JP6303692B2 - Printing apparatus, printing method, and program - Google Patents

Description

  The present invention relates to a printing apparatus, a printing method, and a program.

  There is known a printing apparatus that performs time-division driving in which a plurality of heating elements arranged in a line on a thermal head are divided into a plurality of blocks and heat generation is performed by dividing the time for each block. This is because a large amount of power consumption is required to drive the entire heat generating element of the thermal head at the same time, and the voltage applied to each heat generating element is reduced. In addition, when the voltage applied to the heating element is reduced, it causes printing unevenness and printing density.

  However, if time-sharing driving is performed uniformly regardless of the recording width of the recording medium to be printed and the data pattern of the print data, the printing speed may be constant and the printing efficiency may be reduced.

  In order to cope with this problem, Patent Document 1 executes time-division driving on the heating elements of the thermal head for each line printing cycle based on the recording width of the recording medium to be printed and the data pattern of the print data. Disclosed is a technique for determining whether or not.

JP-A-7-323597

  According to Patent Document 1, when a narrow recording medium is used or when print data does not require division, time division driving is not performed on the heating element of the thermal head, so time division driving is uniformly performed. It is possible to increase the printing speed as compared with the case where is executed. However, since the resolution (dot density) of the pattern to be printed along the recording medium feed direction is constant, the printing speed cannot be increased efficiently, and good print quality cannot be obtained. .

  The present invention has been made in view of such a situation, and provides a printing apparatus, a printing method, and a program capable of efficiently increasing the printing speed and obtaining good printing quality. The purpose is to provide.

In order to solve the above object, a printing apparatus according to the present invention includes:
A printing apparatus that prints a pattern based on print data on a recording medium according to resolution,
The resolution, the recording width of the recording medium, and the pattern size of the pattern set by the user, the resolution determination means for determining based on,
Print data dividing means for dividing the print data of the pattern according to the determined resolution into a plurality of line print data printable by a plurality of heating elements;
Based on the divided line print data, the heating element to be heated among the plurality of heating elements is divided into a plurality of blocks, and the pattern is transferred to the recording medium by sequentially generating heat for each of the divided blocks. Printing means for printing;
Conveying means for conveying the recording medium at a conveying speed based on the number of divided blocks;
Comprising
It is characterized by that.

In order to solve the above object, a printing method according to the present invention includes:
A printing method for printing a pattern based on print data on a recording medium according to resolution,
The resolution, the recording width of the recording medium, and the pattern size of the pattern set by the user, and resolution determining step of determining, based on,
A print data dividing step of dividing the print data of the pattern based on the resolution determined in the resolution determining step into a plurality of line print data printable by a plurality of heating elements;
Based on the divided line print data, the heating element to be heated among the plurality of heating elements is divided into a plurality of blocks, and the pattern is transferred to the recording medium by sequentially generating heat for each of the divided blocks. A printing step for printing;
A transport step of transporting the recording medium at a transport speed based on the number of divided blocks;
Comprising
It is characterized by that.

In order to solve the above object, a program according to the present invention provides:
A program for a printing apparatus for printing a pattern based on print data on a recording medium according to resolution,
On the computer,
The resolution, the recording width of the recording medium, and the pattern size of the pattern set by the user, the resolution determination processing of determining, based on,
Print data division processing for dividing the print data of the pattern based on the determined resolution into a plurality of line print data printable by a plurality of heating elements;
Based on the divided line print data, the heating element to be heated among the plurality of heating elements is divided into a plurality of blocks, and the pattern is transferred to the recording medium by sequentially generating heat for each of the divided blocks. Printing process to print,
A transport process for transporting the recording medium at a transport speed based on the number of divided blocks;
To execute,
It is characterized by that.

  According to the present invention, in the printing apparatus, the printing speed can be efficiently increased, and good print quality can be obtained.

It is a top view of the printing apparatus which concerns on Embodiment 1 of this invention. 1 is a perspective view of an internal structure of a printing apparatus and a tape cartridge according to Embodiment 1. FIG. 1 is a block diagram illustrating a configuration of a printing apparatus according to a first embodiment. It is a figure which shows the example of printing which performed the printing process on the conditions from which the resolution along the feed direction of the recording medium of the recording medium of a tape-shaped recording medium and the pattern to print. It is a figure for demonstrating the variable division drive control of the heat generating element of a thermal head. (A) shows a case where a recording medium width of 36 mm is used, and (B) shows a case where a recording medium width of 18 mm is used. 6 is a flowchart illustrating a flow of printing processing executed by the printing apparatus according to the present embodiment. (A) is a flowchart which shows the flow of the resolution determination process. (B) is a flowchart showing the flow of variable division determination processing.

  Hereinafter, a printing apparatus according to an embodiment of the present invention will be described with reference to the drawings. A printing apparatus according to an embodiment of the present invention is an apparatus that prints a pattern including characters, numbers, symbols, and the like on a tape-shaped recording medium using a thermal head.

  As shown in FIGS. 1 and 2, the printing apparatus 100 accommodates an apparatus main body 101 that performs printing processing on a tape-shaped recording medium RM, a tape-shaped recording medium RM, and an ink ribbon IR, and is attached to and detached from the apparatus main body 101. A tape cartridge TC that is freely mounted.

  As shown in FIG. 1, the apparatus main body 101 includes a keyboard 102, a display 103, and an opening / closing lid 104. Although not shown, the apparatus main body 101 also includes an input terminal for connection to an external device such as a personal computer, a power supply terminal to which a power cord is connected, and an insertion port into which a storage medium such as a memory card is inserted. Prepare.

  The keyboard 102 receives key input from the user. The keyboard 102 is a pattern input key for inputting pattern data, a print key for instructing printing start, a cursor key for moving a cursor on the display screen of the display 103, and various function keys for setting a print mode and various setting processes. Consists of.

  The display 103 functions as a main display screen in the printing apparatus 100 and displays an image related to input data, a selection menu for various settings, messages related to various processes, and the like. The display 103 is configured by a liquid crystal display panel, for example. The display 103 may be configured by a combination of an input function and a display function such as a touch panel having a touch switch function.

  The opening / closing lid 104 is a cover that is formed inside the apparatus main body 101 and covers the cartridge housing portion 120 for loading the tape cartridge TC.

  Next, referring to FIG. 2, each configuration of the cartridge storage unit 120 and the tape cartridge TC will be described.

  As shown in FIG. 2, in the apparatus main body 101, a cartridge storage portion 120 for receiving a tape cartridge TC for storing a tape-shaped recording medium RM and an ink ribbon IR is formed in a recessed manner. A tape printing mechanism 121 serving as a printing unit and a cartridge receiving unit 126 for supporting the tape cartridge TC at a predetermined position are formed in the cartridge storage unit 120.

  The tape printing mechanism 121 includes a thermal head 122 in which a plurality of heating elements for heating the ink ribbon IR and the heat-sensitive recording medium are arranged in a line, and a position facing the thermal head 122, so that a tape-like recording is performed. A platen roller 123 that conveys the medium RM and the ink ribbon IR while being sandwiched between the thermal head 122 and a ribbon take-up shaft 124 that takes up the ink ribbon IR used for printing into the tape cartridge TC.

  In addition, a tape outlet 130 that communicates with the outside of the apparatus main body 101 is formed at one end of the cartridge storage unit 120. The tape feed opening 130 includes a full cut mechanism 128 that cuts the printing tape and release tape of the tape-shaped recording medium RM in the width direction, a half-cut mechanism 129 that cuts only the printing tape of the tape-shaped recording medium RM, Is built-in.

  The tape cartridge TC includes a cartridge case 142. The cartridge case 142 has a tape core 143 around which a tape-shaped recording medium RM is wound, a ribbon supply core 144 around which an unused ink ribbon IR is wound, and a ribbon take-up core 145 that winds up a used ink ribbon IR. Is built-in. Further, the cartridge case 142 is formed with a head placement portion 141 where the thermal head 122 is located when the tape cartridge TC is loaded in the cartridge housing portion 120.

  Further, as shown in FIG. 2, engaged portions 146 that are engaged with and supported by the cartridge receiving portion 126 of the cartridge housing portion 120 are formed at the three corner portions of the cartridge case 142. Has been. The engagement portion 146 of the cartridge case 142 is formed with predetermined irregularities corresponding to the type of the tape cartridge TC, although not shown. In addition, a predetermined recording width detection switch 127 that determines the unevenness formed in the engaged portion 146 of the cartridge case 142 when the tape cartridge TC is loaded is disposed in the cartridge receiving portion 126 of the cartridge housing portion 120. ing.

  When the cartridge case TC is loaded in the cartridge storage unit 120, the engaged portion 146 of the cartridge case 142 and some or all of the recording width detection switches 127 arranged in the cartridge receiving unit 126 of the cartridge storage unit 120 are engaged. Match. The recording width detection switch 127 engaged with the engaged portion 146 is pressed. The printing apparatus 100 determines the type of the tape cartridge TC based on the combination of the recording width detection switch 127 that is turned on.

  That is, the printing apparatus 100 can identify the recording width, color, and the like of the tape-shaped recording medium RM stored in each tape cartridge TC by determining the type of the tape cartridge TC. The CPU 151 described later creates print data that conforms to the recording width of the tape-shaped recording medium RM based on these identification data.

  When the execution of printing is instructed by operating the keyboard 102, the tape-shaped recording medium RM and the ink ribbon IR are fed out from the tape core 143 and the ribbon supply core 144 of the tape cartridge TC, respectively. The tape-shaped recording medium RM and the ink ribbon IR are sandwiched and conveyed between them. The platen roller 123 functions as a conveying unit.

  Then, the heat generating element of the thermal head 122 is driven to generate heat based on the print data, and the ink of the ink ribbon IR is thermally transferred to the print tape of the tape-shaped recording medium RM to print the print data. When printing is completed, the full-cut mechanism 128 or the half-cut mechanism 129 is activated depending on the setting, and the tape-like recording medium RM is cut in the width direction to produce one tape-like label.

  Next, functions realized by the printing apparatus 100 will be described with reference to FIG. As shown in FIG. 3, the printing apparatus 100 includes a control unit 150, an input unit 156, a display unit 157, a print control unit 158, a printing unit 159, a motor drive control unit 160, a motor drive unit 161, a recording width detection unit 162, A cutting mechanism 163 and a USB external terminal 164 are provided.

  The control unit 150 includes a CPU (Central Processing Unit) 151, a CGROM (Character Generator Read-Only Memory) 152, an EEPROM (Electrically Erasable Programmable Read-Only Memory) 153, a ROM (Read-Only Memory) 154, and a RAM (Random Access Memory). ) 155.

  The CPU 151 executes an operation program stored in the ROM 154 or the like, and controls the operation of the entire printing apparatus 100. The CPU 151 is connected to each component and exchanges control signals and data.

  The input unit 156 includes, for example, the keyboard 102, receives input operations such as pattern input keys and function keys by the user, and inputs the pattern code, font type, pattern size, and the like of the pattern input by the user to the control unit 150. Supply. Here, the pattern size is the number of points (points: pt) of the font corresponding to the pattern. The input unit 156 functions as a pattern size acquisition unit.

  The CGROM 152 stores font data of patterns that can be printed by the printing apparatus 100. The font data is data in a bitmap format of a pattern to be printed on the printing apparatus 100 or displayed on the display 103. Each dot in the bitmap format corresponds to a heating element of the thermal head 122 or a pixel of the display 103. The CPU 151 acquires the corresponding font data from the CGROM 152 by designating the pattern code, font type, and pattern size of the pattern input by the user, and generates print data and display image data using the acquired font data. To do.

  The EEPROM 153 is a non-volatile memory that stores print data and the like. The ROM 154 is a non-volatile memory that stores an operation program executed by the CPU 151. The RAM 155 is a volatile memory that temporarily stores information generated when the CPU 151 executes various processes and data necessary to generate the information.

  The display unit 157 includes, for example, the display 103 and displays print data and the like on the display 103.

  The print control unit 158 controls the printing unit 159 according to the print data output from the control unit 150, and causes the tape-shaped recording medium RM to execute printing.

  The printing unit 159 includes, for example, a tape cartridge TC, a thermal head 122, and a ribbon take-up shaft 124, and conveys the tape-shaped recording medium RM and the ink ribbon IR according to the control of the printing control unit 158. Printing is performed on the print tape based on the print data supplied from the print control unit 158. Note that the printing unit 159 functions as a printing unit.

  The motor drive control unit 160 includes a tape transport motor that operates in conjunction with the ribbon take-up shaft 124, a cutting motor that operates in conjunction with the half-cut mechanism 129, and the like based on a control signal output from the control unit 150. A drive signal is supplied to the motor drive unit 161 to perform drive control of each motor.

  The recording width detection unit 162 includes, for example, a recording width detection switch 127 and an engaged portion 146, and the unevenness formed on the engaged portion 146 of the tape cartridge TC is a cartridge receiving portion of the cartridge storage unit 120. The type of the tape cartridge TC is discriminated by detection by the recording width detection switch 127 arranged at 126. The recording width detector 162 supplies the controller 150 with the recording width of the tape-shaped recording medium RM corresponding to the determined type of the tape cartridge TC. Note that the recording width detector 162 functions as a recording width detector.

  The cutting mechanism unit 163 includes a tape feed opening 130, a full cut mechanism 128, and a half cut mechanism 129, and cuts the rear end of the tape-like recording medium RM after the printing process to create a tape piece. .

  The USB external terminal 164 is a serial interface for connecting an external device. The USB external terminal 164 can capture print data from the external device or save the print data in the external device.

  Here, with reference to FIG. 4, an example of a printing result obtained by performing printing processing under conditions in which the recording width of the tape-like recording medium RM and the resolution of the pattern to be printed along the recording medium feeding direction are different will be described.

  Conventionally, in product specifications such as label printers, the resolution of the pattern to be printed along the recording medium feed direction is constant. The However, by determining the resolution based on the recording width of the recording medium and the pattern size to be printed, it is possible to improve the printing efficiency and ensure good print quality. The resolution of the pattern to be printed along the recording medium feeding direction is determined by the feeding pitch of the recording medium per strobe pulse.

  As shown in FIG. 4, the resolution of the pattern to be printed along the recording medium feed direction is 200 dpi and 400 dpi, and the pattern “A” is the maximum pattern size that can be printed on a wide 36 mm wide tape-shaped recording medium RM. When the print results obtained by printing "" are compared, there is no significant difference in the print results depending on the resolution. On the other hand, the resolution of the pattern to be printed along the feeding direction of the recording medium is 200 dpi and 400 dpi, and the pattern “A” is printed with the maximum pattern size that can be printed on the narrow 12 mm tape-shaped recording medium RM. When the print results are compared, the curve of the portion A surrounded by the broken-line ellipse is stepped and jagged (jaggy) as compared to the curve of the portion B surrounded by the broken-line ellipse.

  As described above, when the recording width of the tape-like recording medium RM is wide and the pattern size is relatively large, the resolution along the feeding direction of the recording medium of the pattern to be printed is lowered to about 200 dpi. However, there is no problem in print quality. On the other hand, when the recording width of the tape-like recording medium RM is narrow, the pattern size to be printed is inevitably relatively small, so the resolution of the pattern to be printed along the feeding direction of the recording medium is increased to about 400 dpi. It is preferable to do. As described above, in order to obtain good print quality, it is necessary to determine the resolution along the feed direction of the recording medium of the pattern to be printed based on the recording width of the tape-shaped recording medium RM and the pattern size to be printed. .

  Next, with reference to FIG. 5, variable split drive control of the heating elements of the thermal head 122 will be described. The variable division drive control is time division drive control in which the heat generating elements of the thermal head 122 are uniformly divided and driven by a predetermined number of divisions with respect to line print data obtained by dividing the print data into lines that can be printed by the power generation elements. In contrast to this, the control means that the heating element is efficiently driven to generate heat by changing the number of divisions based on the line black dot rate (printing rate). In the variable division drive control, when the total number of print dots (black dots) in the line print data is lower than the maximum number of heat generating elements that can be driven simultaneously, the printing process is performed by collective drive without block division. .

  Here, in the printing apparatus 100, the thermal head 122 has a printing resolution of 384 dots with respect to a tape-shaped recording medium RM having a width of 36 mm, and is simultaneously driven by the maximum number of dots that can be printed at one time, that is, the heating elements. The maximum possible number of dots is assumed to be 96 dots. Therefore, the thermal head 122 performs printing by dividing the heating element into a maximum of four parts on a tape-like recording medium RM having a width of 36 mm. In the printing apparatus 100, the printing speed is normally 20 mm / sec, and the printing speed decreases by 5 mm / sec every time the number of divided heating elements increases by one.

  FIG. 5A shows an example of print data for printing the pattern “calculation” with the maximum pattern size that can be printed on a tape-shaped recording medium having a recording width of 36 mm. As shown in FIG. 5, in the line print data L1 surrounded by a two-dot chain line, the black dot rate (print rate) is low for one line, so there is no need to drive the heating element of the thermal head 122 separately. Since collective driving is possible, printing is possible at a printing speed of 20 mm / sec. On the other hand, in the line print data L2 surrounded by the solid line, since the black dot rate (print rate) is high for one line, it is necessary to divide the heat generating element of the thermal head 122 into four and drive it. Accordingly, the printing speed is reduced to 5 mm / sec.

  FIG. 5B shows an example of print data for printing the pattern “calculation” at points of the maximum pattern size that can be printed on a tape-shaped recording medium having a recording width of 18 mm. As shown in FIG. 6, in the line print data L3 surrounded by a two-dot chain line, the black dot rate (print rate) is low with respect to one line, so that the heating element of the thermal head 122 is the same as in the case of a recording width of 36 mm. Since it is not necessary to divide and drive all together and batch driving is possible, printing can be performed at a printing speed of 20 mm / sec. On the other hand, in the line print data L4 surrounded by the solid line, although the black dot rate (print rate) is high for one line, the recording width is 18 mm which is half of 36 mm. The energization drive may be performed. Therefore, printing is possible at a printing speed of 15 mm / sec.

  As described above, the variable division drive control of the heating element of the thermal head 122 can change the drive division number of the heating element based on the recording width of the tape-shaped recording medium RM and the black dot rate (printing rate) in the line print data. Thus, unlike the time-division drive control in which the drive is divided by a predetermined number of divisions, the printing speed is made variable.

  Next, a printing operation executed by the printing apparatus 100 will be described with reference to the flowchart of the printing process shown in FIG. The CPU 151 performs printing in response to an instruction to execute printing by operating the keyboard print key in a state where the pattern code data corresponding to the pattern string created by operating the keyboard pattern input key is stored in the RAM 155. Execute the process.

  When the printing process is started, the CPU 151 first acquires the recording width of the tape-shaped recording medium RM (step S101). The CPU 151 acquires the recording width of the tape-shaped recording medium RM accommodated in the tape cartridge TC based on the type of the tape cartridge TC detected by the recording width detection switch 127. The CPU 151 stores in advance a correspondence table that associates the type of the tape cartridge TC and the recording width of the tape-shaped recording medium RM in a ROM or the like, and refers to this to determine the recording width of the tape-shaped recording medium RM. Get it. The CPU 151 stores the acquired recording width of the tape-shaped recording medium RM in the RAM 155.

  After executing the process of step S101, the CPU 151 generates print data (step S102). The CPU 151 generates print data based on the pattern code of the pattern sequence data stored in the RAM 155, the dot pattern stored in the CGROM 152, and stores the print data in the RAM 155.

  Subsequently, the CPU 151 executes resolution determination processing (step S103). Here, the resolution determination process will be described with reference to the flowchart shown in FIG. In the resolution determination process, the resolution mode is determined based on the recording width and pattern size of the tape-shaped recording medium RM. The CPU 151 functions as a resolution determination unit.

  When the resolution determination process is started, the CPU 151 first determines whether or not the recording width of the tape-shaped recording medium RM is 18 mm or less as the first recording width (step S111). The CPU 151 reads data relating to the recording width of the tape-shaped recording medium RM stored in the RAM 155 in the process of step S101, and determines whether or not the recording width is 18 mm (first recording width) or less.

  When it is determined that the recording width of the tape-shaped recording medium RM is 18 mm or less (step S111; YES), the CPU 151 sets the resolution mode to the high resolution mode (step S112). That is, the CPU 151 sets the resolution mode to the high resolution mode because the pattern size to be printed is inevitably relatively small when the recording width of the tape-shaped recording medium RM is 18 mm or less.

  On the other hand, when it is determined that the recording width of the tape-shaped recording medium RM is not 18 mm or less (step S111; NO), it is determined whether or not the pattern size is 43 points or less as the first pattern size (step S111). S113). The CPU 151 reads the data indicating the pattern size to be printed stored in the RAM 155, and determines whether or not the pattern size to be printed which is a printing target is 43 points (first pattern size) or less.

  When it is determined that the pattern size is 43 points or less (step S113; YES), the CPU 151 sets the resolution mode to the high resolution mode (step S112). Even if the storage width of the tape-shaped recording medium is wider than 18 mm, the CPU 151 sets the resolution mode to the high resolution mode when the size of the pattern to be printed is relatively small. After executing the process of step S112, the CPU 151 ends the resolution determination process.

  On the other hand, when determining that the pattern size is not 43 points or less (step S113; NO), the CPU 151 sets the resolution mode to the low resolution mode (step S114). When the storage width of the tape-like recording medium is wider than 18 mm and the pattern size to be printed is relatively large, the CPU 151 sets the resolution mode to the low resolution mode. After executing the process of step S114, the CPU 151 ends the resolution determination process.

  Returning to the flowchart shown in FIG. 6, after executing the resolution determination process in step S <b> 103, the CPU 151 divides the print data generated by the process in step S <b> 102 according to the resolution mode set in the resolution determination process. Is generated (step S104). The CPU 151 reads the resolution mode stored in the RAM 155. For example, when the resolution mode is set to the high resolution mode (400 dpi), the CPU 151 generates line print data obtained by dividing the print data into 400 lines per inch, and prints. When the degree mode is set to the low resolution print mode (200 dpi), line print data is generated by dividing the print data into 200 lines per inch. The CPU 151 functions as a print data generation unit and a print data division unit.

  Next, the CPU 151 executes variable division determination processing (step S105). Here, the variable division determination process will be described with reference to the flowchart shown in FIG. The variable division determination process is a process of determining whether or not to separately drive the heat generating elements of the thermal head 122 based on the line print data to be printed. The CPU 151 functions as a division drive unit.

  When the variable division determination process is started, the CPU 151 searches for line print data to be printed from the line print data stored in the RAM 155 (step S121). After reading the line print data to be printed from the RAM 155, the CPU 151 counts the number of print dots (black dots) in the line print data and determines whether it is 97 dots or more (step S122).

  When it is determined that the number of print dots (black dots) in the line print data is 97 dots or more, which is the maximum number of dots that can be printed at once by the thermal head 122 (step S122; YES), the CPU 151 performs time-division drive control. Is determined to be executed (step S123). The CPU 151 divides the heating element into four if the number of printing dots (black dots) in the line print data is 289 dots or more, and divides the heating element into three if it is 193 dots or more and 288 dots or less, 97 dots or more and 192 dots or less. If so, it is determined to execute time-division drive control in which the heating element is divided into two and each block is driven with time divided.

  On the other hand, when it is determined that the number of print dots (black dots) in the line print data is not 97 or more, which is the maximum number of dots that can be printed at once by the thermal head 122 (step S122; NO), the CPU 151 performs time division. It is determined not to execute the drive control (step S124). The CPU 151 determines to print the print dots (black dots) in the line print data by collectively driving the heating elements.

  After executing the process of step S123 or S124, the CPU 151 ends the variable division determination process.

  Returning to the flowchart shown in FIG. 6, the CPU 151 executes the printing process after executing the process of step S105 (step S106). The CPU 151 executes printing for one line of print data according to the resolution mode set in the process of step S103 and the presence / absence of execution of the time-division drive control determined in the process of step S105. Specifically, one line print data is supplied from the CPU 151 to the thermal head 122, and the heating element of the thermal head 122 corresponding to each print dot (black dot) for one line print data is energized to drive the tape. Printing for one line is performed on the recording medium RM.

  After executing the printing process in step S106, the CPU 151 determines whether the print data for all lines has been completed (step S107). The CPU 151 determines whether or not all printing of the line print data generated in the process of step S104 and stored in the RAM 155 has been completed. When it is determined that printing of print data for all lines has not been completed (step S107; NO), the CPU 151 returns the process to step S105 and repeats the processes of steps S105 to S107. On the other hand, if it is determined that printing of the print data for all lines has been completed (step S107; YES), the CPU 151 ends the printing process.

  As described above, the printing apparatus 100 according to the first embodiment determines the resolution of the pattern to be printed along the feeding direction of the recording medium based on the recording width of the tape-shaped recording medium RM and the pattern size to be printed. And determine the printing speed. More specifically, for example, when the recording width of the tape-shaped recording medium RM is 18 mm or less, or the recording width of the tape-shaped recording medium RM is larger than 18 mm, and the pattern size to be printed is 43 points or less. If it is, low-speed printing in the high resolution mode is executed. On the other hand, when the recording width of the tape-shaped recording medium RM is larger than 18 mm and the pattern size to be printed is larger than 43 points, high-speed printing in the low resolution mode is executed. In addition, when the heating element of the thermal head 122 is subjected to variable division control, when low-speed printing is being performed in the high resolution mode, the printing dot (black dot) rate occupying one line print data is low. There is little decrease in printing speed due to. In addition, when high-speed printing in the low resolution mode is being executed, the printing dot (black dot) ratio in one line print data is high, but the decrease in printing speed due to divided driving of the heating elements is small. As described above, when the resolution along the conveyance direction of the recording medium of the pattern to be printed is determined in addition to the variable division control, the printing speed is efficiently increased compared to the case where only the variable division control is executed, Good print quality can be obtained.

  In the above embodiment, in the process of step S123 in the flowchart shown in FIG. 7B, when the heating elements of the thermal head 122 are divided and driven, the number of print dots (black dots) in the line print data is set for convenience. On the basis of this, all the dots in the line print data were uniquely divided into blocks. However, block division may be performed more functionally based on the distribution of print dots (black dots) in the line print data. For example, the positions of the divided blocks may be appropriately moved in accordance with the distribution of print dots (black dots) in the line print data.

  In addition, not only can a configuration for realizing the function according to the present invention be provided in advance as a printing apparatus, but also an existing information device can be caused to function as the printing apparatus according to the present invention by applying a program. it can. That is, a program for realizing each functional configuration by the printing apparatus 100 exemplified in the above embodiment can be controlled by controlling existing information equipment. The control method according to the present invention can be implemented using a printing apparatus.

  Moreover, the application method of such a program is arbitrary. The program can be applied by being stored in a computer-readable recording medium such as a flexible disk, a CD (Compact Disc) -ROM, a DVD (Digital Versatile Disc) -ROM, or a memory card. Furthermore, the program can be superimposed on a carrier wave and applied via a communication medium such as the Internet. For example, the program may be posted on a bulletin board (BBS: Bulletin Board System) on a communication network and distributed. The program may be started and executed in the same manner as other application programs under the control of an OS (Operating System) so that the above-described processing can be executed.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the specific embodiments, and the present invention includes the invention described in the claims and the equivalent scope thereof. included. The invention described in the scope of the claims of the present invention is appended below.

(Appendix 1)
Conveying means for conveying a recording medium on which a pattern is printed in a predetermined conveying direction;
Resolution determining means for determining the resolution of the pattern in the transport direction based on the recording width of the recording medium and the pattern size of the pattern set by the user;
Print data generation means for generating print data of the pattern based on the resolution determined by the resolution determination means;
Printing means for printing the print data generated by the print data generation means on the recording medium;
Comprising
A printing apparatus characterized by that.

(Appendix 2)
The resolution determining unit reduces the resolution along the transport direction of the pattern to a low resolution when the recording width is wider than the first recording width and the pattern size is larger than the first pattern size. In other cases, the resolution in the transport direction is set to a high resolution.
The printing apparatus according to Supplementary Note 1, wherein

(Appendix 3)
The transport unit determines a transport speed of the recording medium based on the resolution determined by the resolution determination unit;
The printing apparatus according to Supplementary Note 1 or 2, characterized in that:

(Appendix 4)
Recording width determining means for determining the recording width of the recording medium;
Pattern size acquisition means for acquiring the pattern size of the pattern set by the user;
Further comprising
The resolution determination unit is configured to determine the resolution of the pattern along the transport direction based on the recording width determined by the recording width determination unit and the pattern size acquired by the pattern size acquisition unit. decide,
The printing apparatus according to any one of appendices 1 to 3, characterized in that:

(Appendix 5)
Print data dividing means for dividing the print data generated by the print data generating means into a plurality of line print data printable by a plurality of heating elements;
Based on the line print data divided by the print data dividing means, the heating element to be heated among the plurality of heating elements is divided into a plurality of blocks, and divided driving is performed so that the divided heating blocks sequentially generate heat. Means,
Further comprising
The transport unit determines a transport speed of the recording medium based on the number of blocks divided by the split drive unit;
The printing apparatus according to any one of appendices 1 to 4, characterized in that:

(Appendix 6)
The recording medium has a tape shape,
The printing apparatus according to any one of supplementary notes 1 to 5, characterized in that:

(Appendix 7)
A transport step of transporting a recording medium on which a pattern is printed in a predetermined transport direction;
A resolution determining step for determining a resolution along the transport direction of the pattern based on a recording width of the recording medium and a pattern size of the pattern set by a user;
A print data generation step for generating print data of the pattern based on the resolution determined in the resolution determination step;
A printing step of printing the print data generated in the print data generation step on the recording medium;
Comprising
A printing method characterized by the above.

(Appendix 8)
On the computer,
A transport process for transporting a recording medium on which a pattern is printed in a predetermined transport direction;
Resolution determination processing for determining the resolution along the transport direction of the pattern based on the recording width of the recording medium and the pattern size of the pattern set by the user;
Print data generation processing for generating print data of the pattern based on the resolution determined in the resolution determination processing;
A print process for printing the print data generated in the print data generation process on the recording medium;
To execute,
A program characterized by that.

DESCRIPTION OF SYMBOLS 100 ... Printing apparatus, 101 ... Main body, 102 ... Keyboard, 103 ... Display, 104 ... Opening / closing lid, 120 ... Cartridge storage part, 121 ... Tape printing mechanism, 122 ... Thermal head, 123 ... Platen roller, 124 ... Ribbon winding Shaft 125, support shaft, 126 cartridge receiving portion, 127 recording width detection switch, 128 full cut mechanism, 129 half cut mechanism, 130 tape feed outlet, 141 head placement portion, 142 cartridge case, 143 ... Tape core, 144 ... Ribbon supply core, 145 ... Ribbon take-up core, 146 ... Engaged part, 150 ... Control part, 151 ... CPU, 152 ... CGROM, 153 ... EEPROM, 154 ... ROM, 155 ... RAM, 156 ... Input unit, 157... Display unit, 158... Print control unit, 159. DESCRIPTION OF SYMBOLS 160 ... Motor drive control part 161 ... Motor drive part 162 ... Recording width | variety detection part, 163 ... Cutting | disconnection mechanism part, 164 ... USB external terminal, A, B ... The part enclosed by the ellipse of the broken line, IR ... Ink ribbon, L1, L2, L3, L4 ... line print data, RM ... tape-like recording medium, TC ... tape cartridge

Claims (7)

A printing apparatus that prints a pattern based on print data on a recording medium according to resolution,
The resolution, the recording width of the recording medium, and the pattern size of the pattern set by the user, the resolution determination means for determining based on,
Print data dividing means for dividing the print data of the pattern according to the determined resolution into a plurality of line print data printable by a plurality of heating elements;
Based on the divided line print data, the heating element to be heated among the plurality of heating elements is divided into a plurality of blocks, and the pattern is transferred to the recording medium by sequentially generating heat for each of the divided blocks. Printing means for printing;
Conveying means for conveying the recording medium at a conveying speed based on the number of divided blocks;
Comprising
A printing apparatus characterized by that. Said resolution determination means, wherein the recording width is wider than the first recording width, and, when the pattern size is larger than the first pattern size, the pre SL resolution as a low resolution, otherwise, the The resolution is higher than the low resolution ,
The printing apparatus according to claim 1. If the resolution determining means determines that the recording width is not wider than the first recording width, the resolution determining means determines the resolution to the high resolution without acquiring the pattern size.
The printing apparatus according to claim 2. The transport unit determines a transport speed of the recording medium based on the resolution determined by the resolution determination unit;
The printing apparatus according to claim 1, wherein the printing apparatus is a printer. Recording width determining means for determining the recording width of the recording medium;
Pattern size acquisition means for acquiring the pattern size of the pattern set by the user;
In addition Ru equipped with,
The printing apparatus according to claim 1, wherein the printing apparatus is a printer. A printing method for printing a pattern based on print data on a recording medium according to resolution,
The resolution, the recording width of the recording medium, and the pattern size of the pattern set by the user, and resolution determining step of determining, based on,
A print data dividing step of dividing the print data of the pattern based on the resolution determined in the resolution determining step into a plurality of line print data printable by a plurality of heating elements;
Based on the divided line print data, the heating element to be heated among the plurality of heating elements is divided into a plurality of blocks, and the pattern is transferred to the recording medium by sequentially generating heat for each of the divided blocks. A printing step for printing;
A transport step of transporting the recording medium at a transport speed based on the number of divided blocks;
Comprising
A printing method characterized by the above. A program for a printing apparatus for printing a pattern based on print data on a recording medium according to resolution,
On the computer,
The resolution, the recording width of the recording medium, and the pattern size of the pattern set by the user, the resolution determination processing of determining, based on,
Print data division processing for dividing the print data of the pattern based on the determined resolution into a plurality of line print data printable by a plurality of heating elements;
Based on the divided line print data, the heating element to be heated among the plurality of heating elements is divided into a plurality of blocks, and the pattern is transferred to the recording medium by sequentially generating heat for each of the divided blocks. Printing process to print,
A transport process for transporting the recording medium at a transport speed based on the number of divided blocks;
To execute,
A program characterized by that.

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