KR100619040B1 - Method and apparatus for adjusting alignment of image forming device - Google Patents

Abstract

The present invention relates to a method and apparatus for adjusting alignment of a first side and a second side of a media in a printing apparatus which prints by applying heat to a first side and a second side of a media using one thermal transfer head. . The method comprises the steps of: (a) printing a first predetermined pattern by applying a heat at a first predetermined intervals by a thermal transfer head on a first side of the media; (b) printing a second predetermined pattern by applying heat to the second side of the media at a second predetermined intervals by the thermal transfer head; (c) detecting a matching print position among the printed first predetermined pattern and the second predetermined pattern; (d) calculating a distance deviation between the print positions of the first and second sides of the media from the detected print positions; And (e) adjusting the printing position of the first and second sides of the media using the calculated distance deviation.

According to the present invention, when printing by applying heat to a first side and a second side of a media using a single thermal transfer head, the first side and the first side from the patterns printed on the first side and the second side of the media, respectively. By detecting the distance deviation of the two-sided printing position and adjusting the printing position using the detected distance deviation, the alignment between both sides of the media can be conveniently and accurately adjusted.

Description

Method and apparatus for adjusting alignment of image forming device

1 is a cross-sectional view showing a general thermal reaction medium.

2 is a perspective view showing the configuration of a printing apparatus using a general thermal transfer head.

3 is a perspective view showing the configuration of a printing apparatus for explaining the operation of the printing apparatus using one thermal transfer head.

4 is a perspective view showing the configuration of a printing apparatus to which the alignment adjustment method according to the present invention is applied.

5 is a block diagram showing the configuration of an alignment adjusting device according to the present invention.

FIG. 6 is a detailed block diagram illustrating an embodiment of the pattern printing unit of FIG. 5.

FIG. 7 is a detailed block diagram illustrating an embodiment of the position detector of FIG. 5.

FIG. 8 is a detailed block diagram illustrating an embodiment of the deviation calculator of FIG. 5.

9 is a flowchart illustrating an alignment adjustment method according to the present invention.

FIG. 10 is a detailed flowchart illustrating an embodiment of printing a pattern on first and second surfaces of the media of FIG. 9.

FIG. 11 is a detailed flowchart showing an embodiment of the step of detecting the coincidence printing position of FIG.

FIG. 12 is a detailed flowchart illustrating an example of calculating the distance deviation of FIG. 9.

FIG. 13 is a diagram for describing an exemplary embodiment of the alignment adjustment method of FIG. 9.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a printing apparatus using a thermal transfer head, and in particular, an alignment of a first side and a second side of a media in a printing apparatus which prints by applying heat to a first side and a second side of a media using one thermal transfer head. It relates to a method and a device for adjusting alignment.

The thermal transfer printing apparatus applies a heat transfer head to an ink ribbon in contact with the media to transfer ink to the media to form an image, or a thermal transfer head on a media on which an ink layer expresses a predetermined color in response to heat. Refers to an apparatus for forming an image by applying heat.

1 illustrates a cross-sectional view of a typical thermal reaction medium. In the illustrated media, ink layers having a predetermined color are formed on both surfaces of the base sheet 11, that is, the first surface 10a and the second surface 10b. Each ink layer is formed of layers of different colors. For example, yellow (Y) and magenta (M) layers are sequentially stacked on the first surface 10a, and cyan (C) layers are formed on the second surface 10b. It is preferable that the said base material 11 is a transparent material. The reflective layer 13 reflects light from the first surface 10a so that a color image is visible.

2 is a perspective view showing the configuration of a printing apparatus using a general thermal transfer head. The illustrated printing apparatus includes a media 200, a driving roller 210, a driven roller 220, a platen roller 230, and a thermal transfer head 240.

The drive roller 210 transfers the media 200 while rotating in engagement with a motor (not shown) which is a driving source, and the driven roller 220 rotates in engagement with the drive roller 210 with the media 200 interposed therebetween. While transferring the media (200).

The thermal head 240 applies heat to the media 200 to be transported to print yellow, magenta, and cyan data. The platen roller 230 faces the thermal transfer head 240 with the media 200 therebetween to support the media 200 so that the ink can be adsorbed, and rotates according to the transfer of the media 200. .

In order to apply heat to the first and second surfaces of the media 200 using one thermal transfer head 240, the thermal transfer head 240 applies heat to one surface of the media 200. Thereafter, the media 200 is rotated to face the second surface of the media 200, or the media 200 is transferred to the thermal transfer head 240 after the first surface is heated.

As described above, when printing by applying heat to both sides of the media using one thermal transfer head, the transfer path difference or printing apparatus when the thermal transfer head is printed on the first side and the second side of the media Due to the mechanical deviation of, the printing position of the first side and the printing position of the second side do not coincide exactly, which causes a problem that the image of the color actually to be printed is not printed on the media.

The technical problem to be achieved by the present invention, in order to solve the above problems in printing using a thermal transfer head, the first and second surfaces from the patterns printed on the first and second surfaces of the media, respectively It is to provide an alignment adjustment method and apparatus that can conveniently and accurately adjust alignment between both sides of a media by detecting a distance deviation of a printing position and adjusting a printing position using the detected distance deviation.

In the alignment adjustment method of the printing apparatus according to the present invention for solving the above technical problem, (a) the heat transfer head is applied to the first surface of the media at a first predetermined intervals to apply a first predetermined pattern Printing; (b) printing a second predetermined pattern by applying heat to the second surface of the media at second predetermined intervals; (c) detecting a matching print position among the printed first predetermined patterns and second predetermined patterns; (d) calculating a distance deviation between the print positions of the first and second surfaces of the media from the detected print positions; And (e) adjusting the printing position of the first and second surfaces of the media using the calculated distance deviation.

Preferably, the step (a) comprises: (a1) detecting the end of the media using an edge detection sensor while transporting the media; (a2) transferring the media by a predetermined distance, and the thermal transfer head applies heat to the first side of the media to print a predetermined image; And (a3) repeating step (a2) a predetermined number of times while increasing the conveying distance of the media.

Step (b) may include: (b1) rotating the thermal transfer head such that the thermal transfer head faces the second surface of the media; (b2) detecting an end of the media using an edge detection sensor while transferring the media; (b3) transferring the media by the predetermined distance and printing the predetermined image by applying heat to the second surface of the media by the thermal transfer head; And (b4) repeating step (b3) a predetermined number of times while increasing the conveying distance of the media.

Preferably, the step (c), (c1) using a sensor, receiving a predetermined pattern printed on the media as an input value; And (c2) comparing the input values to detect a matching print position among the first predetermined pattern and the second predetermined pattern. In the step (c2), it is preferable to detect the black printing position by comparing the input values.

Preferably, step (d) comprises: (d1) calculating a distance between a print start position of the first surface of the media and the detected print position; (d2) calculating a distance between a print start position of the second side of the media and the detected print position; And (d3) calculating a difference between the distance calculated in step (d1) and the distance calculated in step (d2).

An alignment adjusting device of a printing apparatus according to the present invention for solving the above technical problem, the pattern printing unit for printing a first predetermined pattern and a second predetermined pattern on the first and second surfaces of the media, respectively; A position detecting unit detecting a printing position coincident among the first predetermined pattern and the second predetermined pattern; A deviation calculator for calculating a distance deviation between printing positions of the first and second surfaces of the media from the detected printing positions; And an adjusting unit for adjusting a printing position of the first and second surfaces of the media by using the distance deviation.

Preferably, the pattern printing unit, the transfer unit for transferring the media; A thermal transfer head for printing an image by applying heat to first and second surfaces of the media; An edge detection sensor for detecting end portions of the first and second surfaces of the media conveyed by the conveying unit; For each of the first and second surfaces of the media, transferring the media from the end detection position of the media in the printing direction, transferring the media by a predetermined distance, and then applying heat to the media to print a predetermined image, And a print control unit which controls the transfer unit and the thermal transfer head to heat the media a predetermined number of times while printing the first predetermined pattern and the second predetermined pattern while increasing the transfer distance between heating points. The pattern printing unit may further include a position adjusting unit for rotating the thermal transfer head such that the thermal transfer head faces the first and second surfaces of the media.

Preferably, the position detection unit, the sensor for detecting the image printed on the media to output the image data; An A / D converter converting the image data into digital data; And a data comparison unit comparing the values of the digital data to detect a matching print position among the first predetermined pattern and the second predetermined pattern. Preferably, the data comparator detects a black print position by comparing the values of the digital data. Preferably, the sensor is a reflective sensor.

Preferably, the deviation calculator comprises a memory for storing the print position of the media; A memory controller which stores printing positions of the printed first predetermined pattern and second predetermined pattern in the memory; A distance calculator for calculating a distance between the detected print position and the print start position of the first and second surfaces of the media, respectively; And a difference calculator for calculating a difference between the calculated distances.

The alignment adjustment method of the printing apparatus may be embodied as a computer-readable recording medium recording a program for execution on a computer.

Hereinafter, an alignment adjusting method and apparatus of a printing apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a perspective view showing the configuration of a printing apparatus using one thermal transfer head. The illustrated printing apparatus is a platen roller 305, thermal transfer head 310, drive roller 335, driven roller 340, edge detection sensor 345, media guide 350, discharge driven roller 365 , The discharge roller 370, the pickup roller 380, and the media storage unit 390.

A printing apparatus using one thermal transfer head has at least first, second, and third paths and transfers the media 320 through such a transfer path. The pickup roller 380 picks up the media 320 from the media storage unit 390 and transfers the media 320 to the first path.

The second path is an area in which the media 320 is conveyed in the printing reverse direction (B direction) to be located in the printing area, and in the printing direction (F direction) to be heated and printed by the thermal transfer head 310.

The third path is printed after the thermal transfer head 310 applies heat to the first side of the media 320, and then the media 320 is transferred in the reverse printing direction (B direction) to print the second side. Return to 2 paths. In addition, the third path is a path through which the media 320 having completed printing on the first and second surfaces is transferred in the printing direction (F direction) and finally discharged.

It is preferable that a media guide 350 is provided between the first path and the third path, and the media guide 350 controls the media 320 to be transferred from the first path to proceed to the second path, and The media 320 transferred from the second path is controlled to proceed to the third path.

In the second path, image printing is performed by the image printing unit 300. Such image printing may be performed twice or more times as necessary. However, in the present invention, the image printing is performed twice, once for each side of the first and second sides of the media 320.

The position of the thermal transfer head 310 should be determined prior to printing the image on the first and second sides of the media 320. For example, when the image printing is performed on the first side of the media 320, the thermal transfer head 310 is located at a portion D. When the image printing is performed on the second side of the media 320, the thermal transfer head 310 is located. Thermal transfer head 310 should be located in the C portion. In order to change the position of the thermal transfer head 310, the platen roller 305 and the thermal transfer head 310 may be rotated about the rotation axis of the platen roller 305. The change of position of the thermal transfer head 310 may occur when the interference with the media 320 does not occur, for example, before the media 320 is supplied from the first path or with respect to the first surface of the media 320. After the media 320 is transferred to the third path by image printing and before returning to the second path.

When the media 320 on which the image is printed on the first side is transferred in the printing reverse direction from the third path to the second path, image printing on the second side of the media 320 is performed by the rotated thermal transfer head 310. . In the image printing process, the media 320 is gradually transferred in the printing direction by the transfer unit 330, and is discharged through the media discharge unit 360 after image printing on the second surface of the media 320 is completed. .

The edge detection sensor 345 is a sensor for detecting the end of the media 320 to be transferred by the transfer unit 330, it is preferably composed of an optical sensor.

4 is a perspective view illustrating a configuration of a printing apparatus to which an alignment adjustment method according to the present invention is applied. The illustrated printing apparatus includes a thermal transfer head 400, a platen roller 410, a motor 420, a driving roller 430, a driven roller 440, an encoder 450, and an edge detection sensor 460. Is done.

The thermal transfer head 400 applies heat to the media 470 to print an image. The platen roller 410 adsorbs ink to the media 470 using the heat applied from the thermal transfer head 400 and outputs the ink. The driving roller 430 transfers the media 470 in the printing direction and the printing reverse direction by using the motor 420 as a driving source, and the edge detection sensor 460 detects an end of the media 470 so that the media 470 ) Detects the position of The encoder 450 converts the operation of the driving roller 430 into an electrical signal and outputs the electrical signal. The encoder 450 is for measuring the conveying distance or the conveying speed of the media. The encoder 450 is attached to the driven roller 440 or the motor 420 as well as the driving roller 430 so as to follow the driven roller 440 or the motor 420. By converting the operation of the to an electrical signal can be measured the conveying distance or the conveying speed of the media 470.

5 is a block diagram illustrating a configuration of an alignment adjusting device according to the present invention. The illustrated adjusting device includes a pattern printing unit 510, a position detecting unit 520, a deviation calculating unit 530, and an adjusting unit 540. The adjusting device of FIG. 5 will be described in conjunction with a flowchart showing the alignment adjusting method according to the present invention shown in FIG.

The pattern printing unit 510 prints a first predetermined pattern by applying heat to the first surface of the media 470 at predetermined intervals using the thermal transfer head 400 while transferring the media 470. (Step 900).

The pattern printing unit 510 prints a second predetermined pattern by applying heat to the second surface of the media 470 at predetermined intervals using the thermal transfer head 400 while transferring the media 470. (Step 910).

The position detector 520 detects a position in which the print area of the first predetermined pattern and the second predetermined pattern printed on each of the first and second surfaces of the media 470 is identical (step 920). The deviation calculator 530 calculates and outputs a distance deviation between printing positions of the first and second surfaces of the media 470 using the detected position (step 930).

The adjusting unit 540 adjusts the printing position of the first and second surfaces of the media 470 by using the calculated distance deviation between the first and second printing positions of the media 470. (Step 940). For example, if the first side print position is 0.1 millimeters (mm) ahead of the second side print position, the first side print start position of the media 470 may be adjusted by 0.1 millimeter back, or the media ( The alignment can be adjusted by adjusting the printing start position of the second side of 470 to be 0.1 millimeter forward.

FIG. 6 is a detailed block diagram illustrating an embodiment of the pattern printing unit 510 of FIG. 5. The illustrated pattern printing unit 510 includes an edge detection sensor 600, a print control unit 610, a transfer unit 620, and a thermal transfer head 400. 6 will be described in conjunction with a flowchart illustrating a method of pattern printing on each of the first and second surfaces of the media shown in FIG. 10.

Under the control of the print control unit 610, the transfer unit 620 transfers the media 470 in the reverse printing direction, and the edge detection sensor 600 transfers the end of the media 470 transferred by the transfer unit 620. (Step 1000). The edge detection sensor 600 is preferably an optical sensor.

The transfer unit 620 transfers the media 470 by a predetermined distance L in the printing direction from the end detection position of the media 470 under the control of the print control unit 610 (step 1010). The thermal transfer head 400 applies heat to the media 470 to print an image (step 1020).

The print controller 610 increases the transfer distance L by a predetermined value d (step 1030). Under the control of the print control unit 610, the transfer unit 620 transfers the media 470 by the increased distance in the printing direction (step 1040), and the thermal transfer head 400 is transferred to the media 470. The image is printed by applying heat (step 1050).

The print control unit 610 checks whether the pattern printing is completed (step 1060), and repeats the steps 1030 to 1050 until the pattern printing is completed.

When printing predetermined patterns on the first and second surfaces of the media 470 by using the method, a distance for transferring the media 470 in the printing direction from the end detection position of the media 470 in step 1010. (L) is set to be the same for the first surface and the second surface, and the value (d) for increasing the feeding distance L in step 1030 is preferably set differently for the first surface and the second surface. Do.

After the thermal transfer head 400 prints the pattern on the first side of the media 470, the thermal transfer head is formed on the first side and the first side of the media 470 to print the pattern on the second side. It is preferable to further include a position adjusting unit for rotating the thermal transfer head 400 so as to face the two sides.

FIG. 7 illustrates a detailed block diagram of an embodiment of the position detector 520 of FIG. 5. The illustrated position detector 520 includes a sensor 700, an A / D converter 710, and a data comparator 720. The operation of the position detector 520 of FIG. 7 will be described with reference to the flowchart of FIG. 11.

The sensor 700 detects an image printed on the media 470 and outputs the detected image data (step 1100). Preferably, the sensor 700 is a reflective sensor, and it is preferable to simultaneously use the edge detection sensor 600 and the sensor 700 for detecting the image data with one sensor.

The A / D converter 710 converts the image data, which is the detected analog data, into digital data (step 1110), and the data comparator 720 compares the converted digital data values to the media 470. In step 1120, a matching print position is detected among the first predetermined pattern and the second predetermined pattern printed on the first and second surfaces.

When the patterns are printed by setting the same color density based on the data printed on the first side of the media 470 and the color density based on the data printed on the second side, the printing positions coincide with the first side and the second side. Since a black image is formed in the data comparator 720, the data comparator 720 may detect a matching print position by detecting a data value corresponding to black among the converted digital data values. For example, when the yellow (Y) and magenta (M) layers are sequentially formed on the first side of the media 470, and the cyan (C) layer is formed on the second side, the thermal transfer head 400 is formed. When the yellow (Y), magenta (M) and cyan (C) are printed at the same position by setting the respective data so that a black image is formed on the media 470, it is preferable to print the pattern on the media 470. Do.

FIG. 8 is a detailed block diagram of an embodiment of the deviation calculator 530 of FIG. 5. The illustrated deviation calculator 530 includes a memory controller 800, a memory 810, a distance calculator 820, and a difference calculator 830. The operation of the deviation calculator 530 of FIG. 8 will be described with reference to the flowchart shown in FIG. 12.

The memory controller 800 stores the print positions of the first predetermined pattern and the second predetermined pattern printed on the first and second surfaces of the media 470 in the memory 810.

The distance calculator 820 may match a print position of the first and second surfaces of the media 470 detected by the position detector 520 and a first surface of the media 470 stored in the memory 810. In step 1200, the distance d ₁ between the two print positions is calculated as an input of a print start position of the first predetermined pattern printed on the input.

The distance calculator 820 may match a print position of the first and second surfaces of the media 470 detected by the position detector 520 and a second surface of the media 470 stored in the memory 810. In step 1210, the distance d ₂ between the two print positions is calculated as an input of a print start position of the second predetermined pattern printed on the input.

The difference calculator calculates the difference between the calculated distances, that is, the difference between d ₁ and d ₂ , and outputs information on the distance deviation between the print positions of the first and second surfaces of the media 470 in operation 1220. ). For example, if d ₁ is 31.4 millimeters and d ₂ is 31.1 millimeters, the information that the first side print position of the media 470 is ahead of the second side print position by 0.3 millimeters, which is the difference between d ₁ and d ₂ . Output

13 shows an overall embodiment of an alignment adjustment method according to the present invention. In FIG. 13A, the transfer unit 620 transfers the media 470 in the reverse printing direction until the sensor 1300 detects an end portion of the media 470. The thermal transfer head 400 applies heat at predetermined intervals to the first surface of the media 470, which is conveyed in the F direction) to print the first predetermined pattern shown in FIG.

When pattern printing is completed on the first surface of the media 470, the thermal transfer head 400 and the platen roller 410 are rotated such that the thermal transfer head 400 faces the second surface of the media 470. .

In FIG. 13C, the transfer unit 620 transfers the media 470 in the printing reverse direction until the end of the media 470 is detected using the sensor 1300, and then the transfer unit 620 prints the print direction ( The heat transfer head 400 applies heat at predetermined intervals to the second surface of the media 470, which is conveyed in the F direction) to print the second predetermined pattern shown in FIG. When printing the second predetermined pattern, the print start position is set to match the print start position of the first predetermined pattern.

FIG. 13E illustrates an image formed on the media 470 after pattern printing is completed on the first and second surfaces of the media 470. When the position detection unit 520 detects a print position 1300 coinciding with the first and second surfaces, the deviation calculator 530 prints the position 1300 and the start positions of the first and second surfaces. And distance (d ₁ , d ₂ ) is calculated to output the distance deviation (x = d _2- d ₁ ) between the first and second side printing positions.

The invention can also be embodied as computer readable code on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, optical data storage devices, and the like, which are also implemented in the form of carrier waves (for example, transmission over the Internet). Include. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion. And functional programs, codes and code segments for implementing the present invention can be easily inferred by programmers in the art to which the present invention belongs.

Although a preferred embodiment of the present invention has been described in detail above, those skilled in the art to which the present invention pertains can make various changes without departing from the spirit and scope of the invention as defined in the appended claims. It will be appreciated that modifications or variations may be made. Accordingly, modifications to future embodiments of the present invention will not depart from the technology of the present invention.

According to the alignment adjustment method and apparatus of the printing apparatus according to the present invention as described above, the distance deviation between the first surface and the second surface printing position is detected from the patterns printed on the first and second surfaces of the media, respectively. By adjusting the printing position using the detected distance deviation, the alignment between both sides of the media can be conveniently and accurately adjusted.

Claims (14)

In the alignment adjustment method of the printing apparatus using a thermal transfer head for printing by applying heat to the first side and the second side of the media, (a) printing a first predetermined pattern by applying heat to the first surface of the media at first predetermined intervals by the thermal transfer head; (b) printing a second predetermined pattern by applying heat to the second surface of the media at second predetermined intervals; (c) detecting a matching print position among the printed first predetermined patterns and second predetermined patterns; (d) calculating a distance deviation between the print positions of the first and second surfaces of the media from the detected print positions; And (e) adjusting the printing position of the first and second surfaces of the media using the calculated distance deviation. According to claim 1, wherein step (a), (a1) detecting the end of the media using an edge detection sensor while transferring the media; (a2) transferring the media by a predetermined distance, and the thermal transfer head applies heat to the first surface of the media to print a predetermined image; And and (a3) repeating the step (a2) a predetermined number of times while increasing the conveying distance of the media. According to claim 1, wherein step (b), (b1) rotating the thermal transfer head such that the thermal transfer head faces the second side of the media; (b2) detecting an end of the media using an edge detection sensor while transferring the media; (b3) transferring the media by the predetermined distance and printing the predetermined image by applying heat to the second surface of the media by the thermal transfer head; And and (b4) repeating the step (b3) a predetermined number of times while increasing the conveying distance of the media. The method of claim 1, wherein step (c) comprises: (c1) receiving a predetermined pattern printed on the media as an input value using a sensor; And (c2) comparing the input values and detecting a matching print position among the first predetermined pattern and the second predetermined pattern. The method of claim 4, wherein step (c2) comprises: And adjusting a black print position by comparing the input values. The method of claim 1, wherein step (d) (d1) calculating a distance between a print start position of the first surface of the media and the detected print position; (d2) calculating a distance between a print start position of the second side of the media and the detected print position; And and (d3) calculating a difference between the distance calculated in step (d1) and the distance calculated in step (d2). In the alignment adjusting device of a printing apparatus using a thermal transfer head for printing an image by applying heat to the first and second surfaces of the media, A pattern printing unit printing first and second predetermined patterns on the first and second surfaces of the media, respectively; A position detecting unit detecting a printing position coincident among the first predetermined pattern and the second predetermined pattern; A deviation calculator for calculating a distance deviation between printing positions of the first and second surfaces of the media from the detected printing positions; And And an adjusting unit for adjusting a printing position of the first and second surfaces of the media using the distance deviation. The method of claim 7, wherein the pattern printing unit, A transfer unit for transferring the media; A thermal transfer head for printing an image by applying heat to first and second surfaces of the media; An edge detection sensor for detecting end portions of the first and second surfaces of the media conveyed by the conveying unit; And For each of the first and second surfaces of the media, the media is transferred by a predetermined distance while transferring the media from an end detection position of the media, and then heat is applied to the media to print a predetermined image, and between heating points. And a print control unit controlling the transfer unit and the thermal transfer head to heat the media a predetermined number of times while increasing a transfer distance to print the first predetermined pattern and the second predetermined pattern. The method of claim 8, And a position adjusting unit for rotating the thermal transfer head such that the thermal transfer head faces the first and second surfaces of the media. The method of claim 7, wherein the position detection unit, A sensor for detecting an image printed on the media and outputting image data; An A / D converter converting the image data into digital data; And And a data comparing unit comparing the values of the digital data to detect a matching print position among the first predetermined pattern and the second predetermined pattern. The method of claim 10, wherein the data comparison unit, And a black printing position is detected by comparing the values of the digital data. The method of claim 10, wherein the sensor, Alignment adjusting device, characterized in that the reflective sensor. The method of claim 7, wherein the deviation calculator, A memory in which a print position of the media is stored; A memory controller which stores printing positions of patterns printed on the first and second surfaces of the media in the memory; A distance calculator for each of the first and second surfaces of the media, calculating a distance between a print start position stored in the memory and the detected coincident print position; And And a difference calculator configured to calculate and output the calculated difference between the two distances. A computer-readable recording medium having recorded thereon a program for executing the method according to any one of claims 1 to 6.

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