the data flowing from now on is known to be black and white, the color and black and white conversion unit 314
Then, the color data is converted to black and white, and the data is again written to the hard disk 316 through the 315 black and white compression unit. The previously input color data is deleted after the feedback data is converted to black and white. Thus, data is stored in the hard disk 316 with a minimum capacity.

FIG. 7 is a diagram for explaining a method of obtaining monochrome binary data from color binary data. For example, (R1, G
1, B1) is used to create black-and-white data. Here, RGB is binary data output from the scanner 301. When this image is manually set to the black and white original mode from the operation panel 203 or is set to the black and white original by the color / black and white automatic discrimination unit 312, a black and white signal is generated by the equation (5).

Y _l = 0.299R + 0.587G + 0.114B (5)

Since RGB is binary data, it is 0 or 1, but it is converted into 0 → 0, 1 → 255 and equation (5) is calculated. Y
_{If l} ≧ 128, the black and white binarized data K is K = 0 (no dots are printed), and if _Yl <128, K = 1 (dots are printed).

Equation (5) is an equation in the case where the input is a signal obtained by color separation using an NTSC signal. When other signals are input, the coefficient changes. can get.

As described above, according to the present embodiment, by setting the black and white / color of a document manually or automatically, a compression method for a black and white image is used for a black and white document, and a compression method for a black and white image is used for a color document. By using a compression method for a color image, the compression efficiency can be greatly improved in the case of a black and white original.

Further, the provision of the color / monochrome converter 314 makes it possible to use a black-and-white compression algorithm even when chromatic pixels exist in a part of the document. This also enables communication with existing black and white facsimile machines such as G3 and G4.

The color / monochrome discriminating unit 312 can perform manual discrimination in addition to automatic discrimination. Therefore, when a color original is to be transmitted / received in a short time or when it is not necessary to send it in color, It can be transmitted and received using a compression algorithm for black and white.

(Second Embodiment) The basic configuration of the second embodiment is the same as that shown in FIG.

In this embodiment, the R, G, and NTSC of the NTSC used for color / monochrome discrimination in the first embodiment.
The conversion from the B signal to the L, a, b signal is replaced by the conversion to the HLS signal.

That is, the difference from the first embodiment is that an HLS converter 408 as shown in FIG. 8 is provided instead of the circuits 403 and 404 for conversion into L, a, and b in FIG.

Here, the equations for converting the R, G, B signals into H, L, S signals are as shown in FIG. The color component is given by equation (6).

[0043]

[Outside 4] The method of determining the achromatic color range from l is the same as in the first embodiment.

The conversion from the R, G, B signals is not limited to the L, a, b signals, H, L, S signals, but may be L, u, v.
The same determination can be made by using parameters separated into a brightness signal and a tint signal that can determine chromaticity / achromaticity for each pixel such as a signal. Also, even if the parameter conversion is not performed, for example, Max (R, G, B) -Min
Color / black and white can also be determined by the distribution of chromatic and achromatic colors in the (R, G, B) space.

(Third Embodiment) FIG. 10 shows an example of the use of a color facsimile having a color / monochrome automatic discrimination means of the first embodiment. 601 is ISD
N (digital communication network), 602 is a PSTN (public telephone line), and 604 is a color facsimile having a color / monochrome automatic discrimination means used by C company 603. In Company A 605, it is assumed that a color fax (CFAX) 606 is connected to ISDN through Fline, and a G4 black-and-white fax 607 is also connected to ISDN through Eline. In Company B 608, it is assumed that a color FAX 609 is connected to ISCN through Cline, and a G3 monochrome FAX 610 is connected to PSTN through Dline.

Now, when a color and black and white mixed original is sent from Company C 603 to Company A 605, the CAFAX 604 can automatically discriminate the color and black and white or send it to Eline's color fax via ISDN via ADN when color is selected by the manual means 312. In the case of a black-and-white original, the mode is automatically switched to 607 G4 black-and-white FAX, and high-speed, high-quality black-and-white image data can be transmitted. In the same way, the color / black and white of the company B can be identified and transmitted to separate faxes.

The CAFAX (60
4, 606, 609) are the image communication devices described in the first embodiment. A company's CAFAX 606
Eline, Flin connected to G4FAX607
e, Cline and Dline connected to Company B's CFAX 609 and G3 FAX 610 are color FAXes by address, respectively, and are registered as black and white FAXes, and can be selected by CA CAX 604 of Company C on the transmission side.

Then, if the original is a color image and the discrimination unit 312
If it is determined in the above, CFAX606 or CFAX60
9 and if it is determined that the image is a black and white image, G4
It is transmitted to FAX 607 or G3 FAX 610.

If the receiving company A or B has only a color facsimile, the image is transmitted to a color facsimile. By compressing and transmitting the original document, the color of many originals can be transmitted to a color facsimile, and the black and white original can be transmitted to a facsimile dedicated to black and white. This has a great effect on communication speed, image, cost and the like.

In the case of an ISDN line or the like, a plurality of sub-addresses can be specified for one line, and black and white and color FAX may be set to the sub-addresses.
In this case, according to the present embodiment, a black-and-white signal is automatically generated if there is a black-and-white document in a color document so that communication with G4 and G3 machines is possible due to the current widespread use of color facsimile. Compress, increase compression efficiency,
Furthermore, by recording with a single color of black ink at the time of reception, the tightness of a thin line portion such as a character portion can be improved compared to black recording in which three colors are superimposed, and higher image quality can be achieved when transmitting a black and white original.
For this purpose, a color / monochrome original automatic discriminating means is provided, and a monochrome setting switch is further provided on the operation panel. By setting the monochrome mode, a luminance signal is obtained from three-color data and is binarized. As a result, black-and-white data can be obtained, and communication with conventional faxes other than color facsimile can be realized.

(Fourth Embodiment) The basic configuration of an image processing apparatus according to a fourth embodiment is the same as that of the first embodiment, but the method of discriminating color / black and white is different in this embodiment. .

That is, in the first embodiment, color / black and white discrimination is performed for each page of a document. However, using such a discrimination method, a color page and a black and white page are mixed in a multi-page document. In this case, when a color printer and a black-and-white printer on the receiving side are selected and transmitted by automatic (or manual) discrimination as in the third embodiment, one document is distributed to a plurality of printers. Inconvenience arises when a monochrome printer and a color printer are installed separately. Therefore, in this embodiment, color / color
This problem is solved by performing the black / white determination.

The configuration of the present embodiment will be described with reference to FIG.

In FIG. 3, a color / monochrome discriminating unit 312 is shown.
Determines the color / black and white of the document for each page as in the third embodiment. The page determined to be color is compressed by the color image compression algorithm in the color compression section 313 and stored in the hard disk 316. On the other hand, the page determined to be black and white passes through a color / black and white conversion unit 314, is subjected to a black and white image compression algorithm in a black and white compression unit 315, and is stored in the hard disk 316.

Here, in this embodiment, as shown in FIG. 5, a counter 204 for counting the output 1 (that is, the page determined to be color) of the output signal of the color / monochrome determination circuit 201 is provided, and a plurality of pages are determined. When the counter value is 0 at the time of performing the above, all the originals are transmitted to the color facsimile (CFAX 606 and CFAX 609 in FIG. 10) to perform color output. According to the present embodiment, when a document is composed of a plurality of pages, color / black and white determination is performed for each document, not for each page. Therefore, documents in which both black and white and color are mixed are transmitted to one receiver at a time. Can be. Also, at that time, since the compression of the monochrome page is performed on the monochrome page, the communication time and the cost can be reduced.

(Fifth Embodiment) In the third embodiment, the type of facsimile on the receiving side is registered as an address on the transmitting side in advance, and the color / color of the original is registered.
Although the transmission destination is selected according to black and white, the type of the facsimile on the receiving side may be confirmed by the procedure before the start of communication as in the present embodiment, and the facsimile of the transmission destination may be selected accordingly.

This embodiment will be described with reference to the flowchart of FIG.

First, an original of one page is read by the color separation device 12 (S1), and then, the color / black and white of the original is determined by the color / black and white determination unit 312 (S2). If it is determined that the document is a color document, color image compression is performed by the color compression unit 313 (S3). If it is determined that the document is a monochrome document, the monochrome image compression is performed by the monochrome compression unit 315 (S4).
Is performed. The compressed data is stored in the hard disk 316 in any case.

If the document covers a plurality of pages, this process is repeated for all the pages (S5), and when the processing is completed, the process proceeds to the protocol with the receiving side (S6).

If the original is all black and white (S7) and there is a black-and-white FAX with the receiving side (S8), the document is transmitted to a black-and-white FAX (for example, G4 FAX 605 or G3 FAX 61 in FIG. 10) (S9). Although the originals are all black and white (S7),
If the receiving side is only a color FAX (S8), the monochrome image data is transmitted to the color FAX (S10). At this time, since the color FAX on the receiving side has both the color decompression unit 319 and the black-and-white decompression unit 317 as shown in FIG. 3, even when compressed black-and-white image data is received, a black-and-white image can be reproduced.

On the other hand, at least one page in the original is determined to be color (S7), and the receiving side receives a color fax (for example, FIG. 1).
0 CFAXs 606 and 609) (S1
1) Transmit to a color fax (S12). If there is no color fax, a portion of the image data stored in the hard disk 316 that has undergone color image compression is expanded by a color expansion unit 319, and the color is expanded. Black and white conversion unit 31
4, after converting the image data into black and white image data,
In step 5, the monochrome image is compressed and stored in the hard disk 316 again. In this way, the color portion is changed to black-and-white compression (S13) and transmitted to a black-and-white FAX (S14).

According to the present embodiment, after the transmitting side determines whether the original is black and white or color, the receiving side apparatus determines whether the color apparatus is monochrome or black and white according to the protocol, and performs transmission. Even if it is not known in advance, an appropriate selection can be made.

Further, since both the color / black and white of the original and the color / black and white of the receiving apparatus are taken into consideration, the efficiency is further improved as compared with the case where the control is performed based on only one of the determinations. Can be.

In the above embodiment, the input signals are R, G, and B signals. However, the input signals are other color component signals such as Y (yellow), M (magenta), and C (cyan). May be combined.

The input signal is not limited to a signal obtained by directly reading a document image, but may be, for example, a computer output or a file system output using a magnetic disk.

In the above-described embodiment, a BJ (valve jet) printer is used as a printer, but any printer capable of forming a color image such as a color dot printer, a color ink jet printer, a color laser beam printer, and a color printer can be used. .

Although the description has been given of the case of binary data, the principle is the same for transmission and reception of multi-valued data. When transmitting and receiving multi-value data, the multi-value conversion circuit 402 in the binarization unit color / black and white discrimination unit 312 in the scanner 301 becomes unnecessary.

The determination of color / black and white need not be made on a page-by-page basis. That is, the determination may be made for a fixed number of pages or more, or may be made for every half page. In the latter case, the color portion and the black and white portion in one page can be separated as the unit of determination becomes smaller, and a compression method suitable for each can be taken.

[0069]

As described above, according to the present invention, compressed data of an image can be efficiently stored in a memory, and both color compressed data representing a color image and monochrome compressed data representing a monochrome image can be used. can do.

[Brief description of the drawings]

FIG. 1 illustrates an example of a basic color separation device according to a first embodiment of the present invention.

FIG. 2 is a diagram showing time-series signals of R, G, and B;

FIG. 3 is a block diagram illustrating a basic configuration of a color image processing apparatus according to the present invention.

FIG. 4 is a detailed view of a color / monochrome discriminating unit 312 in FIG.

FIG. 5 is a detailed view of a color / monochrome discriminating unit 312 in FIG.

FIG. 6 is a block diagram showing a color / monochrome original automatic discrimination circuit.

FIG. 7 is a diagram showing creation of monochrome binary data from color binary data;

FIG. 8 is a block diagram showing another example of a color / monochrome original automatic discrimination circuit.

FIG. 9 is a diagram showing a conversion formula from R, G, B signals to L, S, H signals.

FIG. 10 is a diagram showing a network using the color image processing apparatus of the present invention.

FIG. 11 is a flowchart when communication is performed using the color image processing apparatus of the present invention.

[Explanation of symbols]

 312 color / black and white discrimination section 313 color compression section 315 black and white compression section

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI H04N 1/60 H04N 1/40 D

Claims (4)

(57) [Claims] A generating means for generating color image data; a storing means for temporarily compressing all of the color image data as a color image and storing the obtained color compressed data; A transmission means for expanding the compressed color data stored in the means, compressing the compressed color data as a monochrome image, and transmitting the obtained monochrome compressed data. 2. The color image processing apparatus according to claim 1, wherein the expansion of the color image data and the compression as a monochrome image are performed when the transmission destination device is a monochrome image processing device. apparatus. 3. The color image processing apparatus according to claim 1, wherein the monochrome compressed data is stored again in the storage unit. 4. A step of generating color image data, a step of temporarily compressing the color image data as a color image, and storing the obtained color compressed data, and a step of storing the stored color compressed data in accordance with a predetermined instruction. Transmitting the obtained monochrome compressed data by decompressing the color compressed data and compressing it as a monochrome image.