Patent Grant
8031374
The present invention relates to a thermal recording apparatus or the like which reduces effects of heat accumulated in a thermal head and prints highly fine hairline images and circular hairlines by a low resolution.
A thermal printer is an apparatus which heats the back of an ink ribbon superimposed on a recording paper by means of a thermal head in order to thermally transfer the ink of the ink ribbon onto the recording paper, to thereby print an image on the paper. The ink ribbon is a thermal transfer sheet including a layer of thermally meltable color ink, and the recording paper is an image-receiving sheet such as a sheet of paper or a plastic sheet.
The thermal head is a composed of a plurality of heat-generating resistors formed on a substrate in a row. The thermal printer includes a plurality of ink ribbons corresponding to a plurality of colors. The inks of the ink ribbons of the plurality of colors are transferred in a superimposed state onto the recording paper at the same position, to thereby perform color printing. For example, the ink ribbons are disposed to be rotatable, and an ink ribbon to undergo thermal transfer is moved to the position of the thermal head. Further, a recording-paper feed apparatus feeds the recording paper to the position of the thermal head, which is a printing position, whereby printing is effected in a predetermined image-printing area of the recording paper.
There have been known various methods for forming a hairline pattern, which is a pattern composed of a large number of thin lines (hairlines) extending along a specific direction. A method for consistently obtaining a clear hairline pattern has been known (see, for example, Patent Document 1). In this method, hairlines and hairline gaps are arranged on a drawing line of interest; a determination is made as to whether the hairline gaps arranged on the drawing line of interest are adjacent to the hairline gaps of a determined drawing line on which hairlines and hairline gaps have already been arranged; the drawing line of interest is treated as a determined drawing line only when none of the hairline gaps of the drawing line of interest is located adjacent to the hairline gaps of the determined drawing line; and the generation and arrangement of hairlines and hairline gaps for the drawing line of interest are performed once more when any of the hairline gaps of the drawing line of interest is located adjacent to the hairline gaps of the determined drawing line.
There have been known various methods for forming a circular hairline. However, when a fine circular hairline is formed, a moiré, which is a periodic striped pattern, is generated.
There has been known a method for preventing periodic image disturbances, such as moiré and pitch variation, from being emphasized when a plurality of colors are superimposed (see, for example, Patent Document 2). The method is used in an image forming apparatus which forms a color image by repeating an image forming process including a step of applying an oscillating voltage to an electrifier so as to charge an image bearing body. According to the method, the frequency of the oscillating voltage applied to the electrifier is shifted each time the image forming process is repeated, whereby the periodic image disturbances are prevented from being emphasized.
Patent Document 1: Japanese Patent Application Laid-Open (kokai) No. 2002-221781
Patent Document 2: Japanese Patent Application Laid-Open (kokai) No. H6-202445
However, the above-described first method requires complicated calculation for formation of hairlines.
Further, the above-described second method is peculiar to an image forming apparatus which forms a color image, in a transfer scheme or a direct scheme, by repeating an image forming process including a step (primary charging) of uniformly charging an image bearing body such as a photosensitive body or a dielectric body. Therefore, the second method cannot be applied to a thermal recording apparatus or the like.
The present invention has been accomplished in view of such problems, and an object of the present invention is to provide a thermal recording apparatus or the like which reduces effects of heat accumulated in a thermal head and prints highly fine hairline images and circular hairlines by a low resolution.
A first invention for achieving the above-described object is a printed matter obtained by performing shift processing for second image data, which are obtained from first image data through gradation conversion and halftone conversion, to thereby produce third image data; performing rotation processing for said third image data to thereby produce fourth image data; performing heat-accumulation correction processing for said third image data and said fourth image data to thereby produce fifth image data and sixth image data; and printing the fifth image data and the sixth image data on an object to be printed by a thermal recording apparatus including a thermal head.
An original image which is obtained from a read image through CMYK/RGB-gray conversion, gradation conversion, and halftone conversion, is shifted rightward and rotated by 180 degrees to thereby obtain a second image; and the original image and the second image are subjected to the heat-accumulation correction processing and are printed such that the original image and the second image are superimposed on each other. Thus, finer hairlines can be printed at a low resolution.
A second invention is a thermal recording apparatus comprising means for performing shift processing for second image data, which are obtained from first image data through gradation conversion and halftone conversion, to thereby produce third image data; means for performing rotation processing for said third image data to thereby produce fourth image data; means for performing heat-accumulation correction processing for said third image data and said fourth image data to thereby produce fifth image data and sixth image data; and means for printing the fifth image data and the sixth image data on an object to be printed.
A third invention is an image forming method comprising the steps of performing shift processing for second image data, which are obtained from first image data through gradation conversion and halftone conversion, to thereby produce third image data; performing rotation processing for said third image data to thereby produce fourth image data; performing heat-accumulation correction processing for said third image data and said fourth image data to thereby produce fifth image data and sixth image data; and printing the fifth image data and the sixth image data on an object to be printed by a thermal recording apparatus including a thermal head.
A fourth invention is a printed matter obtained by producing first image data for forming a pattern; producing, from said first image data, second image data for forming a second pattern; performing shift processing for said second image data to thereby produce third image data; performing polar coordinate conversion for said second image data and said third image data to thereby produce fourth image data and fifth image data; performing heat-accumulation correction processing for said fourth image data and said fifth image data to thereby produce sixth image data and seventh image data; and printing said sixth image data and said seventh image data on an object to be printed by a thermal recording apparatus including a thermal head.
A horizontal hairline pattern is produced by performing pattern definition, and another horizontal hairline pattern is produced by shifting the horizontal hairline pattern downward. Two circular hairlines are produced from these horizontal hairline patterns through polar coordinate conversion and combined together, whereby moiré can be reduced, and finer circular hairlines are produced.
A fifth invention is a thermal recording apparatus comprising means for producing first image data for forming a pattern; means producing, from said first image data, second image data for forming a second pattern; means for performing shift processing for said second image data to thereby produce third image data; means for performing polar coordinate conversion for said second image data and said third image data to thereby produce fourth image data and fifth image data; means for performing heat-accumulation correction processing for said fourth image data and said fifth image data to thereby produce sixth image data and seventh image data; and means for printing said sixth image data and said seventh image data on an object to be printed.
A sixth invention is an image forming method comprising the steps of producing first image data for forming a pattern; producing, from said first image data, second image data for forming a second pattern; performing shift processing for said second image data to thereby produce third image data; performing polar coordinate conversion for said second image data and said third image data to thereby produce fourth image data and fifth image data; performing heat-accumulation correction processing for said fourth image data and said fifth image data to thereby produce sixth image data and seventh image data; and printing said sixth image data and said seventh image data on an object to be printed by a thermal recording apparatus including a thermal head.
A seventh invention is a printed matter obtained by producing first image data for forming a pattern; producing, from said first image data, second image data for forming a second pattern; performing polar coordinate conversion for said second image data to thereby produce third image data; performing heat-accumulation correction processing for said third image data to thereby produce fourth image data; and printing said fourth image data on an object to be printed by a thermal recording apparatus including a thermal head.
An eighth invention is a thermal recording apparatus comprising means for producing first image data for forming a pattern; means for producing, from said first image data, second image data for forming a second pattern; means for performing polar coordinate conversion for said second image data to thereby produce third image data; means for performing heat-accumulation correction processing for said third image data to thereby produce fourth image data; and means for printing said fourth image data on an object to be printed.
A ninth invention is an image forming method comprising the steps of producing first image data for forming a pattern; producing, from said first image data, second image data for forming a second pattern; performing polar coordinate conversion for said second image data to thereby produce third image data; performing heat-accumulation correction processing for said third image data to thereby produce fourth image data; and printing said fourth image data on an object to be printed by a thermal recording apparatus including a thermal head.
A tenth invention is a printed matter obtained by performing polar coordinate conversion for second image data, which are obtained from first image data through gradation conversion and halftone conversion, to thereby produce third image data; performing heat-accumulation correction processing for said third image data to thereby produce fourth image data; and printing said fourth image data on an object to be printed by a thermal recording apparatus including a thermal head.
An eleventh invention is a thermal recording apparatus comprising means for performing polar coordinate conversion for second image data, which are obtained from first image data through gradation conversion and halftone conversion, to thereby produce third image data; means for performing heat-accumulation correction processing for said third image data to thereby produce fourth image data; and means for printing said fourth image data on an object to be printed.
A twelfth invention is an image forming method comprising the steps of performing polar coordinate conversion for second image data, which are obtained from first image data through gradation conversion and halftone conversion, to thereby produce third image data; performing heat-accumulation correction processing for said third image data to thereby produce fourth image data; and printing said fourth image data on an object to be printed by a thermal recording apparatus including a thermal head.
According to the present invention, it is possible to provide a thermal recording apparatus or the like which reduces effects of heat accumulated in a thermal head and prints highly fine hairline images and circular hairlines by a low resolution.
A first preferred embodiment of a thermal recording apparatus, etc. according to the present invention will next be described in detail with reference to the attached drawings.
Configuration and Function of the Thermal Recording Apparatus)
First, the configuration of the thermal recording apparatus (thermal printer 1) of the embodiment of the present invention will be described with reference to
As shown in
Image data 3 to be printed are input to the image input section 5. The storage section 7 stores the input image data 3, data to be temporarily stored in the course of calculation, processed image data, parameters for image processing, etc. The control section 9 is composed of a CPU (central processing unit) which executes programs, and memory such as ROM (read only memory), RAM (random access memory), etc. for storing program instruction, data, etc. The control section 9 instructs the image input section 5 to read the image data 3 or process the image data 3, sends processed image data to the printing section 11, and instructs the printing section 11 to print the image data.
Although not illustrated, the printing section 11 is composed of a thermal head including a plurality of heat-generating resistors formed in a row on a substrate; a thermal head drive section; etc. Upon receipt of image data to be printed and an instruction from the control section 9, the printing section 11 applies to the thermal head energy corresponding to each pixel value. Thus, ink at the energy-applied portion melts and adheres to recording paper, whereby an output image 15 is output. The greater the pixel value, the greater the image recording density; and the smaller the pixel value, the lower the image recording density.
Notably, the printing section 11 includes four types of ink ribbons of cyan C, magenta M, yellow Y, and black K. The inks of these colors are transferred in a superimposed state so as to perform color printing.
The image input section 5 performs image reading 21 so as to read the image data 3. The image input section 5 stores the read image data into image memory 27 of the storage section 7, and simultaneously sends the image data to the control section 9. The control section 9 performs image processing 23 on the image data 3.
The memory section 7 is composed of the image memory 27 for storing image data to undergo image processing, and the processing parameter memory 29 for storing parameters used when the image processing is performed. Further, although not illustrated, the storage section 7 further stores a control program, and control parameters of the printing section 11 such as the thermal head.
Image data acquired by the thermal printer 1 and image data calculated in the course of the image processing 23 are registered in the image memory 27.
Notably, the original image and image data obtained in the course of calculation, excluding the final image data, are not necessarily required to be left in the image memory 27.
The processing parameter memory 29 of the storage section 7 stores parameters which are used by the image processing 23 for pattern formation, shift processing, polar coordinate conversion, heat-accumulation correction processing.
The control section 9 performs the image processing 23.
The image processing 23 includes various types of processing such as CMYK/RGB-gray conversion processing, gradation conversion processing, halftone conversion processing, pattern definition, horizontal hairline pattern formation, shift processing, rotation processing, polar coordinate conversion, and heat-accumulation correction processing. The image processing 23 performs image processing for the image data stored in the image memory 27 of the storage section 7 while using respective processing parameters stored in the processing parameter memory 29 to thereby obtain final image data. Image data produced in the course of the processing are stored in the image memory 27 of the storage section 7. The control section 9 sends the finally obtained image data to the printing section 11, which performs image printing 25.
The image data 3, which represent the original image acquired by the thermal printer 1, are registered in the image memory 27, as an image G1 31-1. Images G2 31-2, G3 31-3, G4 31-4, G5 31-5, G6 31-6, G7 31-7, G8 31-8, etc. are registered as image data calculated in the course of the image processing 23.
Notably, the image G1 31-1, which is the original image, and image data calculated in the course of calculation, excluding the images G7 31-7 and G8 31-8, which serve as final image data, are not required to be left in the image memory 27.
The processing parameter memory 29 of the storage section 7 stores a CMYK/RGB-gray conversion parameter 33, a gradation conversion parameter 35, a halftone conversion parameter 37, a shift processing parameter 39, a rotation processing parameter 41, a heat-accumulation correction processing parameter 43, etc., which are used by the image processing 23.
Flow of Image Processing)
Next, the flow of image processing in the thermal printer 1 will be described.
The image input section 5 of the thermal printer reads the image data 3 (step 101); and the control section 9 holds the acquired image G1 31-1 in the image memory 27 of the storage section 7 (step 102).
Next, the control section 9 of the thermal printer 1 executes the image processing 23. That is, the control section 9 first converts the CMYK data or RGB data of the image G1 31-1 to gray data in accordance with the resolution of the thermal printer 1 to thereby produce the image G2 31-2 (step 103), and stores it in the image memory 27 of the storage section 7.
The control section 9 of the thermal printer 1 performs the gradation conversion; i.e., converts the gradation of the image G2 31-2 to thereby produce the image G3 31-3 (step 104), and stores it in the image memory 27 of the storage section 7.
In order to form thin and finer hairlines, the control section 9 performs gradation conversion of about 65% when the resolution of the thermal printer 1 is 600 dpi (dots per inch).
As shown in
The control section 9 of the thermal printer 1 performs halftone processing for the image G3 31-3 obtained through gradation conversion, to thereby produce the image G4 31-4 (step 105).
Here, it is assumed that image data express the C, M, Y, K components with the same angle, for example, image data are of a line screen type (intersection angle: 90°).
The matrix size of each halftone dot varies depending on the resolution of the thermal printer 1 and the number of lines. For example, when the resolution of the thermal printer 1 is 600 dpi, the matrix size is 10×10 pixels for the case where the number of lines is 60 lpi (lines per inch), 8×8 pixels for the case where the number of lines is 75 lpi, 6×6 pixels for the case where the number of lines is 100 lpi, and 5×5 pixels for the case where the number of lines is 120 lpi.
The control section 9 of the thermal printer 1 then performs shift processing for the image G4 31-4 obtained through the halftone processing, to thereby produce the image G5 31-5 (step 106).
As shown in
For example, when the resolution of the thermal printer 1 is 600 dpi, L1 is three pixels for the case where the number of lines of the halftone dot is 100 lpi, L1 is four pixels for the case where the number of lines is 75 lpi, L1 is five pixels for the case where the number of lines is 60 lpi, and L1 is two pixels for the case where the number of lines is 120 lpi.
After the shift processing, the control section 9 of the thermal printer 1 performs rotation processing for the image G5 31-5, to thereby produce the image G6 31-6 (step 107).
In the rotation processing, the control section 9 rotates the image G5 31-5 by 180 degrees.
The control section 9 of the thermal printer 1 performs heat-accumulation correction processing for the images G4 31-4 and G6 31-6, to thereby produce the images G7 31-7 and G8 31-8 (step 108).
The control section 9 of the thermal printer 1 ends the step of the image processing 23 and sends the images G7 31-7 and G8 31-8 to the printing section 11 as final image data (step 109).
In accordance with an instruction from the control section 9, the printing section 11 prints and outputs the images G7 31-7 and G8 31-8 as an output image 15 (step 110).
Since a first image and a second image obtained by shifting and rotating the first image are printed in a superimposed state, a halftone-converted image of hairlines can be made finer.
By superimposing, on a hairline halftone-converted image shown in
As described above, according to the present embodiment, there can be provided a thermal recording apparatus or the like which reduces effects of heat accumulated in a thermal head and prints highly fine hairline images and circular hairlines by a low resolution.
Next, a second preferred embodiment of the thermal recording apparatus of the present invention will be described.
In the second embodiment, the structure and the processing details of the thermal printer 1 are generally the same as those in the first embodiment shown in
In the second embodiment, a horizontal hairline pattern is formed after the pattern definition; the shift processing is performed for the horizontal hairline pattern, whereby another horizontal hairline pattern is produced; the two horizontal hairline patterns are subjected to the polar coordinate conversion and the heat-accumulation correction processing; and two circular hairline images are printed in a superimposed state.
In the following, the flow of processing of forming circular hairlines through pattern definition will be described.
The control section 9 of the thermal printer 1 performs the image processing 23 so as to perform pattern definition of circular hairlines and produce a pattern image G11 50 (step 201).
As shown in
Next, the control section 9 of the thermal printer 1 produces from the pattern image G11 50 a horizontal hairline pattern G12 54 shown in
Further, the control section 9 of the thermal printer 1 shifts the horizontal hairline pattern G12 54 downward by 11 pixels, to thereby produce a horizontal hairline pattern G13 55 shown (step 203).
The control section 9 of the thermal printer 1 performs polar coordinate conversion for the horizontal hairline patterns G12 54 and G13 55, to thereby produce circular hairlines G14 56 and G15 57 shown in
Although various methods, such as a nearest neighbor interpolation method, a bilinear interpolation method, and a cubic interpolation method, exist as image interpolation methods for producing circular hairlines, the nearest neighbor interpolation method can reduce moiré to the greatest degree.
After production of the circular hairlines, the control section 9 of the thermal printer 1 performs heat-accumulation correction processing for the circular hairlines G14 56 and G15 57, to thereby produce circular hairlines G16 and G17 (step 205).
The control section 9 of the thermal printer 1 ends the step of the image processing 23 and sends the circular hairlines G16 and G17 to the printing section 11 as final image data (step 206).
The printing section 11 prints and outputs the circular hairlines G16 and G17 as an output image 15 in accordance with an instruction from the control section 9 (step 207).
Since a first image and a second image obtained by shifting the first image are printed in a superimposed state, moiré is reduced, and finer circular hairlines can be formed.
Next, examples of the printed circular hairlines will be described with reference to
As shown in
As shown in
As shown in
As shown in
As described above, according to the present embodiment, there can be provided a thermal recording apparatus or the like which reduces effects of heat accumulated in a thermal head and prints highly fine hairline images and circular hairlines by a low resolution.
In the present embodiment, a horizontal hairline pattern is formed after the pattern definition; the shift processing is performed for the horizontal hairline pattern, whereby another horizontal hairline pattern is produced; the two horizontal hairline patterns are subjected to the polar coordinate conversion and the heat-accumulation correction processing; and two circular hairline images are printed in a superimposed state. However, the present embodiment may be modified such that the polar coordinate conversion and the heat-accumulation correction processing are performed for a single horizontal hairline pattern formed from the pattern definition, and circular hairlines are printed.
Further, circular hairlines having various widths can be readily printed by changing the numbers of black and white pixels used in the pattern definition.
Next, a third preferred embodiment of the thermal recording apparatus of the present invention will be described.
In the third embodiment, the structure and the processing details of the thermal printer 1 are generally the same as those in the first embodiment shown in
In the third embodiment, the flow of the image processing 23 of the second embodiment is partially changed to produce circular hairlines by performing polar coordinate conversion for a hairline image obtained from the input image 3 through CMYK/RGB-gray conversion, gradation conversion, and halftone conversion.
In the following, the flow of processing for producing circular hairlines from an input image will be described.
The image input section 5 of the thermal printer reads the image data 3 (step 301); and the control section 9 holds an acquired image G21 in the image memory 27 of the storage section 7 (step 302).
Next, the control section 9 of the thermal printer 1 executes the image processing 23. That is, the control section 9 first converts the CMYK data or RGB data of the image G21 to gray data in accordance with the resolution of the thermal printer 1 to thereby produce an image G22 (step 303), and stores it in the image memory 27 of the storage section 7.
The control section 9 of the thermal printer 1 performs the gradation conversion; i.e., converts the gradation of the image G22 to thereby produce an image G23 (step 304), and stores it in the image memory 27 of the storage section 7.
In order to form thin and finer hairlines, the control section 9 performs gradation conversion of about 65% when the resolution of the thermal printer 1 is 600 dpi (dots per inch).
As shown in
The control section 9 of the thermal printer 1 performs halftone processing for the image G23 obtained through gradation conversion, to thereby produce an image G24 (step 305).
Here, it is assumed that image data express the C, M, Y, K components with the same angle, for example, image data are of a line screen type (intersection angle: 90°).
The matrix size of each halftone dot varies depending on the resolution of the thermal printer 1 and the number of lines. For example, when the resolution of the thermal printer 1 is 600 dpi, the matrix size is 10×10 pixels for the case where the number of lines is 60 lpi (lines per inch), 8×8 pixels for the case where the number of lines is 75 lpi, 6×6 pixels for the case where the number of lines is 100 lpi, and 5×5 pixels for the case where the number of lines is 120 lpi.
The control section 9 of the thermal printer 1 then performs polar coordinate conversion for the image G24 obtained through the halftone processing, to thereby produce circular hairlines G25 (step 306).
After the production of circular hairlines, the control section 9 of the thermal printer 1 performs heat-accumulation correction processing for the circular hairlines G25, to thereby produce circular hairlines G26 (step 307).
The control section 9 of the thermal printer 1 ends the step of the image processing 23 and sends the circular hairlines G26 to the printing section 11 as final image data (step 308).
The printing section 11 prints and outputs the circular hairlines G26 as an output image 15 in accordance with an instruction from the control section 9 (step 309).
In the above-described third preferred embodiment, polar coordinate conversion is performed for a hairline image obtained from the input image 3 through CMYK/RGB-gray conversion, gradation conversion, and halftone conversion, whereby fine circular hairlines are produced.
Preferred embodiments of the thermal recording apparatus according to the present invention have been described with reference to the accompanying drawings. However, the present invention is not limited to the above-described embodiments. It is clear that a person with ordinary skill in the art can easily conceive various modifications and changes within the technical idea described in the claims, and it is contemplated that such modifications and changes naturally fall within the technical scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2006-096523 | Mar 2006 | JP | national |
| 2006-096544 | Mar 2006 | JP | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP2007/056602 | 3/28/2007 | WO | 00 | 9/24/2008 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2007/114147 | 10/11/2007 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 20030053120 | Ito | Mar 2003 | A1 |
| 20060033801 | Yun | Feb 2006 | A1 |
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| 0 260 917 | Mar 1988 | EP |
| 6-202445 | Jul 1994 | JP |
| 2000-135810 | May 2000 | JP |
| 2002-221781 | Aug 2002 | JP |
| 2002-304632 | Oct 2002 | JP |
| 2005-280302 | Oct 2005 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20090161166 A1 | Jun 2009 | US |
