JP5786394B2 - Printing apparatus, printing system, printing method, and program - Google Patents

Description

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

  2. Description of the Related Art Some image forming systems include an image forming apparatus and a DFE (Digital Front End Processor) apparatus, which is a higher-level apparatus that passes print data to the image forming apparatus and gives a print instruction. A DFE device having a drawing function performs, for example, RIP processing (Raster Image Process) for generating a raster image from print data described in a page description language PDL transmitted from a host device, and forms the generated raster image into an image. A system for transferring data to an apparatus is already known (see, for example, Patent Document 1).

  Unlike the image forming apparatus, a printer apparatus including a printer controller, a printer engine, and a data line connecting the printer controller and the printer engine is already known (for example, see Patent Document 2). In this printer device, for the purpose of speeding up data transfer, a control line for exchanging various control information and a data line for exchanging print data are separated to speed up data transfer.

  On the other hand, Patent Document 3 discloses contents relating to a printing apparatus that enables printing at a high resolution for a printing portion that is optically read, such as a barcode or an OCR, among low-resolution print data.

  However, in such a conventional technique, for the low resolution portion, the bitmap data once rasterized at a low resolution and stored in the bitmap memory is converted to a high resolution and stored in another bitmap memory. However, the printing is performed by combining the high resolution portion bitmap data that has been rasterized at a high resolution.

  For this reason, the high resolution bitmap data is finally combined and printed, and therefore, the bitmap memory for converting the resolution of the low resolution data and storing the high resolution bitmap data, and the bit There is a problem that the data composition unit for synthesizing and outputting the map data and the bitmap data of the high resolution portion is necessary, and the apparatus configuration becomes excessive.

  The present invention has been made in view of the above, and it is a main object of the present invention to provide a printing apparatus, a printing system, a printing method, and a program capable of obtaining a high-quality printing result while simplifying the apparatus configuration. And

In order to solve the above-described problems and achieve the object, a printing apparatus according to the present invention is a printing apparatus that is connected by an image generation apparatus, a first transfer path, and a second transfer path. Printing means for printing at one resolution; first data control means for receiving image data of the first resolution from the image generation device via the first transfer path; and an image of a second resolution lower than the first resolution. Second data control means for receiving data from the image generation device via the second transfer path; and receiving the first resolution image data from the first data control means; First image output control means for controlling image data to be printed by the printing means as it is, receiving the second resolution image data from the second data control means, and receiving the received second resolution image data Second image output control means for controlling the printing means to print while converting the image data to one resolution, and the printing means outputs the first resolution image data from the first image output control means. A first printing means for receiving and printing; and a second printing means for receiving and printing the converted image data of the first resolution from the second image output control means. .

A printing system according to the present invention includes an image generation device that generates image data to be printed, and a printing device that is connected to the image generation device through a first transfer path and a second transfer path. The image generation apparatus transmits image data of a first resolution to the printing apparatus via the first transfer path, and image data of a second resolution lower than the first resolution is transmitted to the second transfer path. The printing apparatus transmits the image data at the first resolution, the image data of the first resolution from the image generation apparatus through the first transfer path. First data control means for receiving the second resolution image data, second data control means for receiving the second resolution image data from the image generation device via the second transfer path, and the first data control means for First resolution First image output control means for performing control to receive the image data and print the received first resolution image data as it is with the printing means; and receiving the second resolution image data from the second data control means And second image output control means for controlling the received second resolution image data to be printed by the printing means while converting the second resolution image data to the first resolution image data. First printing means for receiving and printing the first resolution image data from one image output control means, and receiving and printing the converted first resolution image data from the second image output control means. And a second printing means .

According to another aspect of the present invention, there is provided a printing method executed by a printing apparatus connected by an image generating apparatus, a first transfer path, and a second transfer path, wherein the printing means converts the image data to the first resolution. The first data control step in which the first data control means receives the image data of the first resolution via the first transfer path, and the second data control means in accordance with the first resolution. A second data control step for receiving low second resolution image data via the second transfer path; and a first image output control means for receiving the first resolution image data from the first data control means. A first image output control step for controlling the received image data of the first resolution by the printing means as it is, and a second image output control means for receiving the image of the second resolution from the second data control means. Receiving data, wherein the second image output control step of performing control to cause printing by the printing means while converting the image data of the received second resolution image data of the first resolution,
In the printing step, a first printing unit receives the first resolution image data from the first image output control unit and prints it, and a second printing unit controls the second image output control. And a second printing step of receiving and printing the converted image data of the first resolution from the means .

A program according to the present invention is a program for causing a computer connected by an image generating device, a first transfer path, and a second transfer path to execute image data at a first resolution; A first data control step for receiving first resolution image data via the first transfer path; and a second data control step for receiving second resolution image data lower than the first resolution via the second transfer path. A data control step, a first image output control step for controlling the image data of the first resolution received in the first data control step as it is in the printing step, and the received in the second data control step. A second image output control step for controlling the printing in the printing step while converting the image data of the second resolution into the image data of the first resolution. And the printing step prints the first resolution image data after the conversion by the first printing step for printing the first resolution image data and the second image output control step. And causing the computer to execute a second printing step .

  According to the present invention, it is possible to obtain a high-quality printing result while simplifying the apparatus configuration.

FIG. 1 is a diagram illustrating an exemplary configuration of a printing system applicable to the first embodiment. FIG. 2 is a diagram illustrating a configuration of an example of the higher-level device 10. FIG. 3 is a diagram illustrating a functional configuration of the printer apparatus according to the first embodiment. FIG. 4 is a diagram schematically showing an example of the structure of a printer apparatus 200 including a paper transport system that can be applied to the present embodiment. FIG. 5 is a diagram showing an example of a transfer management table applied to this embodiment. FIG. 6 is a diagram illustrating an example of 240 dpi print image data. FIG. 7 shows an example of 600 dpi print image data. FIG. 8 is a flowchart illustrating a printing process procedure performed by the 240 dpi printing mechanism unit 1061. FIG. 9 is a flowchart illustrating a printing process procedure performed by the 600 dpi printing mechanism unit 1062. FIG. 10 is a diagram illustrating a printing result. FIG. 11 is a sequence diagram of an example conceptually showing a printing process applicable to the present embodiment. FIG. 12A is a sequence diagram illustrating an example of print processing applicable to each embodiment more specifically. FIG. 12-2 is a sequence diagram of an example showing more specifically print processing applicable to each embodiment. FIG. 12C is a sequence diagram of an example showing more specifically the printing process applicable to each embodiment. FIG. 13 is a diagram illustrating a functional configuration of the printer device 13 according to the second embodiment.

  Hereinafter, embodiments of a printing apparatus, a printing system, a printing method, and a program according to the present invention will be described in detail with reference to the accompanying drawings.

(Embodiment 1)
Hereinafter, embodiments of a printing apparatus, a printing system, a printing method, and a program according to the present invention will be described in detail with reference to the accompanying drawings.

  First, for easy understanding, production printing to which the printing system according to the present embodiment is applied will be schematically described. In production printing, the basic idea is to perform a large amount of printing in a short time. For this reason, in production printing, in order to speed up printing and efficiently manage jobs and print data, a workflow system that manages from creation of print data to distribution of printed materials is constructed. .

  The printing system according to the present embodiment relates to a part that executes printing in a production printing workflow. RIP (Raster Image Processor) processing and printing of bitmap data obtained by RIP processing are performed by different apparatuses. Do. The RIP process takes the longest processing time in the printing process, and the printing speed can be increased by separating the apparatus that performs the RIP process from the apparatus that performs the printing process.

  FIG. 1 shows an exemplary configuration of a printing system applicable to the present embodiment. This printing system is configured by connecting a host device 10 and a printer device 13 as a printing device by a plurality of data lines 103 and control lines 102. The host device 10 performs RIP processing in accordance with print job data supplied from the host device, and creates bitmap data for each color, which is print image data. At the same time, the upper level apparatus 10 creates control information for controlling the printing operation based on the print job data, host apparatus information, and the like.

  The print image data for each color created by the host device 10 is supplied to a printer engine unit (not shown) of the printer device 13 via a plurality of data lines 11. Control information is transmitted and received between the upper level apparatus 10 and the printer controller 14 via the control line 12. The printer controller 14 controls the printer engine unit based on the transmission / reception of the control information, and executes printing according to the print job.

  Although the printing method is not particularly limited, in the present embodiment, a print image is formed on a printing paper by an inkjet method. Further, as the printing paper, continuous form paper (continuous form) that is continuous paper in which perforable perforations are punched at a predetermined interval is used. In production printing, this continuous paper is often used as printing paper. Needless to say, the present invention is not limited to this, and a cut sheet having a fixed size such as A4 size or B4 size may be used as the printing paper. In the continuous paper, a page refers to an area sandwiched between perforations that are struck at a predetermined interval, for example.

  FIG. 2 shows an exemplary configuration of the host device 10. A CPU (Central Processing Unit) 101, a ROM (Read Only Memory) 102, a RAM (Random Access Memory) 103, and a hard disk drive (HDD) 104 are connected to the bus 100. An external I / F 110, a control information I / F 111, and an image data I / F 112 are further connected to the bus 100. These units connected to the bus 100 can communicate with each other via the bus 100.

  In ROM 102 and HDD 104, a program for operating CPU 101 is stored in advance. The RAM 103 is used as a work memory for the CPU 101. That is, the CPU 101 controls the overall operation of the host device 10 using the RAM 103 as a work memory in accordance with programs stored in the ROM 102 and the HDD 104.

  The external I / F 110 corresponds to, for example, TCP / IP (Transmission Control Protocol / Internet Protocol) and controls communication with the host device. The control information I / F 111 controls communication of control information. The image data I / F 112 controls communication of print image data and has a plurality of channels. For example, the print image data of each color created by the host device 10 with the colors Y (Yellow), C (Cyan), M (Magenta), and K (Black) is output from each of the plurality of channels. Since the image data I / F 112 is required to have a high transfer speed, for example, PCI Express (Peripheral Component Interconnect Bus Express) is used. The method of the control information I / F 111 is not particularly limited, but here, as with the image data I / F 112, PCI Express is used.

  In such a configuration, print job data transmitted from the host device is received by the external I / F 110 of the host device 10 and stored in the HDD 104 via the CPU 101. The CPU 101 performs RIP processing based on the print job data read from the HDD 104, generates bitmap data for each color, and writes it to the RAM 103. For example, the CPU 101 renders PDL (Page Description Language) by RIP processing, generates bitmap data of each color, and writes it to the RAM 103. The CPU 101 compresses and encodes the bitmap data of each color written in the RAM 103 and temporarily stores it in the HDD 104.

  For example, when the printing operation is started in the printer device 13, the CPU 101 reads out the bitmap data of each color compressed and encoded from the HDD 104, decodes the compressed code, and stores the decompressed bitmap data of each color in the RAM 103. Write. Then, the CPU 101 reads out the bitmap data of each color from the RAM 103, outputs it as print image data of each color from each channel of the image data I / F 112, and supplies it to the printer device 13. Further, the CPU 101 transmits / receives control information to / from the printer device 13 via the control information I / F 111 according to the progress of the printing operation.

  The printer device 13 includes a printer controller 105, printing mechanism units 1061 and 1062, and a paper transport control unit 107. The printer controller 105 and the printing mechanism units 106 and 1062 are connected by a printing mechanism unit control line 113. The printer controller 105 and the paper transport control unit 107 are connected by a paper transport control unit control line 114.

  FIG. 3 is a diagram illustrating a functional configuration of the printer apparatus according to the present embodiment. The printer device 13 includes a printer controller 1051 and a printer engine 15. The printer controller 14 is connected to the control line 12 and controls the printing operation by transmitting / receiving control information to / from the host apparatus 10 via the control line 12. The printer engine 15 is connected to a plurality of data lines 11a, 11b, 11c, and 11d, and each color transferred from the host device 10 through the data lines 11a, 11b, 11c, and 11d, respectively, under the control of the printer controller 14. Print processing using the print image data.

  The host device 10 and the printer device 13 are connected to the host I / F control line 102 and the data communication path 103. The upper I / F control line 102 is connected to the printer controller 105, and the data line 103 is connected to the printing mechanism units 1061 and 1062. Of the data lines 103, one is a data line for transferring 240 dpi print data, and the other is a data line for transferring 600 dpi print data.

  The printer controller 1051 includes a CPU 112 and a print control unit 111.

  The printing mechanism unit 1061 includes a 240 dpi data control unit 1081, an image output control unit 1091 and four heads 1101. Similarly, a 600 dpi data control unit 1082, an image output control unit 1092, and a head 1102 are mounted on the printing mechanism unit 1062.

  A memory 1161 and a memory 1162 are mounted inside the 240 dpi data control unit 1081 and the 600 dpi data control unit 1082, respectively.

  The host device 10 performs RIP processing on the print data to create 240 dpi bitmap data with low resolution for characters and other data, and creates 600 dpi high resolution bitmap data for the optically read portion.

  The host device 10 transmits control information regarding the created bitmap to the printer controller 1051 from the host I / F control line 102.

  The host device 10 receives the print image data received from the printer controller 1051 via the data communication path 103, converts the 240 dpi print image data to the 240 dpi data control unit 1081, and the 600 dpi print image data to the 600 dpi data. The data is transferred to the control unit 1082.

  When the printer controller 1051 receives the control information from the upper level device 10, the print controller 111 transfers the print image data to the 240 dpi data controller 1081 and the 600 dpi data controller 1082 via the print mechanism control line 113. The start is notified, and the host I / F control line 102 requests the host device 10 to start the transfer of print image data.

  The print control unit 111 in the printer controller 1051 notifies the paper transport control unit 107 of a paper transport request via the paper transport control unit control line 114.

  The print control unit 111 notifies the data control units 1081 and 1082 and the image output control units 1091 and 1092 of the start of sheet conveyance via the print mechanism unit control line 113.

  The paper conveyance control unit 107 starts conveyance according to the paper conveyance request, and reports the printable state to the print control unit 111.

  The data control units 1081 and 1082 of the printing mechanism units 1061 and 1062 store the transferred print image data in the internal memories 1161 and 1162, respectively.

  The image output control unit 1091 reads 240 dpi print image data stored in the memory 1161 in the 240 dpi data control unit 1081 in accordance with the sheet conveyance, and converts the resolution to the resolution of the head 1101 (600 dpi in this embodiment). However, the image data is output to the head 1101. Similarly, the image output control unit 1092 reads the print image data of 6000 dpi stored in the memory 1162 in the 600 dpi data control unit 1082 in accordance with the paper conveyance, and this is not subjected to resolution conversion. Are output to the head 1102 as they are.

  The head 1101 discharges ink on the paper according to the data sent from the image output control unit 1091 to perform printing. Similarly, the head 1102 discharges ink onto the paper according to the data sent from the image output control unit 1092. By printing, two data can be overprinted.

  FIG. 4 schematically shows an example of the structure of a printer apparatus 200 including a paper transport system applicable to the present embodiment. As described above, in this embodiment, the printer device 200 uses continuous paper as printing paper.

  The printing paper 201 is supplied from the printing paper supply unit 210 to the first transport unit 230 via the power operation box 220. The printing paper 201 is conveyed by the first conveyance unit 230 via a plurality of rollers and the like by the conveyance control of the conveyance control unit 51, and is aligned. To be supplied.

  The printer engine units 240 and 250 perform printing in accordance with the print image data on the printing paper 201 supplied from the first transport unit 230 in the printing unit 241 corresponding to the image output unit 50 described above. The printing paper 201 that has been printed is discharged from the printer engine unit 250 by the conveyance control of the conveyance control unit 51 and is supplied to the second conveyance unit 260. The printed printing paper 201 is transported in a predetermined manner inside the second transport unit 260 and discharged, and is supplied to the cutting unit 270. The printing paper 201 after printing is cut according to the perforation by the cutting unit 270, and each page is separated.

  Here, since the printer apparatus 200 performs printing on the printing paper 201 that is a continuous sheet of continuous pages, the printing paper 201 is printed on the printing paper 201 by the printer engine units 240 and 250, and the printing paper 201 is then transferred to the second transport unit 260. The printing paper 201 is always present in the path from the printer to the paper.

  In addition, another set of configurations including the first transport unit 230, the printer engine units 240 and 250, and the second transport unit 260 is prepared, and the printing paper 201 after printing discharged from the front second transport unit 260 is prepared. Is reversed and supplied to the first conveyance unit 230 on the rear side, whereby double-sided printing on the printing paper 201 becomes possible.

  FIG. 5 shows an example of a transfer management table applied to this embodiment. The transfer management table includes information common to each color of K240 dpi and K600 dpi and information for each color. The information common to each color and the information for each color are information for data transfer used for transferring image data from the host apparatus 10 and information for printing which is information related to a print instruction to the image output control unit 50, respectively. Information.

Information common to each color according to the present embodiment will be described. In the information common to all colors, information other than data transfer and printing includes PBID, a station number indicating the order of the stations 16, and the number of data per page. The PBID is a page identifier for identifying a print page, and the transfer management table is identified by this PBID. As described above, the station number is a value of station identification information set in the identification unit 52 of the station 16, and the values are “1”, “2”, “3”,. And the value “1”. Here, the printer device 13 includes four stations 16 ₁ , 16 ₂ , 16 _3, and 16 ₄ , and the station number takes values “1” to “4”. The number of data per page is the number of colors used for the page identified by the PBID. For example, the value is “1” for monochrome and the value is “4” for full color.

  The information for data transfer in the information common to each color applied to this embodiment includes a data storage destination address, a raster data transfer size, an address update value, and an update count. The data transfer source address indicates an address where the image data of the page indicated by PBID is stored in the upper level device 10. The data storage destination address is an address indicated by the input pointer described above. Therefore, every time the input pointer is updated, the data storage destination address is also updated.

One raster data transfer size indicates the data size of image data for one raster (one line) transferred at the request of the data control unit of each of the stations 16 _{1 to} 16 ₄ . One raster data transfer size includes a boundary adjustment size.

  The address update value is an increment of the address relative to the address when the previous one raster image data was specified when specifying one raster image data to the upper level device 10, and the address is the data size. Is specified by multiplying the raster data transfer size by the number of stations m. In this example where the number of stations m is 4, the address update value = 1 raster data transfer size × 4. The number of updates indicates how many times the address is updated with the address update value within one page, and a value obtained by dividing the image data size for one page (including the boundary adjustment size) by the number of stations m is used. In this example where the number of stations m is 4, the number of updates is equal to the image data size for one page ÷ 4.

  In this embodiment, a resolution is set to indicate the resolution of print image data to be transferred. This resolution is set to either 240 dpi or 600 dpi.

  Information for printing in information common to each color applied to the present embodiment will be described. The information for printing includes resolution and gradation as information of image data to be printed, and information on the print target includes paper feed length, paper width, printing surface (front / back), non-printable area (up / down / left / Right) and image information. The image information includes a bitmap printing position X and a bitmap printing position Y, and an X-direction effective size and a Y-direction effective size.

  In the information of image data to be printed, the resolution indicates the print resolution in each of the main scanning direction and the sub-scanning direction. The gradation indicates the number of bits per pixel.

  The upper, lower, left, and right non-printable areas are the non-printable areas 203 that prohibit printing, the upper end (first in the paper feed direction), the lower end (rear end in the paper feed direction), and the left end (paper feed in the paper width direction). This is indicated by the number of dots from each of the left end in the direction) and the right end (the right end in the paper feed direction in the paper width direction).

  Among the image information, the bitmap printing positions X and Y are dots of the address (coordinates) of the printing start position when the upper left of the page area 202 (the top in the paper feed direction and the left end in the paper width direction) is the origin. Shown in number. In the image information, the effective size in the X direction indicates the size not including the boundary adjustment area 205 in the X direction (paper width direction) by the number of dots. The boundary adjustment area 205 is provided to align the data size to a predetermined unit when the data size of one raster data includes a fraction less than a predetermined unit (for example, byte unit). In addition, the effective size in the Y direction indicates the size in the Y direction (paper feeding direction) by the number of dots. In other words, the X-direction effective size indicates an effective size printed by one raster data, and the Y-direction effective size indicates the number of rasters (lines) printed at the X-direction effective size.

  Information for each color according to the present embodiment will be described. In the information for each color, a color identifier indicating which print color information among K240 dpi and K600 dpi is described as information other than for data transfer and printing. Since the information for each color has a common configuration, the following describes the information with the color identifier “K240 dpi”. The transfer management table includes information for each color for each color of K240 dpi and K600 dpi.

  The information for data transfer in the information for each color applied to the first embodiment includes a data transfer source address, necessity of data transfer, and a transferred flag. The transferred flag indicates whether or not the transfer of the image data for one page of the color identified by the color identifier is completed in the station 16 indicated by the station number. When transfer is completed, the value is set to “ON”.

  The data transfer source address indicates an address where the image data of the page indicated by PBID is stored in the upper level device 10.

  The necessity of data transfer indicates whether or not the image data of the printing color is necessary. For example, when blank paper, that is, when printing is not performed, the data transfer necessity / unnecessity is set to “No” for all colors of K240 dpi and K600 dpi. Further, the data transfer necessity / unnecessity is set to “No” for colors other than those indicated by Color (K240 dpi, K600 dpi).

  The information for printing in the information for each color applied to the first embodiment includes the necessity of printing. The necessity of printing indicates the necessity of printing the image data of the print color. For example, when blank paper, that is, when printing is not performed, “no” is determined as the necessity of printing for all colors of K240 dpi and K600 dpi. Further, for the colors other than those indicated by the Color identifier, the necessity of printing is set to “No”.

  Hereinafter, the printing process of the present embodiment will be described. The host device 10 generates 240 dpi print image data and 600 dpi print image data by RIP processing. FIG. 6 is a diagram illustrating an example of 240 dpi print image data. FIG. 7 shows an example of 600 dpi print image data. In this example, print image data of 240 dpi is generated for characters and ruled lines, and print image data of 600 dpi is generated for barcodes. Then, the upper level apparatus 10 transmits 240 dpi print image data to the print mechanism unit 1061 through the 240 dpi data communication path 103, and transmits 600 dpi print image data to the print mechanism unit 1061 through the 600 dpi data communication path 103. .

  FIG. 8 is a flowchart illustrating a printing process procedure performed by the 240 dpi printing mechanism unit 1061. The data control unit 1081 receives 240 dpi print image data (bitmap data) from the upper level apparatus 10 (step S11) and stores it in the memory 1161. Then, the image output control unit 1091 acquires 240 dpi print image data from the memory 1161 and outputs it to the head 1101 while converting it to a resolution of 600 dpi (step S12). Next, the head 1101 ejects ink from the print image data converted into 600 dpi and prints it on a sheet (step S13).

  FIG. 9 is a flowchart illustrating a printing process procedure performed by the 600 dpi printing mechanism unit 1062. The data control unit 1082 receives 600 dpi print image data (bitmap data) from the host device 10 (step S21) and stores it in the memory 1162. Then, the image output control unit 1092 acquires 600 dpi print image data from the memory 1162, and outputs the print image data to the head 1102 as it is without converting the resolution (step S22). Next, the head 1101 prints 600 dpi print image data by ejecting ink on a sheet on which 240 dpi print image data is printed (step S23). The printed result is as shown in FIG.

  FIG. 11 is a sequence diagram of an example conceptually showing a printing process applicable to the present embodiment. FIG. 12A to FIG. 12C are sequence diagrams of an example showing more specifically print processing applicable to each embodiment.

  As described above, in this embodiment, the control line and the data line between the upper level apparatus 10 and the printer apparatus 13 are separated, the data transfer path 103 is separated for each resolution, and one data control unit 1081, 1082 per resolution. The print image data is output to the heads 1101 and 1102 via the image control output units 1091 and 1092 connected to the data control units 1081 and 1082 of the respective resolutions by data lines. In this embodiment, the low resolution (240 dpi) print image data and the high resolution (600 dpi) print image data are transferred to the individual data control units 1081 and 1082, respectively, and the image output control units 1091 and 1092 are transferred. By unifying the print resolution and outputting to the heads 1101 and 1102, low-resolution print data and high-resolution print data can be combined and printed (overlapping printing). Therefore, in this embodiment, a bitmap memory for storing high resolution data obtained by converting the resolution of low resolution print image data, and the bitmap data and the bitmap data of the high resolution portion are synthesized and output. Therefore, a high-quality printing result can be obtained while simplifying the apparatus configuration without requiring a data synthesizing unit.

(Embodiment 2)
FIG. 13 is a diagram illustrating a functional configuration of the printer device 13 according to the second embodiment. The second embodiment is different from the first embodiment in that the image output control unit 1091 and the head 1101 are shared by 240 dpi print image data and 600 dpi print image data.

  In other words, the image output control unit 1091 according to the present embodiment receives 240 dpi print image data from the 240 dpi data control unit 1081 and outputs the received 240 dpi print image data to the head 1101 while converting the print image data to a resolution of 600 dpi. . On the other hand, the image output control unit 1091 receives 600 dpi print image data from the 600 dpi data control unit 1082 and outputs the received 600 dpi print image data to the head 1101 without converting the resolution. As a result, the same print result as in FIG. 10 described above can be obtained. The functions and configurations of the data control units 1081 and 1082 are the same as those in the first embodiment.

  As described above, in this embodiment, the image output control unit 1091 and the head 1101 are shared by 240 dpi print image data and 600 dpi print image data, so that the apparatus configuration can be simplified and high quality can be achieved. Printing results can be obtained.

(Modification)
In the first and second embodiments, monochrome printing has been described as an example, but the present invention can also be applied to color printing in which black (K) is divided into two types of low resolution and high resolution. .

  In this embodiment, the resolution of the print image data has been described as 240 dpi and 600 dpi, but the resolution is not limited to these.

  Note that a print program executed by the printer apparatus according to the present embodiment is provided by being incorporated in advance in a ROM or the like.

  The printing program executed by the printer apparatus according to the present embodiment is a file in an installable or executable format, such as a CD-ROM, a flexible disk (FD), a CD-R, a DVD (Digital Versatile Disk), or the like. The information may be provided by being recorded on a recording medium that can be read by the user.

  Furthermore, the printing program executed by the printer apparatus of the present embodiment may be provided by being stored on a computer connected to a network such as the Internet and downloaded via the network. The print program executed by the printer apparatus according to the present embodiment may be provided or distributed via a network such as the Internet.

  The print program executed by the printer device of the present embodiment has a module configuration including the above-described units. As actual hardware, a CPU (processor) reads out the print program from the ROM and executes it. Each of the above parts is loaded on the main storage device, and each part is generated on the main storage device.

DESCRIPTION OF SYMBOLS 10 Host apparatus 103 Data line 102 Control line 13 Printer apparatus 1051 Printer controller 1061,1062 Printing mechanism part 22 Print control part 1081,1082 Data control part 1161,1162 Memory 1091,1092 Image output control part 1101,1102 Head 107 Paper conveyance control Part

JP 2004-287519 A JP 2002-254663 A JP 2008-931 A

Claims (6)

A printing apparatus connected by an image generation device, a first transfer path, and a second transfer path,
Printing means for printing image data at a first resolution;
First data control means for receiving first resolution image data from the image generation device via the first transfer path;
Second data control means for receiving image data of a second resolution lower than the first resolution from the image generation device via the second transfer path;
First image output control means for performing control to receive the first resolution image data from the first data control means and to print the received first resolution image data as it is with the printing means;
A second control unit that receives the second resolution image data from the second data control unit and controls the printing unit to print the received second resolution image data while converting the received second resolution image data into the first resolution image data; Image output control means,
The printing means includes
First printing means for receiving and printing the first resolution image data from the first image output control means;
Second printing means for receiving and printing the converted first resolution image data from the second image output control means;
A printing apparatus comprising: The printing apparatus according to claim 1 , wherein the first resolution image data and the second resolution image data are monochrome image data. Through the third transfer path, said first data control means, the image generation apparatus that further comprising a print control section to request the transfer of the image data to each said second data control means The printing apparatus according to claim 1 or 2 . A printing system comprising: an image generating device that generates image data to be printed; and a printing device connected to the image generating device by a first transfer path and a second transfer path,
The image generation device includes:
Transmitting image data of a first resolution to the printing apparatus via the first transfer path, transmitting image data of a second resolution lower than the first resolution to the printing apparatus via the second transfer path,
The printing apparatus includes:
Printing means for printing the image data at the first resolution;
First data control means for receiving the first resolution image data from the image generation device via the first transfer path;
Second data control means for receiving the second resolution image data from the image generation device via the second transfer path;
First image output control means for performing control to receive the first resolution image data from the first data control means and to print the received first resolution image data as it is with the printing means;
A second control unit that receives the second resolution image data from the second data control unit and controls the printing unit to print the received second resolution image data while converting the received second resolution image data into the first resolution image data; Image output control means,
The printing means includes
First printing means for receiving and printing the first resolution image data from the first image output control means;
Second printing means for receiving and printing the converted first resolution image data from the second image output control means;
A printing system comprising: A printing method executed by a printing apparatus connected by an image generation device, a first transfer path, and a second transfer path,
A printing step in which the printing means prints the image data at the first resolution;
A first data control step in which first data control means receives image data of a first resolution via the first transfer path;
A second data control step, wherein the second data control means receives the image data of the second resolution lower than the first resolution via the second transfer path;
The first image output control means receives the first resolution image data from the first data control means, and controls the printing means to print the received first resolution image data as it is. Control steps;
The second image output control unit receives the second resolution image data from the second data control unit, and converts the received second resolution image data into the first resolution image data while the printing unit converts the received second resolution image data to the first resolution image data. A second image output control step for performing control of printing with
The printing step includes
A first printing means for receiving and printing the first resolution image data from the first image output control means;
A second printing step, wherein the second printing means receives and prints the converted first resolution image data from the second image output control means;
A printing method comprising: A program for causing a computer connected by an image generation device, a first transfer path, and a second transfer path,
A printing step for printing image data at a first resolution;
A first data control step of receiving image data of a first resolution via the first transfer path;
A second data control step of receiving image data of a second resolution lower than the first resolution via the second transfer path;
A first image output control step for performing control to print the image data of the first resolution received in the first data control step as it is in the printing step;
A second image output control step for controlling the image data to be printed in the printing step while converting the image data of the second resolution received in the second data control step into the image data of the first resolution; Let
The printing step includes
A first printing step of printing the first resolution image data;
A second printing step of printing the image data of the first resolution after the conversion by the second image output control step;
A program for causing the computer to execute.

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