JPH0664206A - Halftone recording thermal head, method and apparatus for halftone recording - Google Patents

Abstract

PURPOSE:To eliminate the lowering of image quality due to the line formation in the main scanning direction in a sub-scanning direction dividing system. CONSTITUTION:The width (d) in a sub-scanning direction of each of the heating resistor elements 3 of a thermal head is made narrower than the width D of one pixel in the sub-scanning direction and the position or printing position in the sub-scanning direction of each of the heating resistor elements 3 is arbitrarily set within the width of one pixel. Therefore, the printing dots of the respective lines recorded by the respective heating resistor elements 3 are not continuously and linearly connected along a main scanning direction and the stripe like noise in a printing image caused by the line formation in the main scanning direction can be eliminated. Since the overlap of the respective colors of printing dots is arbitrary in color recording, the color shift of the whole of an image is not generated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses a thermal head in which a plurality of heating resistor elements are juxtaposed in the main scanning direction and suitable for halftone recording, and a thermal head in which heating resistors are installed in the main scanning direction. The present invention relates to a recording method and a recording device.

[0002]

2. Description of the Related Art Conventionally, there is sublimation type thermal transfer recording as one of halftone recording systems using a thermal head. In this method of recording, a donor film carrying a sublimation type dye is heated by a thermal head, and the dye sublimated by this heating is transferred to a recording medium to develop a color. Printing requires time because a large amount of energy is required for heating.
Further, there is a problem in that it costs too much because special paper for sublimation type thermal transfer recording is used as the recording medium.

On the other hand, as another recording method, a fusion type thermal transfer system is known in which an ink donor film carrying ink is heated and melted to transfer the ink from the film to a recording medium. This fusion-type thermal transfer method uses a small amount of energy to heat the thermal head and is inexpensive, but since the ink donor film itself cannot obtain gradation even if the applied energy is changed, multi-gradation recording, that is, halftone recording is performed. Is difficult. In order to solve this problem, a matrix method such as dithering, sub-scanning divided printing, and local heat concentration on the surface of the heating resistor element of the thermal head are used to reduce the heating area and take gradation. Is proposed.

Further, Japanese Patent Laid-Open No. 60-248074,
In the thermal transfer thermal halftone recording method disclosed in Japanese Patent Laid-Open No. 3-219969, a heating resistor element having a width in the sub-scanning direction shorter than that in the main-scanning direction is used (hereinafter, referred to as "heat generating resistor element").
This method is called the sub-scanning division method). FIG. 18 is a plan view of a heat generating portion of a thermal head used for recording in the sub-scanning direction division method, showing a main portion of a so-called alternate read type thermal head, in which 1 is a common electrode and 2 is a selection. The electrodes 3 are heating resistors.

This thermal head has comb-shaped common electrode elements 1-1 to 1-1 provided so as to extend from the common electrode 1 in the sub-scanning direction.
-6 and the comb-shaped selection electrode elements 2-1 to 2-5, which are alternately arranged in the main scanning direction with respect to the comb-shaped common electrode elements 1-1 to 1-6, on the main scanning direction. And a heat generating resistor 3 formed in a strip shape in the shape of, for example, a comb-shaped selection electrode element 2
2 is selected and a current I is passed through the common electrode 1 through the comb-shaped common electrode elements 1-1 and 1-2 to heat the area H of the heating resistor shown in the main scanning direction to heat the ink. It is melted and transferred to a recording medium.

FIG. 19 is an explanatory diagram of an example of print recording when halftone recording is performed using the above thermal head.
Reference numerals -1 to 4-15 indicate one or a plurality of print dots each expressing one pixel.

[0007]

In the above prior art, as shown in FIG. 19, in the halftone recording, each pixel is often printed continuously in the main scanning direction, and the recording of each pixel is performed. Since the start timings are the same, the recording start of each pixel is aligned as shown in the figure, and a continuous print line is formed in the main scanning direction. Due to the formation of the print line, there is a problem that streak-shaped visual noise is generated in the printed image, which deteriorates the image quality.

When recording a color image, yellow,
Overprint with magenta and cyan (black if necessary) ink. Therefore, unless registration is accurately performed for each color, the degree of overlap of the print lines formed for each color changes, causing color misregistration, which causes a problem of degrading image quality. FIG. 20 is a printing state diagram for explaining color misregistration, and a case of overprinting two color inks will be described. Here, (a), (b), and (d) show the print state of a single color, and (c) and (e) show the print state of overprinting.

FIG. 1A shows a state where the first color is printed, and FIG. 1B shows a state where the second color is printed. If the registration of the first color printing and the second color printing is performed correctly, (a) and (b)
By overlapping, the print lines are accurately overlapped with each other as shown in FIG. On the other hand, for example, as shown in (d) of the figure, when the registration of the printing of the second color is not accurately performed, (a) of the printing of the first color and (d) of the printing of the second color are performed. ), The printed lines do not overlap exactly as shown in (e) of the figure,
Color shift occurs.

In this color misregistration, since the recording start timing of each pixel is the same, the recording start of each pixel is aligned and a continuous print line is formed in the main scanning direction.
Due to the formation of the print line, color misregistration is emphasized and streak-like visual noise is generated in the image. It is a first object of the present invention to provide a halftone recording thermal head suitable for the sub-scanning division method.

A second object of the present invention is to provide a recording method using a halftone recording thermal head suitable for the sub-scanning division method. A third object of the present invention is to provide a recording apparatus using a thermal head for halftone recording suitable for the sub-scanning division method.

[0012]

To achieve the above object, the present invention provides a halftone recording thermal head in which a plurality of heating resistor elements are arranged side by side in the main scanning direction. The width of the resistor element in the sub-scanning direction is made narrower than the width of one pixel to be printed, and the arrangement position of each heating resistor element in the sub-scanning direction in the area of one pixel is arbitrary, and the adjacent pixel in the main scanning direction is set. This is to prevent continuous dots from occurring.

Further, the present invention uses a thermal head in which a band-shaped heating resistor whose width in the sub-scanning direction is smaller than that of one pixel to be printed is arranged in the main scanning direction. When the print width of the pixel in the sub-scanning direction is modulated to express the halftone density, the print start position of the one pixel in the sub-scanning direction is selected at an arbitrary position within the width of one pixel in the sub-scanning direction. It is characterized in that recording of each pixel is started.

Further, according to the present invention, a plurality of strip-shaped heating resistors whose width in the sub-scanning direction is smaller than the width of one pixel to be printed in the sub-scanning direction are arranged side by side in the main scanning direction. −
When the print width of one pixel in the sub-scanning direction is modulated by using a round head to express the halftone density of three colors of cyan, magenta and yellow, the print start position of one pixel of each color in the sub-scanning direction is set to 1 It is characterized in that recording is started for each pixel by selecting an arbitrary position within the width of the pixel in the sub-scanning direction.

That is, in order to achieve the first object, the present invention provides a halftone recording thermal head in which a plurality of heating resistor elements are juxtaposed in the main scanning direction, and the heating resistor of the thermal head is used. The width d of the elements 3-1 to 3-5 in the sub-scanning direction is narrower than the width D of one pixel to be printed in the sub-scanning direction, and the plurality of heating resistor elements 3-1 to 3-5 are provided.
The position in the sub-scanning direction is arbitrarily arranged within the width of one pixel in the sub-scanning direction.

In order to achieve the second object, according to the present invention, a plurality of heat generating resistor elements 3-1 to 3-5 are arranged in parallel in the main scanning direction, and the heat generating resistor element 3-1. A width d of 3-5 in the sub-scanning direction is a width D of one pixel to be printed in the sub-scanning direction
It is narrower and the plurality of heating resistor elements 3-1 to 3-3-
Printing is performed using a thermal head in which the position 5 in the sub-scanning direction is arbitrarily arranged within the width D in the sub-scanning direction for one pixel.

In order to achieve the second object, the present invention provides a strip-shaped heating resistor 3 having a width d of the heating resistor 3 in the sub-scanning direction narrower than a width D of one pixel to be printed in the sub-scanning direction. In a halftone recording method of expressing a halftone density by modulating a print width of one pixel in the subscanning direction using a thermal head installed in the main scanning direction, the recording start position of one pixel in the subscanning direction is set to 1 It is characterized in that the printing is started by selecting an arbitrary position within the width D of the pixel in the sub-scanning direction.

In order to achieve the second object, the present invention provides a strip-shaped heating resistor 3 having a width d of the heating resistor 3 in the sub-scanning direction narrower than a width D of one pixel to be printed in the sub-scanning direction. In a halftone recording method of expressing a halftone density by modulating a print width of one pixel in the subscanning direction using a thermal head installed in the main scanning direction, the recording start position of one pixel in the subscanning direction is set to 1 When the dot forming each pixel is selected at an arbitrary position within the width D of the pixel in the sub-scanning direction and the thin line or character is printed, the thin line or character is printed. It is characterized in that the dots are printed at the same print start position between adjacent pixels in the main scanning direction.

In order to achieve the second object, according to the present invention, a plurality of strip-shaped heating resistors whose width d in the sub-scanning direction of the heating resistor 3 is narrower than width D in the sub-scanning direction for one pixel to be printed. Three
In a half-tone recording method in which the print width of one pixel in the sub-scanning direction is modulated by using a thermal head arranged in parallel in the main-scanning direction to express halftone densities of three colors of cyan, magenta, and yellow. The printing start position of one pixel of each color in the sub-scanning direction is selected at an arbitrary position within the width D of the one pixel in the sub-scanning direction, and printing of the dots forming each pixel is started. .

Further, in order to achieve the second object, according to the present invention, a plurality of strip-shaped heat generations in which the width d of the heating resistor 3 in the sub-scanning direction is narrower than the width D of one pixel to be printed in the sub-scanning direction. A halftone that expresses halftone density of three colors of cyan, magenta, and yellow by modulating the print width of one pixel in the subscan direction using a thermal head in which resistors 3 are arranged in parallel in the main scan direction. In the recording method, the recording start position of one pixel of each color in the sub-scanning direction is displaced from an adjacent pixel by a certain amount within a width D of one pixel in the sub-scanning direction, and the displacement amount of each color is made different. It is characterized in that printing of dots forming each pixel is started.

In order to achieve the third object, the present invention provides a strip-shaped heating resistor 3 having a width d of the heating resistor 3 in the sub-scanning direction narrower than a width D of one pixel to be printed in the sub-scanning direction. In a halftone recording apparatus that expresses a halftone density by modulating a print width of one pixel in the subscanning direction using a thermal head installed in the main scanning direction, image data input means 81 for taking in image data to be recorded. A gradation conversion / γ correction means 82 for gradation conversion of the captured image data and γ correction, and a print position deviation amount for arbitrarily setting the print position of the heating resistor 3 in the sub-scanning direction. A deviation amount generating means 83 for generating, print data generating means 84 for generating print data from the gradation data input from the gradation converting / γ correcting means 82 and the deviation amount from the deviation amount generating means 83.
And a head driver 85 for generating a head drive signal for driving the thermal head 86 based on the print data,
And a recording unit 87 including the thermal head that executes printing in accordance with a drive signal supplied from the head driver 85.

In order to achieve the third object, the present invention provides a strip-shaped heating resistor 3 having a width d in the sub-scanning direction narrower than a width D of one pixel to be printed in the sub-scanning direction. An image data input unit 81 for taking in image data to be recorded in a halftone recording apparatus that uses a thermal head installed in the main scanning direction to modulate a print width of one pixel in the subscanning direction to express halftone density. A gradation conversion / γ correction means 82 for gradation conversion of the captured image data and γ correction, a thin line / character detection means 88 for detecting that the input data to be printed is a thin line or a character, A print position shift amount for arbitrarily setting the print position of the heating resistor 3 in the sub scanning direction along the main scanning direction is generated, and
When a signal with a zero displacement amount is generated from the fine line / character detection unit 88, the displacement amount generation control unit 83 ′ that makes the printing position displacement amount zero and the gradation input from the gradation conversion / γ correction unit 82. Print data generating means 84 for generating print data from the data and the shift amount from the shift amount generating means 83 '.
And a head driver 85 for generating a head drive signal for driving the thermal head 86 based on the print data,
And a recording unit 87 including the thermal head 86 that executes printing by a drive signal supplied from the head driver.

The fine line / character detecting means 88 is used in place of detecting fine lines and characters based on the output of the gradation converting / γ correcting means 82, and directly from input image data or print data generation. It is also possible to adopt a configuration in which thin lines and characters are detected based on the print data generated by the means 84.

[0024]

With the configuration of the thermal head, the printing method, and the recording apparatus according to the present invention, the print dots recorded by each heating resistor are recorded at any position within the width of one pixel in the sub-scanning direction. Even if the adjustment recording is performed, no line is generated due to the combination of the print dots continuous in the main scanning direction.

For this reason, the lines have different angles with respect to the recording paper because of good connection with the adjacent pixels generated in each color, and the manner in which the dots recorded by the heating resistors overlap is different. Therefore, unlike the prior art, it is possible to realize extremely high-quality halftone recording without deterioration of the recording image quality such as streak-like visual noise and color misregistration caused by line formation in the main scanning direction.

For objects such as thin lines and characters to be printed whose reproducibility is deteriorated when adjacent print dots are not continuous in the main scanning direction, the above-described deviation amount is not generated. The input data is directly supplied to the thermal head as gradation data and print data. The present invention is not limited to the alternate read type thermal head described above, but can be applied to a so-called individual facing type thermal head.

[0027]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a plan view of an essential part for explaining one embodiment of a thermal head according to the present invention, in which 1 is a common electrode, 2 is a selection electrode, 3 is a heating resistor, and this thermal head is a so-called alternating lead. Type thermal head.

In the figure, comb-shaped common electrode elements 1-1 to 1-6 extending from the common electrode 1 in the sub-scanning direction,
Comb-shaped selection electrode elements 2-1 to 2-1 arranged alternately with respect to the comb-shaped common electrode elements 1-1 to 1-6 in the main scanning direction.
Heat generating resistor elements 3-1 to 3-5 constituting the heat generating resistor 3 are provided on the main scanning direction 2-5, and for example, the comb-shaped selection electrode element 2-3 is selected to select the comb-shaped common electrode. By passing a current through the common electrode 1 through the elements 1-3 and 1-4,
The illustrated heating resistor element 3-3 is caused to generate heat to heat and melt the ink (not shown), which is transferred to a recording medium.

As described above, the printing is performed in a region sandwiched by one comb-shaped selection electrode element and the comb-shaped common electrode elements on both sides thereof. Here, the positions of the heating resistor elements 3-1 to 3-5 in the sub-scanning direction are varied within the range of the width D in the sub-scanning direction for one pixel. The scattering method in this embodiment will be described with reference to Table 1.

[0030]

[Table 1]

In Table 1, resistor numbers 1, 2,
.. are numbers in order of the heating resistor elements arranged from one end to the other end of the thermal head in the main scanning direction, where r is a random number and D is one sub-scanning direction. Indicates the width of the pixel. In this embodiment, a computer is used to generate a random number r (where 0 ≦ r ≦ 1), and the random number r and 1 are generated.
A value obtained by multiplying 1/2 of the width D of the pixel in the sub-scanning direction is calculated.

Coordinates in the sub-scanning direction of odd-numbered resistor numbers of the heat-generating resistor elements arranged in the main-scanning direction are obtained by using this random number r × D / 2 and coordinates of the even-numbered heating resistors in the sub-scanning direction. Uses a value obtained by adding D / 2 to the random number r × D / 2. Table 1 shows the actual 300 DPI (dot per
The values calculated in the case of a pixel density of inch) (that is, the width D of one pixel in the sub-scanning direction corresponds to about 84.7 μm) are shown.

Further, in the present embodiment, the width d in the sub-scanning direction of each of the heating resistor elements 1, 2, 3, 4, ... Is about 1/5 of the width D for one pixel in the sub-scanning direction. Is set to. For example, in the case of a pixel density of 300 DPI, the width d of each heating resistor element 1, 2, 3, 4, ... In the sub-scanning direction is about 19 μm. With such a configuration, the print dots recorded by the respective heating resistor elements 1, 2, 3, 4, ... Are recorded at arbitrary positions within the width of one pixel in the sub-scanning direction and are adjacent to each other. The probability of continuous printing dots is low, and lines in the main scanning direction do not occur even when halftone recording is performed. Therefore, deterioration of image quality due to streak-like noise due to line formation in the main scanning direction and visual noise such as color misregistration is eliminated, and good halftone recording can be realized.

Next, a method of manufacturing the thermal head of the embodiment described with reference to FIG. 1 will be described. 2 is a structural sectional view of a thermal head for explaining a method of manufacturing a thermal head according to one embodiment of the present invention, and FIG. 3 is a top view for explaining a method of manufacturing a thermal head according to one embodiment of the present invention. Is. In FIG. 2, 4 is a ceramic substrate, 5 is a glass glaze layer, 6 is a conductor film,
In FIG. 3, 7 is a photosensitive resist, 8-1 to 8-5.
Is a resist opening.

First, as shown in FIG. 2, a glass glaze layer 5 having a thickness of about 60 μm is formed on the ceramic substrate 4 by a thick film technique. Then, a conductor film 6 having a thickness of about 1 μm is formed on the glass glaze layer 5 by coating and firing a metal organic paste such as gold, and the common electrode 1 (the comb-shaped common electrode elements 1-1 to 1-1 is formed by a photolithography etching process. 1-6) and the selection electrode 2 (comb-shaped selection electrode elements 2-1 to 2-5) are formed. The electrode structure is shown in FIG.
They are arranged in the alternating lead type as described in 1.

Next, as shown in FIG. 3, a photosensitive resist 7 is applied on the above-formed electrodes by a roll coater, a spin coater or the like to a film thickness of about 20 μm, exposed and developed by a photomask, and heated. A photosensitive resist pattern having resist opening portions 8-1 to 8-5 is formed at the location where the resistor element is provided. In this embodiment, the opening 8-1
The width in the sub-scanning direction of 8 to 5 is set to be about 1/5 of the width D in the sub-scanning direction for one pixel. For example, 300DP
In the case of the pixel density of I, the openings 8-1 to 8-5 are formed so that the width d of each heating resistor element in the sub-scanning direction is about ⅕ of the width D of one pixel in the sub-scanning direction. The width in the sub-scanning direction was about 20 μm.

A thick film resistor is formed so as to be wider than the width of the opening and thicker than the film thickness of the opening with respect to the photosensitive resist pattern in which the openings 8-1 to 8-5 are formed. The metal organic resistor paste to be formed is formed by screen printing and then dried. After that, the thick film resistor on the photosensitive resist pattern is removed by polishing with, for example, a lapping sheet, and at the same time, the surface of the thick film resistor in the opening is removed so as to have the same thickness as the opening.

The thick film resistor thus flattened is
The photosensitive resist 7 is burned and sintered at a high temperature of 00 to 900 ° C., and the photosensitive resist 7 is burned and vaporized to generate a heating resistor element 3-
1-3-5 (FIG. 1) are formed. Finally, a paste containing a glass material is applied by screen printing or the like, and this is baked at a high temperature of 800 to 900 ° C. to form an overglaze layer (not shown) as a wear resistant layer.

The thermal head according to the present invention is manufactured by the above process. FIG. 4 is an illustration of a printing example in which the thermal head according to the present invention manufactured as described above is used for printing. All the comb-shaped selection electrode elements 2-1 to 2-5 are selected and energized. Heating element 3-1
3 to 5 are heated to print a line image in the main scanning direction for recording.

As shown in the drawing, the print dots at this time are the print dots 9-1 to 9-5 of the first line, the print dots 10-1 to 10-5 of the second line, and the print dots of the third line. The dots 11-1 to 11-5 are recorded. The positions of the respective heating resistor elements 3-1 to 3-5 in the sub-scanning direction are set so as to vary within the range of the width D in the sub-scanning direction for one pixel. 9-1 to 9-
The lines 5, 10-1 to 10-5 and 11-1 to 11-5 are not continuously connected in a straight line, and even if halftone recording is performed, line formation in the main scanning direction does not occur.

Further, the method of varying the position of each heating resistor element in the sub-scanning direction is not limited to the above embodiment, and for example, as shown in Table 2, a random number r ( However, a value obtained by multiplying 0 ≦ r ≦ 1) by the width D in the sub-scanning direction for one pixel may be used.

[0042]

[Table 2]

Further, instead of using random numbers or the like, they may be arranged according to an appropriate rule such that the amount of deviation in the sub-scanning direction is different between adjacent heating resistor elements. In the case of 300 DPI of the present embodiment, the position of each heating resistor element in the sub scanning direction is the width D (= about 84.7) of one pixel in the sub scanning direction.
μm). However, when the pixel density is low or depending on the application, when the position is changed by the width D of one pixel in the sub-scanning direction, the deviation of each print dot in the first line may deteriorate the image quality. Therefore, it is desirable to change the arrangement position of the heating resistor element within a range smaller than the width D of one pixel in the sub-scanning direction.

Next, another embodiment of the present invention will be described. In the above-described embodiment, the visual noise in the main scanning direction is reduced by varying the arrangement position itself of the heating resistor elements that form the thermal head.
In the embodiment described below, the heating resistor is formed in a continuous strip shape in the main scanning direction, and the printing start position in the sub-scanning direction of the unit heating region formed by this heating resistor is arbitrarily set within the range of one pixel. It was done.

5A and 5B are explanatory views of another embodiment of the halftone recording method according to the present invention. FIG. 5A is a configuration diagram of a thermal head, and FIG. 5B is an explanatory diagram of print dots expressing gradation. ,
FIG. 7C is an explanatory diagram of print timing. In the figure, 1 is a comb-shaped common electrode, 2 is a comb-shaped selection electrode, 30 is a heating resistor, and 1-1 to 1-9 are comb-shaped common electrodes extending from the comb-shaped common electrode 1 in the sub-scanning direction. Electrode element, 2-1 to 2-9
Is a comb-shaped selection electrode element, 30-1 to 30-8 are unit heat generating areas, and 12-1 to 12-8 are print records.

The basic electrode structure of this thermal head is an alternating lead type, and for printing and recording, one comb-shaped selection electrode element (for example, 2-5) and comb-shaped common electrode elements on both sides thereof (for example, 1) are used. This is performed in the unit heat generation region H sandwiched between -5 and 1-6). The width d of the heating resistor 30 in the sub-scanning direction is set smaller than the width D of one pixel in the sub-scanning direction. In the present embodiment, a case will be described in which the width d of the heating resistor 30 in the sub-scanning direction is set to about ¼ of the width D in the sub-scanning direction for one pixel, and halftone recording of 8 gradations is performed.

The recording paper, which is a recording medium, is fed at a constant speed in the sub-scanning direction. The feeding speed of the recording paper is set to a speed for feeding the width D of one pixel in the sub-scanning direction in the print cycle T shown in (c). As shown in the print record 12-1, the first gradation is represented by no printing without applying the print pulse.

As shown in the print record 12-2, the second gradation is expressed by applying a print pulse having a pulse width Tp so as to record a dot having substantially the same area as the unit heating area of the heating resistor 30. To do. As a result, 1/4 (2/8) of one pixel is recorded. At the third gradation, first, the same recording as the above-mentioned second gradation is performed, and then a timing delayed by 1/8 of the printing cycle T (recording paper is sent by 1/8 of the width of one pixel in the sub-scanning direction). ), A print pulse having a pulse width Tp is again applied to the heating resistor in the unit heating area 30-3 to print and record. As a result, 3/8 of one pixel is recorded.

For the fourth gradation, after the same recording as the above-mentioned third gradation, a timing delayed by ⅛ of the printing cycle T (recording paper is sent by ⅛ of the width of one pixel in the sub-scanning direction). The print pulse having the pulse width Tp is again applied to the unit heating area 3
It is applied to the heating resistors 0-4 and printed and recorded. As a result, 1/2 (4/8) of one pixel is recorded.

Thereafter, when the number of print pulses sequentially applied is increased by the same operation, as shown in FIG.
Halftone recording of gradation can be performed. In this embodiment, eight gradations are used for simplification of description. However, with a thermal head having a resolution of 300 DPI, the width d in the sub-scanning direction is set to about 20 μm, and a high resolution ink donor film (P
ET substrate thickness 3.5 μm, ink application amount 2.0 g / m ² )
It is possible to record halftones of 64 gradations with a cycle of 20 ms / 1 in.

If the print cycle is shortened or the number of gradations is increased, the interval between print pulses is shortened and heat is accumulated. In that case, recording is performed with each print pulse. It is necessary to adjust the pulse width so that the area is almost the same as the heating resistor in the unit heating area. Next, a driving method for setting the recording start position of the recording pixel in the sub-scanning direction to an arbitrary position within the width of one pixel will be described.

FIG. 6 is an explanatory diagram of a driving method in which the recording start position of the recording pixel in the sub-scanning direction is set to an arbitrary position within the width of one pixel. FIG. 6A is a structural diagram of the thermal head. , (B) is an explanatory diagram of print dots expressing gradation,
FIG. 7C is an explanatory diagram of print timing. In the figure, the same reference numerals as those in FIG. 5 correspond to the same parts, and the recording pixels of three gradation expression in FIG. 5 are taken as an example.

As shown in FIG. 6, if printing is started at the first timing of the printing cycle T shown in (c), the same recording as in FIG. 5 is performed, but the recording timing is 0 in the printing cycle.
By changing from / 8 to 5/8, the print start position within one pixel can be changed as shown in (b). In FIG. 6, as a specific example of changing the print start position within one pixel, a case where the print start position of one pixel in the sub-scanning direction is displaced from an adjacent pixel by a certain amount within a width of one pixel is shown. . Therefore, by changing the recording timing from 0/8 to 5/8 of the printing cycle, the recording start position of one pixel in the sub-scanning direction is set to 1/8 of that of adjacent pixels.
It can be shifted by the amount of deviation.

FIG. 7 shows that each pixel is actually 3 by using the above method.
FIG. 9 is an explanatory diagram of an example of print recording in the case of gradation, in which the print timing of each recording pixel 13-1 to 13-8, 14-1 to 14-8 is 0/8 to 5 / of the print cycle T, respectively. Each unit heat generation area 30 by varying in the range of 8
The print dots recorded by the heat generating resistors -1 to 30-8 are recorded at arbitrary positions within the width D of one pixel in the sub-scanning direction, and each print dot becomes linear even if halftone recording is performed. Lines in the main scanning direction are not generated without continuous connection.

As a result, the problem of image quality deterioration such as streak noise and color shift due to line formation in the main scanning direction is solved, and good halftone recording can be realized. Next, a method of varying the print start position in this embodiment will be described with reference to Table 1.

[0056]

[Table 3]

In the three-step recording of FIG. 7, a value varying in the range of 0 to 5 is required, and a random number r (where 0 ≦ r ≦ 1) is generated using a microprocessor or the like, and the random number r and 5 Calculate the value multiplied by .99 and round down the decimal point to create the deviation amount. By setting the value of this shift amount as the recording start timing, the print recording as shown in FIG. 7B becomes possible. Note that "5.9" used here is used.
The value of "9" is a number for multiplying and rounding down to the nearest whole number to generate 0-5.

Next, an explanation will be given of the case where the driving method for making the recording start position of the recording pixel in the sub-scanning direction an arbitrary position within the width of one pixel is applied to color printing.
FIG. 8 is a flowchart for explaining the operation in the case of performing color printing. In color printing, three colors of yellow, magenta and cyan, or four colors including black are sequentially printed, and the colors are overlapped. .

First, yellow component data is received from an external device (step S1), and printing is performed on the recording paper in step A (step S2). In step A, after setting the thermal head, the paper is fed at a constant speed, and the thermal head is driven according to the received data in synchronization with the paper feeding. When the printing of the yellow component is completed in step S2, the magenta component data is received from the external device (step S3), and the recording paper is printed again in step A (step S4).

When the printing of the magenta component is completed in step S4, the cyan component data is received from the external device (step S5), and the recording paper is printed in step A (step S6). Step S1
By the step S6, printing of three colors of yellow, magenta and cyan is performed. Further, when printing is performed in black in addition to these three colors, the black component data is received from the external device in step S7, and printing is performed on the recording paper in step A (step S8).

An example of applying the method of the present invention when performing color printing by the above steps will be described. Figure 9
It is an example of print recording of color printing, and shows an example of print recording in the case of two-color printing and three gradations. In this example, the deviation amount from the adjacent pixel is set to 1 of the printing cycle for the first color.
/ 8, and for the second color, it is set to 2/8 of the print cycle. The set amount of the print cycle can be set arbitrarily as long as it is different between adjacent pixels. In the figure, 9 represents the first color and 10 represents the first color.

By this setting, it is possible to make the overlapping manner of the print dots recorded by each heating resistor different. How the print dots overlap will be described with reference to FIG. FIG. 10 is a printing state diagram for explaining the color misregistration in the present invention, and the case of overprinting two color inks will be described. Here, (a), (b) and (d) show the print state of a single color, and (c) and (e) show the print state of overprinting, respectively, showing the case of the same gradation. .

FIG. 6A shows the printing state of the first color, and between adjacent pixels, the shaded print portions are printed in such a manner that they are sequentially displaced by a certain displacement amount δ1. . Further, (b) shows the printing state of the second color, and between adjacent pixels, the printed portion indicated by the diagonal line in the direction opposite to the diagonal line in the case of (a) above is
Printing is performed with a certain shift amount δ2 in order. The shift amount δ2 is set to be different from the shift amount δ1.

When the registration of the printing of the first color and the printing of the second color are accurately performed, the printing states of (a) and (b) are overlapped, as shown in (c) of the same figure. On the other hand, for example, when the registration of the printing of the second color is not accurately performed as shown in (d) of the figure, the printing of the first color (a) and the printing of the second color are performed. When (d) is overlaid, a print state is obtained as shown in (e) of the figure.

Comparing (c) showing the printing state when the registration is correctly performed and (e) showing the printing state when the registration is not correctly performed, it is found that the printing dots overlap each other. Although different, the degree of overlap can be considered to be substantially the same, and they are equivalent in a macroscopic region by visual sense, and the problem of image quality deterioration called color shift is solved.

The streak noise due to line formation in the main scanning direction is not emphasized by overprinting because the angles are different for each color, and the streak noise as shown in FIG. 20 is reduced. As described above, according to the driving method of the present invention, the problem of image quality deterioration such as color misregistration and streak noise is solved, and good halftone recording can be realized.

FIG. 11 is a block diagram of a main part for explaining the construction of a recording apparatus provided with a print data generating means for carrying out print recording of 64 gradations, 81 is an image data input circuit, and 82 is an image data input circuit. Is a gradation conversion / γ correction circuit, 83 is a shift amount generation circuit, 84 is a print data generation circuit, 85 is a head driver, 86 is a thermal head, and 87 is a recording unit. In the figure, in the gradation conversion / γ correction circuit 82, the image data of 1 to 256 gradations input from the image data input circuit 81 is input.
Data is converted to 64 gradations while correcting the data.

The shift amount generating circuit 83 calculates the shift amount of the recording start timing from the converted n gradations (n is 1 or more and 64 or less) data and the random number r generated by using the microprocessor. . 0/6 for n gradation recording pixels
A value that varies in the range of 4 to (64-n) / 64 is generated.

Next, in the print data generation circuit 84, the print data is obtained from the n gradation data converted by the gradation conversion / γ correction circuit 82 and the shift amount generated by the shift amount generation circuit 83. A certain binary data (63 bits) is generated, the print data is rearranged by the head driver 85, and parallel / serial conversion is performed, and the data is transferred to the thermal head 86 of the recording unit 87 for printing.

The series of processes described above is executed by using a microprocessor for controlling the thermal head, a lookup table using a ROM, or the like. In this embodiment, the deviation of the recording start timing differs depending on each line, each color, and each heating resistor. Therefore, image data at a position where the recording start timing is deviated is required.

Therefore, a method of generating data when performing print recording of 64 gradations will be described. FIG. 12 shows 64
It is a procedure explanatory view of a data generating method when performing gradation print recording, and in this embodiment, since the recording start timing is shifted depending on the number of lines, the heating resistor, and the color,
The current number of lines, heating resistor, and color data are stored in a counter or buffer (step 91). Then, using the current number of lines, heating resistor, and color data, a processing apparatus such as a microprocessor calculates the deviation amount δ of the recording start timing (step 92).

When the deviation amount δ is zero, the printing image data is used as it is. The image data for printing at this time is represented by 1 to 256 gradations (step 9).
3). On the other hand, if the shift amount δ is not zero, the image data at the shifted position is generated from the interpolation image data (procedure 94) obtained from the print image data of the adjacent pixels and the shift amount δ (procedure 95). ).

Next, in the gradation conversion and γ correction circuit,
64 while correcting the image data of 1 to 256 gradations by γ correction
Convert to gradation (procedure 96). Next, in the print data generating circuit, binary data (6) for the thermal head is calculated from the converted n gradation data and the calculated shift amount δ.
3 bits) are generated (procedure 97), data rearrangement, parallel / serial conversion, and the like are further performed, and transferred to the thermal head for printing (procedure 98).

A series of these processes can be performed by a look-up table using a thermal head control microprocessor or ROM. Next, FIG. 13 shows how to obtain the image data at the above-mentioned shifted position.
~ It demonstrates using FIG. The above-mentioned method of obtaining image data is based on, for example, the method shown in FIG.
The following four methods can be used as shown in 3-16.

The first method is, as shown in FIG. 13, the image data at the position shifted by using linear interpolation from the printing image data of two pixels in the sub-scanning direction closest to the shifted position and the shift amount δ. Is generated. In FIG. 13, the pixel of interest is indicated by a thick solid line, and the shifted position is indicated by a point cloud. At this time, the image data D at the shifted position is obtained from the printing image data D11 and D21 (indicated by diagonal lines) of the two pixels in the sub-scanning direction that are closest to the shifted position and the shift amount δ. be able to.

In the second method, as shown in FIG. 14, as the interpolation image data, not only the sub-scanning direction but also the printing image data D0 of four neighboring pixels including the main scanning direction.
It can be obtained from 1, D10, D11, D12, D21 (shown by diagonal lines) and the shift amount δ. Also,
As shown in FIG. 15, the third method uses, as interpolation image data, printing image data D00, D01, D01 of pixels in eight neighboring pixels including the main scanning direction as well as the sub-scanning direction.
It can be obtained from D10, D11, D12, D20, D21, D22 (shown by diagonal lines) and the shift amount δ.

The fourth method is to use one image data of one of the pixels adjacent in the sub-scanning direction as the image data for interpolation as shown in FIG. In FIG. 16, when the pixel of interest is indicated by a thick solid line and the displaced position is indicated by a point group, for example, in the case of (a), the amount of displacement is less than half of one pixel, so there is displacement. The thick solid line image data (indicated by diagonal lines) is used as it is as the image data of the position, and in the case of (b), since the amount of deviation is more than half of one pixel, it is adjacent as the image data of the displaced position. The image data (shown by diagonal lines) of the pixels to be used is used.

In the case of a pictorial image, this is
This is because a shift of about half of one pixel can be ignored macroscopically, can be sufficiently reproduced by either one of the image data, and no correction is required. Therefore, according to the present invention,
The problem of deterioration of image quality due to color misregistration is solved by making the overlapping of printed dots recorded by each heating resistor different, and the streak noise is reduced by shifting the angle of the line formed for each color. Therefore, a good halftone image can be obtained.

However, when there are fine lines or characters in the main scanning direction in the input data, the fine lines or characters have irregularities, which causes a problem of reproducibility. Therefore, it is possible to improve the reproducibility of thin lines and characters by adding a thin line and character detection algorithm to the print data generation circuit, indicating thin lines and characters when detecting thin lines and characters, and setting the same dot recording start timing. it can.

As the thin line or character detection algorithm, it is possible to use, for example, detection of the case where the same gradation data continues for a set bit or more in the main scanning direction. FIG. 17 shows a processing block diagram in the case where the input data includes thin lines and characters in the main scanning direction. FIG. 17 is a block diagram of a principal part for explaining the configuration of another recording apparatus according to the present invention which is provided with a print data generating means for performing print recording of 64 gradations, and the same reference numerals as those in FIG. Corresponding to the part, 8
3'is a shift amount generation control circuit, and 88 is a fine line / character detection circuit.

When the image to be printed is a thin line or a character, if the printing position is displaced in the sub-scanning direction, the reproducibility in the main scanning direction is deteriorated and the print quality is deteriorated. In order to prevent this, in the embodiment shown in the figure, when the input image data includes a thin line or a character, the thin line / character detection circuit 88 detects this and the deviation amount generation control circuit 83 is detected. 'Is given a signal with a displacement amount of "zero".

When the deviation amount generation control circuit 83 'receives the deviation amount zero signal from the thin line / character detection circuit 88, the deviation amount generation operation is stopped, and the gradation data from the gradation conversion / γ correction circuit 82 remains unchanged. It is given to the print data generation circuit 84.
The thin line / character detection circuit 88 has a thin line / character detection algorithm for detecting a thin line when the same gradation data continues for more than a predetermined number of bits in the main scanning direction. Shift amount generation control circuit 8 as zero signal
3'is provided.

According to this embodiment, the print dots recorded by the heating resistors constituting each unit heating area are recorded at any position within the width of one pixel in the sub-scanning direction, and halftone recording is performed. Even if each print dot is not connected continuously in a straight line and a line in the main scanning direction is not generated, a good halftone image can be obtained, and if there are fine lines or characters in the main scanning direction in the input data. When the thin line or the character is detected, the recording start timings of the dots indicating the thin line or the character can be set to be the same to improve the reproducibility of the thin line or the character.

As described above, according to the present invention, good image quality can be obtained not only for halftone images but also for images containing characters and fine lines. The thin line / character detection circuit is not limited to the one provided in the subsequent stage of the gradation / γ correction circuit 82 as in the above-described embodiment, and the thin line / character detection algorithm execution means is added to the print data generation circuit 84 as an additional function. Other methods such as

Further, the method of varying the position of each heating resistor in the sub-scanning direction is not limited to the method described in each of the above embodiments, random numbers are not used, and adjacent heating resistors are not used. Appropriate rules may be provided such that the amount of shift in the sub-scanning direction is different. Further, in the case of 300 DPI of this embodiment, the position of each heating resistor in the sub-scanning direction changes within the range of the width D (about 84.7 μm) in the sub-scanning direction for one pixel. However, when the pixel density is low or depending on the intended use, when the position is changed by the width of one pixel in the sub-scanning direction, the deviation of each print dot in the first line may deteriorate the image quality. In such a case, the position of the heating resistor may be changed within a range smaller than the width of one pixel in the sub-scanning direction.

[0086]

As described above, according to the present invention,
Since the print dots printed by each heating resistor element are recorded at arbitrary positions within the width of one pixel in the sub-scanning direction, the print dots of each line in the main scanning direction may be continuously connected on a straight line. No line is formed in the main scanning direction.

As a result, it is possible to reduce the generation of streak-shaped visual noise in the printed image due to the line formation in the main scanning direction. Further, in the recording of a color image, even if there is no accurate registration between the print colors, the overlapping of the colors in each print dot is arbitrary, so that color misregistration does not occur in the entire image. in this way,
According to the present invention, deterioration of image quality such as streak noise and color misregistration in the main scanning direction is eliminated, and good halftone recording can be realized.

Further, the thermal head according to the present invention can be applied to any thermal recording system, but it is remarkably applied to the melt transfer recording, which has not been capable of multi-gradation expression in the past, especially the color halftone recording. effective. Furthermore, according to the halftone recording method using the strip-shaped heat generating resistor of the present invention, the print dots recorded by each heat generating resistor forming the unit heat generating area are arbitrary within the width of one pixel in the sub-scanning direction. Since it is recorded at the position, the print dots of each line in the main scanning direction are not continuously connected linearly, and line formation in the main scanning direction does not occur.

Therefore, similarly to the above, the streak-shaped visual noise in the printed image due to the line formation in the main scanning direction can be eliminated. Further, in the recording of a color image, even if there is no accurate registration, the overlapping of colors in each print dot is arbitrary, so that the color shift does not occur in the entire image. Furthermore, according to the present invention, by adding a thin line or character detection algorithm, when a thin line or a character is detected, the recording start timing of dots indicating the thin line or the character is made the same, and not only the halftone image is displayed. Thus, it is possible to provide a halftone recording apparatus that can obtain good image quality even in an image including characters and fine lines.

[Brief description of drawings]

FIG. 1 is a plan view of an essential part for explaining one embodiment of a thermal head according to the present invention.

FIG. 2 is a structural cross-sectional view of a thermal head for explaining a method of manufacturing a thermal head according to an embodiment of the present invention.

FIG. 3 is a top view for explaining the manufacturing method of the thermal head according to the first embodiment of the present invention.

FIG. 4 is an explanatory diagram of a printing example in which printing is performed using the thermal head according to the present invention.

FIG. 5 is an explanatory diagram of another embodiment of the halftone recording method according to the present invention, in which (a) is a configuration diagram of a thermal head,
(B) is an explanatory diagram of print dots expressing gradation, and (c) is an explanatory diagram of print timing.

FIG. 6 is an explanatory diagram of a driving method according to the present invention that sets a print start position of a print pixel in a sub-scanning direction to an arbitrary position within a width of one pixel, and (a) is a configuration diagram of a thermal head. , (B) is an explanatory diagram of print dots expressing gradation,
FIG. 7C is an explanatory diagram of print timing.

FIG. 7 is an explanatory diagram of an example of print recording when each pixel has three gradation levels by actually using the driving method according to the present invention.

FIG. 8 is a flowchart illustrating an operation when performing color printing.

FIG. 9 is an explanatory diagram of a printing example using the thermal head according to the present invention.

FIG. 10 is a printing state diagram for explaining color misregistration in the present invention, wherein (a), (b) and (d) are monochrome printing state diagrams, and (c) and (e) are overprinting. It is a printing state figure.

FIG. 11: Print data when performing print recording with 64 gradations
FIG. 3 is a block diagram of an essential part for explaining a configuration of a recording apparatus according to the present invention including a means for generating a data.

FIG. 12 is a procedure explanatory diagram illustrating a data generating method when performing print recording of 64 gradations.

FIG. 13 is a conceptual diagram illustrating a method of selecting interpolation image data.

FIG. 14 is a conceptual diagram illustrating another method for selecting interpolation image data.

FIG. 15 is a conceptual diagram illustrating still another selection method of interpolation image data.

16A and 16B are other conceptual diagrams illustrating a method of selecting interpolation image data, in which FIG. 16A shows a case where the shift amount is within half of one pixel, and FIG. 16B shows a shift amount of more than half of one pixel. Is the case.

FIG. 17: Print data when print recording with 64 gradations
FIG. 11 is a block diagram of a main part for explaining the configuration of another recording apparatus according to the present invention including a data generating unit.

FIG. 18 is a plan view of a heat generating portion of a thermal head according to a conventional technique used for recording in a sub-scanning direction division method.

FIG. 19 is an explanatory diagram of a print recording example when halftone recording is performed using a thermal head according to the related art.

FIG. 20 is a printing state diagram for explaining color misregistration.

[Explanation of symbols]

1 ... Common electrode 1-1 to 1-6 ... Comb-shaped common electrode element 2 ... Selection electrode 3 ... Heating resistor 2-1 to 2-5 ... Comb -Shaped selection electrode element 4 ... Ceramics substrate 5 ... Glass glaze layer 6 ... Conductor film 7 ... Photosensitive resist 8-1 to 8-5 ... Resist opening 9- 1-9-9 ... 1st line print dot 10-1-10-5 ... 2nd line print dot 11-1-11-5 ... 3rd line Print dot 81 ... Image data input circuit 82 ... Gradation conversion / γ correction circuit 83 ... Deviation amount generation circuit 83 '
・ ・ ・ Displacement generation control circuit 84 ・ ・ ・ Print data generation circuit 85 ・ ・ ・ ・ Head driver 86 ・ ・ ・
・ Thermal head 87 ・ ・ ・ ・ Recording unit 88 ・ ・ ・
Fine line / character detection circuit.

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] June 14, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Fig. 10

[Correction method] Change

[Correction content]

FIG. 10 is a printing state diagram for explaining color misregistration in the present invention.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location H04N 1/23 102 B 9186-5C B41J 3/20 115 D

Claims (9)

[Claims] 1. A half-tone recording thermal head having a plurality of heating resistor elements arranged in parallel in a main scanning direction, wherein a width of the heating resistor element of the thermal head in a sub-scanning direction corresponds to one pixel to be printed. A thermal head for halftone recording, which is narrower than a width in the sub-scanning direction, and wherein the positions of the plurality of heating resistor elements in the sub-scanning direction are arbitrarily arranged within a width of one pixel in the sub-scanning direction. 2. A plurality of heating resistor elements are arranged side by side in the main scanning direction, and the width of the heating resistor elements in the sub-scanning direction is narrower than the width of one pixel to be printed in the sub-scanning direction. The halftone recording method, wherein printing is performed using a thermal head in which the position of the heating resistor element in the sub-scanning direction is arbitrarily arranged within the width of one pixel in the sub-scanning direction. 3. A sub-scan of one pixel using a thermal head in which a band-shaped heat-generating resistor whose width in the sub-scanning direction is narrower than the width of one pixel to be printed in the sub-scanning direction is installed in the main-scanning direction. In a halftone recording method in which a print width in a direction is modulated to express a halftone density, a recording start position of one pixel in the subscanning direction is selected and printed at an arbitrary position within a width of one pixel in the subscanning direction. A halftone recording method, characterized by starting the recording. 4. A sub-scan of one pixel by using a thermal head in which a band-shaped heat-generating resistor whose width in the sub-scanning direction is smaller than the width of one pixel to be printed in the sub-scanning direction is installed in the main-scanning direction. In a halftone recording method for modulating color printing width to express halftone densities of three colors of cyan, magenta, and yellow to perform color printing, a recording start position of one pixel of each color in the sub-scanning direction is set to one pixel. A halftone recording method, wherein printing is started by selecting an arbitrary position within a width of a minute in the sub-scanning direction. 5. A sub-scan of one pixel by using a thermal head in which a band-shaped heat-generating resistor whose width in the sub-scanning direction is narrower than the width of one pixel in the sub-scanning direction to be printed is installed in the main-scanning direction. In a halftone recording method in which a print width in a direction is modulated to express halftone densities of three colors of cyan, magenta, and yellow to perform color printing, a recording start position of one pixel of each color in the sub-scanning direction is set to an adjacent pixel And a halftone recording method in which printing is started by shifting a fixed amount within a width of one pixel in the sub-scanning direction, and further changing the amount of deviation of each color. 6. A sub-scan of one pixel by using a thermal head in which a band-shaped heat-generating resistor whose width in the sub-scanning direction is smaller than the width of one pixel to be printed in the sub-scanning direction is installed in the main scanning direction. In a halftone recording method for modulating a print width in a direction to express a halftone density, a recording start position of the one pixel in the subscanning direction is selected at an arbitrary position within a width of one pixel in the subscanning direction. When starting the printing of the dots that make up the pixels and printing the thin lines and characters, make the dot print start positions for printing the thin lines and characters the same between adjacent pixels in the main scanning direction. A halftone recording method characterized by recording. 7. When the printing is the printing of thin lines or characters, the dots are printed at the same print start position for printing the thin lines or characters between adjacent pixels in the main scanning direction. Halftone recording method described in 5. 8. A sub-scanning direction of one pixel using a thermal head in which a band-shaped heat-generating resistor whose width in the sub-scanning direction is narrower than the width of one pixel in the sub-scanning direction to be printed is installed in the main scanning direction. In a halftone recording apparatus that expresses halftone density by modulating the print width of, the image data input means for taking in the image data to be recorded, and the gradation for performing the gamma correction on the taken image data Conversion / γ correction means, deviation amount generation means for generating a printing position deviation amount for arbitrarily setting the printing position of the heating resistor in the sub-scanning direction, and a floor input from the gradation conversion / γ correction means Print data generating means for generating print data from the adjustment data and the displacement amount from the displacement amount generating means, and a head driver for generating a head drive signal for driving the thermal head based on the print data. Consists, halftone recording apparatus characterized in that it is composed of a recording unit provided with the thermal head to perform the printing by a drive signal supplied from the head driver. 9. A sub-scan of one pixel is used by using a thermal head in which a strip-shaped heat-generating resistor whose width in the sub-scanning direction is narrower than width of one pixel to be printed in the sub-scanning direction is installed. In a halftone recording apparatus that expresses halftone density by modulating the print width in the direction, an image data input means for taking in the image data to be recorded, and a step for performing gradation conversion and gamma correction of the taken image data Tone conversion / γ correction means, fine line / character detection means for detecting that the input data to be printed is a fine line or a character, and the printing position of the heating resistor in the sub-scanning direction is arbitrarily set along the main scanning direction. A print position shift amount for setting is generated, and a shift amount generation control unit for setting the print position shift amount to zero when a signal of zero shift amount is generated from the thin line / character detection unit, and the gradation conversion. / Γ correction means From print data generating means for generating print data from the gradation data input from the above and the displacement amount from the displacement amount generating means, and a head driver for generating a head drive signal for driving the thermal head based on the print data. A halftone recording apparatus, comprising: a recording unit including the thermal head configured to execute printing in response to a drive signal supplied from the head driver.