JP2007268730A - Thermal recorder, image formation method and printed matter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thermal recorder which acquires a smooth gray-level image with no unevenness in superimposition printing of a highlight part and with no touch of harshness. <P>SOLUTION: A control part 9 of the thermal printer 1 performs resolution conversion and gray-level conversion of inputted image data 3, and performs CMYK plate separation processing. To the image data of each color subjected to CMYK plate separation, the control part 9 performs shift processing according to the resolution and the number of lines of the thermal printer 1 so as to acquire double-tone image data. The control part 9 performs dot-on-dot processing which is special shift processing for, e.g., a magenta (M) plate to be superimposition printed. After the image data after shift processing is passed through halftone dot processing, the data are subjected to shift processing and reverse shift processing. Then, the data subjected to dot-on-dot processing as data of a highlight region of an image, and data subjected to normal shift processing at the other region are combined and superimposition printed in the double tone. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention reduces the unevenness of overprinting in the highlight area, is not affected by the heat accumulated in the thermal head, has a feeling of roughness and can obtain a smooth gradation image, and has a white lining or polycarbonate. The present invention relates to a thermal recording apparatus and the like that can prevent white portions from being lost in printing or poor adhesion during transfer to a recording medium.

  A thermal printer is a device that heats the back of an ink ribbon stacked on a recording paper with a thermal head and thermally transfers the ink on the recording ribbon to the recording paper for printing. The ink ribbon is a thermal transfer sheet having a heat-meltable colored ink layer, and the recording paper is an image receiving sheet such as paper or a plastic sheet.

  The thermal head is composed of a plurality of heating resistors formed in a line on the substrate. The thermal printer includes a plurality of ink ribbons, and color printing can be performed by transferring the inks of a plurality of color ink ribbons on the same position of the recording paper. For example, a plurality of ink ribbons are installed in a rotating manner, and the ink ribbon for performing thermal transfer is moved to the position of the thermal head. Further, the recording paper transport device transports the recording paper to the position of the thermal head that is the printing position, and a predetermined printing range of the recording paper is printed.

  Each thermal head can control the heating amount in stages, but when transferring the color material by melting, it is easily affected by the density of the dots and adjacent dots, and it is not possible to control the gradation for each pixel. Since it is difficult, it is performed with binary values of “transfer / do not transfer” after melting. In this case, gradation expression is performed by area modulation by drawing dots of a certain size. For example, a halftone dot generation method using a rational tangent matrix, or a supercell method halftone dot generation method in which the number of gradations is artificially increased using a plurality of matrices based on this method is used.

  The image signal is processed by a correction circuit for image signal processing including a gradation correction table, the processed image signal and the image signal from the external device are selectively switched, and the image signal to be output is subjected to gradation processing. There is a way to output. In addition, the input image data is spatially partitioned into a matrix, and the growth start gradation is determined according to the priority determined in order from the pixel located at the center of the partitioned matrix toward the pixel located at the outer edge of the matrix There is a method of performing gradation conversion based on the value. (For example, see Patent Document 1 and Patent Document 2)

JP-A-11-177826 Japanese Patent Application No. 2005-096406

  However, the above-described method has a problem in that when a color plate is overlaid and printed, the halftone image of the color plate to be overlaid cannot be stably printed. This problem is particularly prominent in highlights with low gradation, resulting in a decrease in print quality, a feeling of roughness, and a smooth gradation image could not be obtained.

That is, as shown in FIGS. 10A and 10B, the printing stability of the portion to be overprinted is lowered, the halftone dot image to be printed from above is not properly applied, and the printing quality is lowered.
FIG. 4A shows an example of printing when a magenta (M) image is superimposed on a cyan (C) color plate (monochrome in the figure). A vertical wavy shaded portion is a cyan (C) portion, and a dotted portion in a light (highlight) portion of cyan (C) is a magenta (M) portion. It can be seen that when the magenta (M) image is superimposed on the highlight portion of cyan (C) and printed, the magenta (M) image is difficult to be attached and uneven.

  FIG. 4B shows an example of printing (in the figure, monochrome) when the cyan (C), magenta (M), and yellow (Y) are overprinted in this order. Magenta (M) and yellow (Y) are overprinted on the highlighted portion of cyan (C), but the magenta (M) and yellow (Y) images are difficult to stick and uneven.

  The present invention has been made in view of such a problem, and an object of the present invention is to provide a thermal recording capable of obtaining a smooth gradation image without a rough feeling without overlapping printing unevenness in a highlight portion. It is to provide a device or the like.

  In order to achieve the above-described object, the first invention performs a shift process on the second image data obtained by performing resolution conversion, gradation conversion, and color separation on the first image data, The third image data and the fourth image data are generated, and dot-on-dot processing is performed on at least one color image data to be printed after the second one of the second image data. To generate a fifth image and a sixth image data, and to convert the third image data, the fourth image data, the fifth image data, and the sixth image data into a halftone dot conversion process and vice versa. Shift processing is performed to generate seventh image data, eighth image data, ninth image data, and tenth image data, respectively, extract a highlight area of the first image data, and 7 image data and the first Among the image data, the image data in the highlight area of the image data of at least one color plate to be printed after the second are respectively the ninth image data and the tenth image data. The image data is changed to image data, eleventh image data and twelfth image data are generated, respectively, and the eleventh image data and the twelfth image data are applied to an object to be printed by a thermal recording apparatus having a thermal head. It is a printed matter characterized by being obtained by overlapping printing.

The second invention is a thermal recording apparatus having a thermal head,
Shift processing is performed on the second image data obtained by performing resolution conversion, gradation conversion, and color separation on the first image data to generate third image data and fourth image data. And dot-on-dot processing is performed on at least one color image data to be printed after the second of the second image data, and the fifth image and the sixth image data are obtained. Generating means, and performing halftone dot conversion processing and reverse shift processing on the third image data, the fourth image data, the fifth image data, and the sixth image data, respectively, Means for generating data, eighth image data, ninth image data, tenth image data, means for extracting a highlight area of the first image data, the seventh image data, and the seventh image data Among the 8 image data The image data in the highlight area of the image data of at least one color plate to be printed after the second is changed to the ninth image data and the tenth image data, respectively. Each of the eleventh image data and the twelfth image data, and the eleventh image data and the twelfth image data are printed on the object to be printed by a thermal recording apparatus having a thermal head. And a thermal recording apparatus.

  Here, the second image data, the third image data, the fourth image data, the seventh image data, the eighth image data, the eleventh image data, and the twelfth image The data includes image data for each color plate subjected to color separation.

  The shift process generates a third image data by performing a shift process for each color plane image data of the second image data by a predetermined number of pixels for each color plane. For each color plane image data of the image data, a shift process for a predetermined number of pixels and a shift process for double tone printing are performed for each color plane to generate the fourth image data.

Further, the dot-on-dot processing is the same shift processing as the color plate to be printed before at least one kind of color plate image data to be printed after the second of the second image data. To generate fifth image data and sixth image data.
For example, when printing in the order of cyan (C), magenta (M), yellow (Y), and black (K), at least with respect to magenta (M) of the color plate to be printed second or later. It is preferable to perform the same shift processing as cyan (C) to be printed.

  The shift process shifts the number of pixels different for each color plate, resulting in a step, and the printing stability of the color plate overlaid on the color plate decreases particularly in the highlight region. By using the fifth image data and the sixth image data as image data of at least one type of color plate to be printed thereafter, stable printing without unevenness becomes possible.

  The means for extracting the highlight area extracts an area having a gradation level lower than a predetermined value as the highlight area. For example, an area where the magenta (M) gradation is 40% or less may be extracted as a highlight area, or the magenta (M) gradation is 40% or less and the cyan (C) gradation is 40. % Or more of the regions may be the highlight region.

  The third invention performs a shift process on the second image data obtained by subjecting the first image data to resolution conversion, gradation conversion, and color separation, and the third image data and the fourth image data. A dot-on-dot process is performed on at least one color image data to be printed after the second of the second image data, and the fifth image and the second image data. A step of generating sixth image data; and a halftone dot conversion process and a reverse shift process on the third image data, the fourth image data, the fifth image data, and the sixth image data, Respectively, a step of generating seventh image data, eighth image data, ninth image data, and tenth image data, a step of extracting a highlight area of the first image data, and the seventh Image data and the eighth image Among the data, the image data in the highlight area of the image data of at least one color plate to be printed after the second is the ninth image data and the tenth image data, respectively. The eleventh image data and the twelfth image data, and the eleventh image data and the twelfth image data on the object to be printed by a thermal recording apparatus having a thermal head. An image forming method comprising the steps of:

  According to the present invention, it is possible to reduce overprinting unevenness in a highlight portion, to obtain a smooth gradation image without being affected by heat accumulated in the thermal head, and to obtain a smooth gradation image, and to have a white backing. It is possible to provide a thermal recording apparatus or the like that can prevent white portions from being lost in printing or poor adhesion at the time of transfer to a polycarbonate or the like.

  Hereinafter, preferred embodiments of a thermal recording apparatus and the like according to the present invention will be described in detail with reference to the accompanying drawings.

  First, the configuration of a thermal recording apparatus (thermal printer 1) according to an embodiment of the present invention will be described with reference to FIG.

  As shown in FIG. 1, the thermal printer 1 heats the back of an ink ribbon (not shown) superimposed on a recording paper (not shown) with a thermal head (not shown) so that the ink on the ink ribbon is recorded on the recording paper. This is a device that prints by thermal transfer to the printer. The thermal printer 1 includes an image input unit 5, a storage unit 7, a control unit 9, a printing unit 11, and the like, which are connected by a bus 13.

  The image input unit 5 receives image data 3 to be printed. The storage unit 7 stores input image data 3, temporarily stored data being calculated, processed image data, parameters for image processing, and the like. The control unit 9 includes a CPU (central processing unit) that executes a program and a memory such as a ROM (read only memory) and a RAM (random access memory) for storing program instructions or data. The unit 5 is instructed to capture the image data 3 and the processing of the image data 3, or the processed image data is sent to the printing unit 11 to instruct printing.

Although not shown, the printing unit 11 includes a thermal head composed of a plurality of heating resistors formed in a row on a substrate, a thermal head driving unit, and the like. When the image data to be printed is sent by the instruction of the control unit 9, the printing unit 11 applies energy according to the pixel value to the thermal head, whereby the applied portion of ink melts and adheres to the recording paper, and the output image 15 is output. If the pixel value is large, the print recording density is high. Conversely, if the pixel value is small, the print recording density is low.
There are four types of ink ribbons, cyan C, magenta M, yellow Y, and black K, and color printing is performed by transferring these inks in a superimposed manner.

  FIG. 2 is a diagram showing the relationship between the configuration of the thermal printer 1 in FIG. 1 and the processing content. The image input unit 5 performs image reading 21 of the image data 3, records the read image in the image memory 27 of the storage unit 7, and sends it to the control unit 9 at the same time. The control unit 9 performs image processing 23 on the image data 3.

  The image processing 23 is a processing step such as resolution conversion processing, gradation conversion processing, CMYK color separation processing, image shift processing, dot-on-dot processing, halftone processing, image reverse shift processing, and the like. The image data is processed using the respective processing parameters 29 to obtain final image data. The image data being processed is stored in the image memory 27 of the storage unit 7. The control unit 9 sends the finally obtained image data to the printing unit 11, and the printing unit 11 performs the image printing 25.

  FIG. 3 is a diagram illustrating details of the storage unit 7 of the thermal printer 1. The storage unit 7 includes an image memory 27 that stores image data to be subjected to image processing, and a processing parameter 29 that stores parameters used when performing image processing. Although not shown, the storage unit 7 also stores a control program, control parameters of the printing unit 11 such as a thermal head, and the like.

In the image memory 23, R (red), G (green), and B (blue) image data 3 which are original images acquired by the thermal printer 1 are registered as an image G (31-1). Image GR (31-2), image GT (31-3), image GP (31-4), image GS1 (31-5), image GS2 (31-6), image GO1 _M and image GO2 _M (31- 7), image GS1D (31-8), image GS2D (31-9), image GO1D _M and image GO2D _M (31-10), image GS1R (31-11), image GS2R (31-12), image GO1R _M and the image GO2R _M (31-13), the image GF1 (31-14), and the image GF2 (31-15) are registered as image data calculated in the course of the image processing 23.

  The image GP (31-4), the image GS1 (31-5), the image GS2 (31-6), the image GS1D (31-8), the image GS2D (31-9), the image GS1R (31-11), An image GS2R (31-12), an image GF1 (31-14), and an image GF2 (31-15) are image data obtained by converting the image GT (31-3) into CMYK data (CMYK separation), and cyan, It consists of four image data of magenta, yellow and black.

The image GO1 _M and image _GO2 M (31-7), the image GO1D _M and image GO2D _M (31-10), the image GO1R _M and image GO2R _M (31-13), the cyan, magenta, yellow, black Among them, it is image data for any color plate to be printed second or later in the overprinting.
Here, overprinting is performed in the order of cyan (C), magenta (M), yellow (Y), and black (K), and for magenta (M) to be printed second, the image GO1 _M and the image GO2 _M (31- 7), the image GO1D _M and image GO2D _M (31-10), will be described later in detail when creating an image GO1R _M and image GO2R _M (31-13).

  The processing parameter 29 of the storage unit 7 records a resolution conversion parameter 33, a gradation conversion parameter 35, a shift processing parameter 37, a halftone processing parameter 39, and a highlight area extraction parameter 41 used by the image processing 23. These parameters will also be described in detail later.

  Next, the flow of image processing in the thermal printer 1 will be described. 4 is a diagram illustrating a flowchart of the operation by the image processing 23, FIG. 5 is a diagram illustrating the transition of the image data, and FIG. 6 is a diagram illustrating an example of parameters of gradation conversion and shift processing, and halftone processing. FIG. 7 is a diagram for explaining the shift processing, and FIG. 8 is a diagram for explaining the synthesis of data in the highlight area.

The flow of the image processing 23 will be described with reference to FIG.
The image input unit 5 of the thermal printer 1 reads the image data 3 (step 101), and the control unit 9 stores the acquired image G (31-1) in the image memory 27 of the storage unit 7 (step 102).

  Next, the control unit 9 of the thermal printer 1 executes image processing 23. First, the resolution conversion processing of the image G (31-1) is performed in accordance with the resolution of the thermal printer 1, and the image GR (31-2) is executed. (Step 103) and stored in the image memory 27 of the storage unit 7. The resolution of the thermal printer 1 is, for example, 600 dpi (dots per inch), and the image data is matched with the resolution.

Next, the control unit 9 of the thermal printer 1 performs gradation conversion of the image GR (31-2), generates an image GT (31-3) (step 104), and stores it in the image memory 27 of the storage unit 7. To do.
In the case of a double tone in which the same color is divided into two, shifted, and overprinted, ideally, it is only necessary to convert the gradation by 50%. Therefore, gradation conversion of 60 to 65% is performed. The optimum gradation conversion differs depending on the resolution of the thermal printer 1 and the number of lines of the print image. For example, as shown in FIG. 5, when the resolution is 600 dpi and the number of lines is 60 lpi (dots per inch), the resolution is 60% and 75 lpi. Is 60%, 100 lpi is 65%, and 120 lpi is 65%.

The control unit 9 of the thermal printer 1 converts the image GT (31-3) obtained by gradation conversion into CMYK data (CMYK separation processing), and generates an image GP (31-4) (step 105). ) And stored in the image memory 27 of the storage unit 7. As shown in FIG. 5, the image GP (31-4) is composed of four image data of cyan GP _C , magenta GP _M , yellow GP _Y , and black GP _K.

Then, the control unit 9 of the thermal printer 1 shifts the image with respect to cyan GP _C , magenta GP _M , yellow GP _Y , and black GP _K that are image data of each color of the image GP (31-4) subjected to CMYK color separation processing. Processing is performed to generate an image GS1 (31-5) and an image GS2 (31-6) as shown in FIG. 5 (step 106). The image shift process (step 1-6) for generating the image GS1 (31-5) and the image GS2 (31-6) will be described in detail later. As shown in FIG. 5, the image GS1 (31-5) and the image GS2 (31-6) are composed of four pieces of image data of cyan C, magenta M, yellow Y, and black K, respectively.
The image data is based on the premise that CMYK is expressed with the same angle, and is assumed to be, for example, 90 ° of the line type.

  In the image shift process for generating the image data of each color plane of the image GS1 (31-5) from the image data of each color plane of the image GP (31-4), a process of shifting by the number of pixels determined for each color is performed. On the other hand, in the image shift processing for generating the image data of each color plate of the image GS2 (31-6) from the image data of each color plate of the image GP (31-4), the number of pixels determined for each color similar to the above case In addition to the shift processing by, a shift processing for performing double tone printing is performed.

FIG. 6 shows an example of the number of shift pixels in the image shift process. The number of right shift pixels and the number of lower shift pixels are shown for each color. For example, the right shift pixel number (L1 + L _Y ) for yellow (Y) is “5 + 1” when the resolution is 600 dpi and the line number is 60 lpi. This indicates that as a shift process for performing the double tone printing, 5 pixels (L1) are shifted to the right and 2 pixels are shifted to the right as the number of pixels (L _Y ) determined for yellow (Y).

That is, in the shift processing for generating the image GS1 (31-5), the data of each color plate in the image GP (31-4), if _{L M} pixels yellow case (Y) _{L Y} pixel, magenta (M), If _{L K} pixels of cyan when _{L C} pixels (C), black (K), shifted to the right, the image GS1 (31-5). When the resolution is 600 dpi and the number of lines is 60 lpi, yellow (Y) shifts to the right by 2 pixels, cyan (C) shifts to the right by 3 pixels, and magenta (M) shifts to the right by L _M = 0. Not performed.

  On the other hand, in the shift process for generating the image GS2 (31-6), in order to perform double-tone printing, the L1 pixel is shifted to the right + the number of shift pixels of each color, and the L2 pixel is shifted downward. That is, as shown in FIG. 7, in the case of cyan (C), it is shifted to the right by 7 pixels of (5 + 2) pixels, and in the case of magenta (Y), it is shifted to the right by 5 pixels of (5 + 0). , Shift 5 pixels down, yellow (Y) shifts 6 pixels to the right (5 + 1), shifts down 5 pixels, and black (K) shifts to the right, 8 pixels (5 + 3) pixels down To 5 pixels.

  As described above, the image GS1 (31-5) generated by the shift processing for each color and the image GS2 (31-6) generated by the shift processing for double tone printing are generated, and based on this. By performing double-tone printing, even when transferring to a white backing or polycarbonate, a printed image that is free from the effects of heat accumulated in the thermal head is obtained, with no white areas missing or poor adhesion. be able to.

However, by performing the shift processing for each color as described above, it is difficult to attach a color plate to be printed in the second and subsequent layers, and printing unevenness may occur. For example, when performing overprinting in the order of cyan (C) -magenta (M) -yellow (Y) -black (K), magenta (M) or yellow (Y) for overprinting on cyan (C). This makes it difficult to fix the ink, and print unevenness as shown in FIG. 10 occurs.
This is particularly noticeable in the case of a highlight image with a low gradation.

In order to prevent such non-uniformity of the overprint due to the shift process, a special shift process is performed on the color plate image to be overprinted (step 107).
Here, a case where a special shift process is performed on the image data of magenta (M) will be described by taking as an example a case where magenta (M) is overprinted next to cyan (C).

As shown in FIG. 5, image data GP _M of magenta (M) after color separation is subjected to shift processing similar to cyan (C), which is a color plate to be printed before that, and images GO1 _M and An image GO2 _M (31-7) is generated and stored in the image memory 27 of the storage unit 7 of the thermal printer 1.
That is, first, to two shifts in pixels right is the right shift pixel number _{L C} of cyan (C) for the image GP _M, to generate an image GO1 _M. Also, right-shift is the number of pixels L1 + L _C pixel (7 pixels), L2 pixels (5 pixels) shift a number of shifting down pixels cyan (C) as a shift processing for double-tone printing, to generate an image GO2 _M (FIG. 7).

In the above description, the resolution 600 dpi, but the number of shift pixels when the number of lines 60lpi been described as an example, the shift number shift pixels in the lateral direction _{L1, L C, L M,} L Y, L K, and downward The number of pixels L2 varies depending on the resolution of the thermal printer 1 and the number of lines of the print image.

As shown in FIG. 6, in the case of 75 lpi, the number of right shift pixels for each color is 60 lpi, the number of right shift pixels for each color is the same as in the case of 60 lpi, but the number of shift pixels for double-tone printing is The right shift pixel number L1 = 4 pixels and the lower shift pixel number L2 = 4 pixels. In the case of 100 lpi and 120 lpi, the number of right shift pixels for each color also changes.
By performing shift processing with the number of shift pixels of each condition shown in FIG. 6, image data GS1 (31-5), image data GS2 (31-6), image GO1 _M, and image GO2 _M (31- 7) can be generated.

In the above description, dot-on-dot processing, which is a special shift processing, is performed for magenta (M) that performs superimposition printing after cyan (C), but this is not limited to magenta (M). Dot-on-dot processing (step 107) may also be performed on a color plate such as yellow (Y). Further, dot-on-dot processing may be performed on both magenta (M) and yellow (Y).
Furthermore, in the above description, the order of overprinting has been set to the order of cyan (C) -magenta (M) -yellow (Y) -black (K), which is considered optimal, but this order is not limited to this. . In this case, the dot-on-dot process (step 107) may be performed on the color plane image data to be printed second and later.

After the image shift processing, the control unit 9 of the thermal printer 1 performs halftone dot processing on the color plate data of the image GS1 (31-5) and image GS2 (31-6), the image GO1 _M, and the image GO2 _M (31-7). To generate an image GS1D (31-8), an image GS2D (31-9), an image GO1D _M, and an image GO2D _M (31-10) (step 108), respectively, and the image in the storage unit 7 of the thermal printer 1 Save in the memory 27.
The image GS1D (31-8) is obtained from four image data of cyan GS1D _C , magenta GS1D _M , yellow GS1D _Y , and black GS1D _K , and the image GS2D (31-9) is cyan GS2D _C , magenta GS2D _M , yellow GS2D. _Y, composed of four data of black GS2D _K.

  The halftone dot matrix size varies depending on the resolution and the number of lines of the thermal printer 1. As shown in FIG. 6, when the resolution is 600 dpi, the line number is 60 lpi, the line number is 10 × 10 pixels, the line number is 75 lpi, and the line number is 8 × 8 pixels. With 6 × 6 pixels and 120 lpi, there are 5 × 5 pixels.

Next, the control unit 9 of the thermal printer 1 performs reverse shift processing on each halftone image (step 109). In other words, the image GS1D (31-8), the image GS2D (31-9), the image GO1D _M, and the image GO2D _M (31-10) are shifted in the reverse direction, and the image GS1R (31-11), respectively. and image GS2R (31-12), generates image GO1R _M and image GO2R _M (31-13), is stored in the image memory 27 of the storage section 7 of the thermal printer 1.

Since the image GS1D (31-8), the image GS2D (31-9), the image GO1D _M, and the image GO2D _M (31-10) are subjected to the shift process and the halftone process, the reverse shift process allows the correct position. Will be moved to.
Image GS1R (31-11) is cyan GS1R _C , magenta GS1R _M , yellow GS1R _Y , black GS1R _K , and image GS2R (31-12) is cyan GS2R _C , magenta GS2R _M , yellow GS2R _Y , black GS2R _K It consists of four pieces of data.

Here, in the reverse shift process, the same number of pixels are shifted in the opposite direction to the image shift process in step 106 and step 107.
That is, the image GS1D (31-8) is shifted to the left by the number of right shift pixels (L _Y , L _M , L _C , L _K ) determined for each color shown in FIG. An image GS1R (31-11) is generated. In the case of 60 lpi, yellow (Y) may be shifted by 1 pixel to the left, cyan (C) by 2 pixels to the left, and black (M) by 3 pixels to the left. Since magenta (M) is L _M = 0, no reverse shift processing is performed.

On the other hand, the image GS2D (31-9) is shifted to the left by the number of right shift pixels (L1 + L _Y , L1 + L _M , L1 + L _C , L1 + L _K ) for each color and double tone printing shown in FIG. Further, the image GS2R (31-12) is generated by shifting upward by the number L2 of the lower shift pixels. In the case of 60 lpi, yellow (Y) is 6 pixels left (5 + 1), 5 pixels above, magenta (M) is 5 pixels left (5 + 0), 5 pixels above, cyan (C) is left ( 7 pixels of 5 + 2), 5 pixels above, and black (K) may be shifted 8 pixels left of (5 + 3) and 5 pixels upward.

Further, the image GO1D _M and the image GO2D _M (31-10) are shifted in the reverse direction by the number of pixels shifted by the special shift processing in step 107.
That is, reverse shift processing is performed using the number of cyan (C) shift pixels (L1, L _C , L2) to be printed first. In the case of 60 lpi, the image GO1D _M is shifted to the left by (L _C =) 2 pixels, the image GO2D _M is shifted to the left by (L1 + L _C =) 7 pixels, and (L2 =) by 5 pixels, and the image GO1R _M And the image GO2R _M (31-13).

Above, by the process of step 109, the image GS1R (31-11) is a data to be used for double-tone printing, the image GS2R (31-12), calculating the image GO1R _M and image GO2R _M (31-13) is complete Thereafter, the image GS1R (31-11) and the image GO1R _M , and the image GS2R (31-12) and the image GO1R _M are combined to finally obtain image data for double-tone printing.
Next, the synthesis method will be described.

First, a highlight area with a low gradation is extracted from one image to be printed (step 110).
As shown in FIG. 8, based on the image data GR (31-2) after the resolution conversion process, a portion with a low gradation is a highlight region 53, and the other region is a shadow portion 51.

  At this time, as a criterion for determining the highlight area, for example, a method in which an area having a magenta (M) gradation of 40% or less is used as a highlight area, a magenta (M) gradation is 40% or less, and A method in which a region where the gradation level of cyan (C) is 40% or more is used as a highlight region can be considered.

With respect to the highlight area extracted as described above, the image data for the color plate that has been subjected to the dot-on-dot process in step 107 in the image GS1R (31-11) and the image GS2R (31-12), , The image GO1R _M and the image GO2R _M (31-13) are generated, and GF1 (31-14) and GF2 (31-15) are respectively generated and stored in the image memory 27 of the storage unit 7 of the thermal printer 1 ( Step 111).

That is, as described in the above example of processing, when dot-on-dot processing is performed on magenta (M), GS1R _M data in image GS1R (31-11) is limited to the highlight area. It is replaced with the data GO1R _M, replaced by the image data GO2R _M only data GS2R _M of among image GS2R (31-12) in the highlight area.

The right figure of FIG. 8 is explanatory drawing at the time of replacing the data of the highlight area | region of image GS1R (31-11).
As GF1 _M image data of a magenta (M) version of the image GF1, the GO1R _M is the highlight region 53 is the data of magenta (M) of GS1R (31-11) in the other shadow area 51 GS1R _M is adopted.
By also performing the same processing an image GS2R (31-12) and the image data GO2R _M, image GF2 (31-15) are obtained.

  The control unit 9 of the thermal printer 1 ends the process of the image processing 23 and sends GF1 (31-14) and GF2 (31-15) to the printing unit 11 as double-tone image data (step 112).

  The printing unit 11 prints out the image GF1 (31-14) and the image GF2 (31-15) as the output image 15 in accordance with an instruction from the control unit 9 (step 113). In addition to performing double-tone printing, shift processing and special shift processing (dot-on-dot processing) are performed in the highlight area, and by overprinting, the thermal head does not collapse due to heat accumulation, and in the highlight area There is no unevenness of printing, and when transferring to a white backing, polycarbonate, etc., it is possible to prevent missing prints and poor adhesion of the white part, and to obtain a stable, smooth and smooth gradation image.

  FIG. 9 shows a print example in which double-tone printing is performed by the method of the present embodiment (actually color printing, but FIG. 9 is monochrome). As shown in the figure, magenta (M) when overprinting on cyan (C) can be printed stably without uneven printing.

  The preferred embodiment of the thermal recording apparatus according to the present invention has been described with reference to the accompanying drawings, but is not limited to the above-described embodiment. It is obvious for those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea described in the claims, and these are naturally within the technical scope of the present invention. It is understood that it belongs.

The figure which shows the structure of the thermal printer 1 The figure which shows the relationship between the structure of the thermal printer 1, and the processing content The figure which shows the detail of the memory | storage part 7 of the thermal printer 1 A flowchart showing the flow of the image processing 23 Diagram explaining the relationship of image data The figure which shows an example of the parameter of gradation conversion, a halftone process, and a shift process Explanatory drawing of shift processing Illustration of combining data in the highlight area The figure which shows the printing result by this Embodiment Diagram showing an example of printing using the conventional method

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ......... Thermal printer 3 ......... Image data 5 ......... Image input part 7 ......... Storage part 9 ......... Control part 11 ......... Print part 13 ......... Bus 15 ......... Output image 21 ... …… Image reading 23 …… Image processing 25 ……… Image printing 27 ……… Image memory 29 ……… Processing parameters

Claims (10)

Shift processing is performed on the second image data obtained by performing resolution conversion, gradation conversion, and color separation on the first image data to generate third image data and fourth image data. With
Among the second image data, dot-on-dot processing is performed on at least one color plate image data to be printed after the second to generate fifth and sixth image data,
Halftone dot conversion processing and reverse shift processing are performed on the third image data, the fourth image data, the fifth image data, and the sixth image data, respectively. Generating image data, ninth image data, and tenth image data;
Extracting a highlight area of the first image data;
Among the seventh image data and the eighth image data, the image data in the highlight area of the image data of at least one color plate to be printed after the second, respectively, Change to the ninth image data and the tenth image data, respectively, generate eleventh image data and twelfth image data,
A print product obtained by printing the eleventh image data and the twelfth image data by superimposing them on a print object with a thermal recording apparatus having a thermal head. A thermal recording apparatus having a thermal head,
Shift processing is performed on the second image data obtained by performing resolution conversion, gradation conversion, and color separation on the first image data to generate third image data and fourth image data. Means,
Means for performing dot-on-dot processing on image data of at least one color plate to be printed after the second of the second image data to generate a fifth image and a sixth image data When,
Halftone dot conversion processing and reverse shift processing are performed on the third image data, the fourth image data, the fifth image data, and the sixth image data, respectively. Means for generating image data, ninth image data, and tenth image data;
Means for extracting a highlight area of the first image data;
Among the seventh image data and the eighth image data, the image data in the highlight area of the image data of at least one color plate to be printed after the second, respectively, Means for changing to the ninth image data and the tenth image data, and generating eleventh image data and twelfth image data, respectively;
Means for printing the eleventh image data and the twelfth image data by superimposing the eleventh image data and the twelfth image data on an object to be printed by a thermal recording apparatus having a thermal head;
A thermal recording apparatus comprising:   The second image data, the third image data, the fourth image data, the seventh image data, the eighth image data, the eleventh image data, and the twelfth image data are colors. 3. The thermal recording apparatus according to claim 2, further comprising image data for each separated color plate.   In the shift process, the color image data of the second image data is shifted by a predetermined number of pixels for each color plate to generate the third image data, and the second image The fourth image data is generated by performing shift processing for a predetermined number of pixels and shift processing for double tone printing for each color plane image data of data. Item 3. The thermal recording apparatus according to Item 2.   In the dot-on-dot processing, the same shift processing as that of the color plate printed before is performed on the image data of at least one type of color plate printed after the second of the second image data. 5. The thermal recording apparatus according to claim 2, wherein the fifth image data and the sixth image data are generated.   In the dot-on-dot processing, when printing in the order of cyan (C), magenta (M), yellow (Y), and black (K), at least magenta (M) of the color plate to be printed after the second. 6. The thermal recording apparatus according to claim 5, wherein the same shift processing as cyan (C) to be printed before is performed.   3. The thermal recording apparatus according to claim 2, wherein the highlight area extracting unit extracts an area having a gradation level lower than a predetermined value as a highlight area.   8. The thermal recording apparatus according to claim 7, wherein the highlight area is an area having a magenta (M) gradation of 40% or less.   8. The thermal recording apparatus according to claim 7, wherein the highlight area is an area having a magenta (M) gradation of 40% or less and a cyan (C) gradation of 40% or more. Shift processing is performed on the second image data obtained by performing resolution conversion, gradation conversion, and color separation on the first image data to generate third image data and fourth image data. Process,
A step of performing dot-on-dot processing on at least one color image data to be printed after the second of the second image data to generate a fifth image and a sixth image data When,
Halftone dot conversion processing and reverse shift processing are performed on the third image data, the fourth image data, the fifth image data, and the sixth image data, respectively. Generating image data, ninth image data, and tenth image data;
Extracting a highlight area of the first image data;
Among the seventh image data and the eighth image data, the image data in the highlight area of the image data of at least one color plate to be printed after the second, respectively, Changing to the ninth image data and the tenth image data, and generating the eleventh image data and the twelfth image data, respectively;
A step of printing the eleventh image data and the twelfth image data by superimposing them on an object to be printed by a thermal recording apparatus having a thermal head;
An image forming method comprising: