Patent Publication Number: US-6712450-B2

Title: Ink jet printer

Description:
This application is a continuation of international application PCT/JP99/06512 filed on Nov. 22, 1999. 
    
    
     TECHNICAL FIELD 
     The present invention relates generally to an ink jet printer having a color head and a monochrome head, and more particularly to an ink jet printer that is switchable, during a single scanning operation, between a color printing mode by the color head and a monochrome printing mode by the monochrome head. 
     BACKGROUND ART 
     Up until now, a print head of an ink jet type includes a nozzle, a pressure chamber, an ink supply system, an ink tank and a piezoelectric element, and records characters or images on a recording medium, like paper, etc., allowing ink particles to be injected from the nozzle, after transmitting the displacement and pressure generated at the piezoelectric element to the pressure chamber. 
     FIG. 1 is a block diagram of the conventional ink jet printer. The ink jet printer comprises a control unit  200  and a head carrier  202 . To the control unit  200 , a CPU  206  to control the whole, a memory  208 , an interface  210  to connect to a host  204 , a controller  212 , an image memory  214 , a mechanical driver  216  to drive a mechanism  218 , and a drive waveform generation unit  220  are installed. To the head carrier  202 , a color head drive unit  222 , a monochrome head drive unit  224 , a color head  226 , and a monochrome head  228  are mounted. The monochrome or color image data sent from the host computer  204  to the control unit  200  is processed by the CPU  206  and written into the image memory  214 . Of these image data, the color image data is split into color components, Y, M and C, and written into the image memory  214 . When printing documents, etc. in the monochrome mode, the controller  212  sequentially reads monochrome data (K) from the image memory  214 , corresponding to the nozzle layout of the head, and supplies the data to the monochrome head drive unit  222 . As drive waveform data is already written in a waveform memory located in the controller  212  as monochrome drive waveform data, and the drive waveform data is continuously outputted to the drive waveform generation unit  220 , and supplied to the monochrome head drive unit  224 , after being converted into analog drive waveform. The monochrome data from the controller  212  is used to select drive waveform at the monochrome head drive unit  224 , and the selected drive waveform is supplied to the monochrome head  228 , so that the printer records characters or images on a record medium like the paper, etc., as the piezoelectric element drives ink particles to be injected from the nozzle. 
     Also, when printing color images, like photos or graphics, the conventional ink jet printer supplies a group of drive waveforms consisting of a plurality of drive waveforms corresponding to the number of intensities from the drive waveform generation unit  220  to the color head drive unit, based on the color waveform data written in a waveform memory of the controller, and further supplies them to the color head  26 , after selecting waveform of intensities corresponding to the individual color data of Y, M, and C, to print multi-intensity color image. On the other hand, when printing binary images, like monochrome characters or line-drawings, the conventional printer supplies a group of drive waveforms with improved degree of resolution to obtain sharp image, in short, it supplies drive waveforms having higher frequency than in the case of color images, so as to upgrade resolution. 
     However, in the ink jet printer, in which the monochrome printing and the color printing share the use of the conventional drive waveform generation unit  220 , if the printer must print the document  230  as shown in FIG. 2, in which the color photo  232  is inserted in the monochrome text  234 , the printer cannot print the monochrome text  234  and the color photo  232  simultaneously, by performing only a single head scanning. Therefore, the printer traditionally prints the monochrome text  234  while the monochrome head  28  is scanning once, as setting high resolution for monochrome scanning, and then, it prints the remaining color photo  234  with the color head  226 , in the same scanning position, after shifting to multi-intensity color scanning. Because of this, if monochrome text and color photo is intermingled while the head is scanning one stroke, the printer must divide scanning into two modes, multi-intensity color scanning and high-resolution monochrome scanning modes, thereby resulting in a problem that the printing speed can be reduced by half. 
     DISCLOSURE OF THE INVENTION 
     According to the ink jet printer of the present invention there is provided an ink jet printer that can print by a single scanning operation, even if monochrome images and color images are intermingled, to speed up the printing speed. 
     The present invention is directed to an ink jet printer comprising a color head having a plurality of nozzles arranged on a head carrier, each of the plurality of nozzles injecting color ink particles by the drive of a piezoelectric element; and a monochrome head having a plurality of nozzles arranged the head carrier, each of the plurality of nozzles injecting monochrome ink particles by the drive of a piezoelectric element; wherein the ink jet printer comprises a control unit which, within a single scanning of the head carrier, switches the printing mode between a color printing mode by the color head and a monochrome printing mode by the monochrome head, to thereby provide a control of printing. As described above, the ink jet printer in accordance with the present invention will be able to make simultaneous printing with high speed, switching between color image and monochrome image within a single scanning of the head carrier. 
     The control unit of the ink jet printer includes a color drive waveform generation unit which simultaneously generates a group of color drive waveforms representative of at least two types of color dots; a monochrome drive waveform generation unit which simultaneously generates a group of monochrome drive waveforms representative of at least two types of monochrome dots; a color data output unit which outputs color data for a single scanning from a color image, in synchronism with a single scanning of the head carrier; a monochrome data output unit which outputs monochrome data for a single scanning from a monochrome image, in synchronism with a single scanning of the head carrier; a color head drive unit which selects one waveform from the group of color drive waveforms, based on the color data, the color head drive unit supplying the selected one waveform to the piezoelectric element of the color head for the drive thereof; and a monochrome head drive unit which selects one waveform from the group of monochrome drive waveforms, based on the monochrome data, the monochrome head drive unit supplying the selected one waveform to the piezoelectric element of the monochrome head for the drive thereof. By virtue of this configuration of the control unit, in cases where color data and monochrome data are intermingled in the printing data for a single scanning of the head carrier, the control unit can select the color head drive waveform in response to the color data during the single scanning, and select the monochrome waveform drive signal in response to the monochrome data, to thereby provide a switching between the color printing mode and the monochrome printing mode. The color printing mode of the control unit is a multivalued intensity mode, and the monochrome printing mode of the control unit is a high-resolution mode in which the resolution of the monochrome head is integer times the resolution of the color head. As described above, the printer can ensure high quality image printing, as well as high-speed printing, as a result of setting the color printing mode to multivalued intensity mode, and the monochrome printing mode to high-resolution mode, even if color image including a full-color picture, etc., and monochrome image including line-drawing, etc. are intermingled. In the multivalued intensity mode of the control unit, the amount of ink particles of the color head is variable for each nozzle. The high resolution mode of the control unit can employ any one form of the followings for example. 
     (1) the resolution in the horizontal scanning direction of the monochrome head is integer times the resolution of the color head; 
     (2) the ink injection cycle of the monochrome head is integer times the ink injection cycle of the color head; 
     (3) a multiple of the ink injection cycle of the monochrome head relative to the ink injection cycle of the color head is equal to a multiple of the resolution in the vertical scanning direction of the monochrome head relative to the resolution in the vertical scanning direction of the color head; 
     (4) the resolution in the vertical scanning direction of the monochrome head is integer times the resolution in the vertical scanning direction of the color head; 
     (5) the number of nozzle lines of the monochrome head is integer times the number of nozzles lines for each color of the color head; and 
     (6) a multiple of the number of nozzle lines of the monochrome head relative to the number of nozzle lines for each color of the color head is equal to a multiple of the resolution of the monochrome head relative to the resolution of the color head in the horizontal scanning direction. 
     A basic drive frequency of a group of color drive waveforms generated by the color drive waveform generation unit is equal to a basic drive frequency of a group of monochrome drive waveforms generated by the monochrome drive waveform generation unit. In this case, at least one intensity waveform of the group of the monochrome drive waveforms is a drive waveform that allows ink particles to be injected twice or more during a single injection cycle of the group of the color drive waveforms. The color data supplied to the color head drive unit, and the monochrome data supplied to the monochrome head drive unit are a set of pixel data containing a plurality of bits, and the bit data of color pixels contains information representing ink particle diameters by the color drive waveform, while the bit data of monochrome pixels contains information representing dot positions by the monochrome drive waveform. The color head drive unit and the monochrome head drive unit include for each piezoelectric element an analog multiplexer of multi-input/single output which inputs a plurality of drive waveforms and selects any one waveform or does not perform selection at all, depending on the pixel data bit. The color drive waveform generation unit generates at least two types of color drive waveforms for different ink particle diameters, and the monochrome drive waveform generation unit generates at least two types of monochrome drive waveforms that can drive injection once or a plurality of times within a single monochrome cycle. For instance, the color drive waveform generation unit generates color drive waveforms for different ink particle diameters, such as large, medium, and small diameters. The monochrome drive waveform generation unit generates monochrome drive waveforms for all dot patterns with different positions, such as front, rear, and both front and rear positions. Common head control signals, including clock, shift, etc., are supplied both to the color head drive unit and the monochrome head drive unit. The color head drive unit and the monochrome head drive unit are mounted on the head carrier. The color drive waveform generation unit and the monochrome drive waveform generation unit include a waveform memory storing the group of drive waveform data, and an AD conversion unit which converts the group of drive waveform data simultaneously read out of the waveform memory, into analog waveforms. 
    
    
     BRIEF DESCRIPTION OF DRAWINGS 
     FIG. 1 is a block diagram of the conventional ink jet printer; 
     FIG. 2 describes printing document containing a color photo in a monochrome text; 
     FIG. 3 illustrates the appearance of the ink jet printer in accordance with the present invention; 
     FIG. 4 illustrates the internal structure of FIG. 3; 
     FIGS. 5A and 5B are block diagrams of the ink jet printer in accordance with the present invention; 
     FIG. 6 illustrates the nozzle layouts of a color head and a monochrome head shown in FIGS. 5A and 5B; 
     FIG. 7 illustrates a head piezoelectric element shown in FIGS. 5A and 5B; 
     FIG. 8 illustrates the printing mode when color data and monochrome data are intermingled in a single scanning; 
     FIG. 9 is a block diagram of a controller shown in FIGS. 5A and 5B; 
     FIG. 10 shows a flowchart of image memory writing processing by the control unit shown in FIGS. 5A and 5B; 
     FIGS. 11A and 11B show circuit block diagrams of a color drive waveform generation unit and a monochrome drive waveform generation unit shown in FIGS. 5A and 5B; 
     FIGS. 12A to  12 P illustrate color dot and monochrome dot corresponding to the color drive waveform, monochrome drive waveform and individual drive waveform; 
     FIGS. 13A and 13B show circuit block diagrams of a color head drive unit and a monochrome head drive unit shown in FIGS. 5A and 5B; 
     FIGS. 14A to  14 C show a time chart for shift, latch and drive waveform output as to Y data; 
     FIGS. 15A to  15 C show a timing chart for the Y data, clock and latch, against the nozzle row of the Y head shown in FIG. 6; 
     FIG. 16 illustrates a logic chart of drive waveform selection by 2-bit pixel data; 
     FIGS. 17A to  17 N show time charts of data, clock and latch corresponding to the nozzle row of each head shown in FIG. 6; 
     FIG. 18 illustrates nozzle layouts for another color head and monochrome head to be used by the present invention; and 
     FIGS. 19A and 19B illustrate the comparison of dot layouts for UCR processing to replace the gray area in a color image with monochrome, as to the heads shown in FIGS.  6  and  18 . 
    
    
     BEST MODE FOR CARRYING OUT THE INVENTION 
     FIG. 3 shows an ink jet printer in accordance with the present invention. In FIG. 3, the ink jet printer  10  has a paper insertion guide  12  and a paper ejection guide  26 . The paper insertion guide  12  is a guide to insert the not-printed paper into the printer. The paper ejection guide  26  holds the ejected paper. 
     FIG. 4 shows the internal structure of the ink jet printer  10  shown in FIG.  3 . The paper held by the paper insertion guide  12  is picked up by a pick-up roller  14 , and guided by a sheet guide  16 . A sheet push roller  21  in front of a head  28  pushes the paper fed by the sheet guide  16 . The paper printed by the head  28  is fed toward the rear by a feed roller  22 , and at this time, the paper gets caught between a sheet push roller  24  and the feed roller  22 . The ink jet head  28  is installed with its nozzle face  30  facing down. Also, the ink jet head  28  travels along a shaft  32  that can be extended in the direction of depth as viewed from the illustration. A cleaning mechanism  20  cleans the nozzle face  30  of the ink jet head  28 . The cleaning mechanism  20  is installed to the outside of the ink jet head  28  and to the underside of the nozzle face  30  of the ink jet head  28 . 
     FIGS. 5A and 5B are block diagrams showing functions of a control unit and a head carrier of the ink jet printer in accordance with the present invention. The ink jet printer in accordance with the present invention comprises a control unit  34  and a head carrier  36 . To the control unit  34 , a CPU  40  to control the whole of the printing movement, a memory  42 , an interface  44  to connect a host computer  38 , a controller  46  to be installed as a control logic, an image memory  48 , a mechanical driver  50  to drive a mechanism  52  including the structure shown in FIG. 4, and further a color drive waveform generation unit  54  to generate a color drive waveform signal to be supplied to a color head, and a monochrome drive waveform generation unit  56  to generate a monochrome drive waveform signal to be supplied to a monochrome head are installed. Also, to the head carrier  36 , a color head drive unit  58 , a monochrome drive unit  60 , a color head  62  and a monochrome head  64  are mounted. 
     FIG. 6 illustrates nozzle layouts of the color head  62  and the monochrome head  64  installed to the head carrier  36 , shown in FIGS. 5A and 5B. This embodiment takes the case as an example, where the color head  62  performs printing of 4 intensities with 300 dpi, and the monochrome head  64  performs monochrome printing of 2 intensities with 600 dpi, that is double the resolution of the color head  62 . As the color head  62  shown in FIG. 6 performs color printing using a compound consisting of the color elements Y, M and C, a Y head  124 , an M head  126  and a C head  128  are installed. To the individual heads  124 ,  126  and  128  for these Y, M, C, n pieces of nozzles are placed in a vertical scanning direction, in short, a vertical direction as illustrated. For instance, as shown in the case of the Y head, nozzles  124 - 1 ,  124 - 2 , . . .  124 -n are placed. As the resolution of the monochrome head  64  is double the resolution of the color head  62 , as to the same K element, a K 1  head and a K 2  head are placed in two rows. As for the K 1  head  130  and the K 2  head  132 , n pieces of nozzles  130 - 1  through  130 -n, or  132 - 1  through  132 -n are placed in a vertical scanning direction, respectively. Also, the nozzles  130 - 1  through  130 -n, and the nozzles  132 - 1  through  132 -n are placed, being staggered only by a half pitch, so that the resolution of the monochrome head  64  is double the resolution of the color head  62 . As to each head installed to the color head  62  and the monochrome head  64 , for instance, the Y head  124  is taken here as an example, as shown in FIG. 7, piezoelectric elements  125 - 1 .  125 - 2  . . .  125 -n are installed, individually corresponding to the Y head&#39;s nozzles  124 - 1  through  124 -n. To the piezoelectric elements  125 - 1  through  125 -n, color drive waveform signals are individually supplied from the color head drive unit  58  as shown in FIGS. 5A and 5B. Corresponding to the nozzle of the head, a pressure chamber, an ink supply system, and an ink tank are installed, and by means of transmitting the displacement and the pressure generated by the drive of the piezoelectric elements  125 - 1  through  125 -n to the pressure chamber, the printer records characters or images on a record medium, like paper, etc., allowing the nozzle to inject ink particles. The structure of driving the head by the piezoelectric elements  125 - 1  through  125 -n is the same, as to the other M head  126 , V head  128 , K 1  head  130  and the K 2  head  132  shown in FIG.  6 . 
     Referred again to FIGS. 5A and 5B, in order to allow the printer to perform monochrome printing and color printing by a single scanning, even if there is any intermingled data containing monochrome image like text, etc., and color image, like a photo while the head carrier  36  is scanning in its stroke as shown in FIG. 2, in this embodiment, a color drive waveform generation unit  54  and a monochrome drive waveform generation unit  56  are independently installed to the control unit  34 , corresponding to the color head  62  and the monochrome head  64 . In this embodiment, when the printer is printing, three types of color drive waveform signals Vwc 1 , Vwc 2  and Vwc 3 , and also three types of monochrome drive waveform signals Vwk 1 , Vwk 2  and Vwk 3  are simultaneously outputted from the color drive waveform generation unit  54  and the monochrome drive waveform generation unit  56 . These color drive waveform signals Vwc 1  through  3 , and the monochrome drive waveform signals Vwk 1  through  3  are supplied to a color head drive unit  58  and a monochrome head drive unit  60  of the head carrier  36 . The color head drive unit  58  and the monochrome head drive unit  60  of the head carrier  36  are simultaneously controlled by a head control signal including a clock signal and a latch signal sent from the controller  46 . Also, the controller  46  supplies the color data consisting of three elements of Y, M and C to the color head drive unit  58 , and after selecting whichever one of the three types of color drive waveform signals Vwc 1  through  3 , depending on the value of the individual color data of Y, M, and C, it further supplies to the piezoelectric element of the nozzle corresponding to the color head  62 . Also, the controller  46  supplies K 1  monochrome data and K 2  monochrome data to the monochrome head drive unit  60 , as monochrome data to embody the resolution that is twice as high as the color resolution, and after selecting whichever one of the three types of monochrome drive waveform signals Vwk 1  through  3 , depending on the individual K 1  and K 2  monochrome data, it further supplies to the piezoelectric element of the nozzle corresponding to the monochrome head  64 . Herein, since the individual color data of Y, M and C allow the color head  62  to express color dots of 4 intensities, and it is accepted to select whichever one of the color drive waveform signals Vwc 1  through  3  corresponding to the intensity levels  1 ,  2  and  3 , of the intensity levels  0 ,  1 ,  2  and  3 , 2-bit data is used. For instance, if the color drive waveform signals Vwc 1  through  3  have been set corresponding to the color intensity levels  1 ,  2  and  3 , for the color data “00”, any of the color drive waveform signals Vwc 1  through  3  is not selected, for the color data “01”, the color drive waveform signal Vwc 1  is selected, for the color data “10”, the color drive waveform signal Vwc 2  is selected, and further, for the color data “11”, the color drive waveform signal Vwc 3  is selected. 
     The monochrome head  64  uses the K 1  head  130  and the K 2  head  132  staggered by a half-nozzle pitch in the vertical scanning direction as shown in FIG. 6, so as to embody double the resolution of the color head  62 . Also, by using of either one of the K 1  head  130  and the K 2  head  132  only, it is also possible to embody a resolution of 300 dpi same as the color head  62 . Therefore, the monochrome head  64  can perform monochrome printing with a resolution of 300 dpi, selecting either one of the K 1  head  130  and the K 2  head  132 , or with a high-resolution of 600 dpi, selecting both of the K 1  head  130  and the K 2  head  132 . Due to this, like the color data, the K 1  and K 2  monochrome data from the controller  46  shown in FIGS. 5A and 5B should be 2-bit data. 
     Here, when the monochrome drive waveform signal Vwk 1  sent from the monochrome drive waveform generation unit  56  corresponds to a resolution of 300 dpi, selecting the K 1  head  130  shown in FIG. 6, and the monochrome drive waveform signal Vwk 2  also corresponds to the same resolution of 300 dpi by the K 2  head  132  shown in FIG. 6, and further, the monochrome drive waveform signal Vwk 3  corresponds to a high-resolution of 600 dpi, using both of the K 1  head  130  and the K 2  head  132  shown in FIG. 6, for the monochrome data “00”, the printer does not select whichever one of the monochrome drive waveform signals Vwk 1  through  3 , for the monochrome data “01”, it selects the monochrome drive waveform signal Vwk 1  of 300 dpi, for the monochrome data “10”, it selects the monochrome drive waveform signal Vwk 2  of 300 dpi with the dot positions staggered by ½ pitch, and further, for the monochrome data “11”, it selects the monochrome drive waveform signal Vwk 3  of a high-resolution of 600 dpi. 
     FIG. 8 is a time chart showing the selection state of the color drive waveform and the monochrome drive waveform according to the color data and the monochrome data when the head carrier  36  is scanning once in the horizontal scanning direction, in the embodiment shown in FIGS. 5A and 5B, and when the color data and the monochrome data are intermingled during a single scanning. A supposition is made that the color data of the Y, M and C data exist as valid data in the first half of the horizontal scanning period T1, a single scanning of the carrier  36 , and in the second half, the monochrome data of the K 1  and the K 2  data exist as valid data. Here, the valid data means a stream of 2-bit data that can effectively select each drive waveform signal from the color drive waveform generation unit  54 , or from the monochrome drive waveform generation unit  56 , in the color head drive unit  58 , or in the monochrome head drive unit  60 , and further, that all data will not become bit “00”. On the other hand, invalid data means all data will become bit “00”, because the data will not select any drive waveform signal at any dot. Of course, there are some cases when even the valid data may express a intensity of  0  level, and in this case, like the invalid data, the data bit corresponding to that dot with  0  level intensity is “00”. 
     In this manner, within the horizontal scanning period T1, a single scanning of the head carrier  36 , the area where the color data of Y, M, and C are valid data will become a color-printing mode, and the area where the K 1  and the K 2  data are invalid data will become a monochrome-printing mode. Switching between the color-printing mode and the monochrome-printing mode in a single scanning, when the color data and the monochrome data are intermingled, is made by means of the simultaneous generation of the color drive waveform signal and the monochrome drive waveform signal, and if the color data becomes valid and the color drive wave signal has been selected, the printing mode will enter the color-printing mode, and if the monochrome drive waveform signal has been selected, the printer will enter the monochrome-printing mode. 
     FIG. 9 shows functions of a controller  46  installed to the control unit  34  shown in FIGS. 5A and 5B, together with an image memory  48 . The controller  46  comprises parallel/serial conversion units  66  and  68 , a waveform memory  70  and a timing control unit  72 . The waveform memory  70  stores a color waveform data  70 - 1  and a monochrome waveform data  70 - 2  as a drive unit for a single ink injection from the nozzle. Here, the color waveform data  70 - 1  stores three types of color waveform data corresponding to color intensity levels  1 ,  2  and  3 , as the color head  62  performs color printing of four intensities of color intensity levels  0 ,  1 ,  2  and  3  with 300 dpi. Also, the monochrome waveform data  70 - 2  stores three types of waveform data, a monochrome drive waveform data to drive the K 1  head  130 , a monochrome drive waveform data to drive the K 2  head  132 , and a high-resolution monochrome drive waveform data to drive both of the K 1  and the K 2  heads, as the printer embodies a high-resolution monochrome-printing of 600 dpi, with the nozzles staggered by a half-nozzle pitch, placing the K 1  head  130  and the K 2  head  132  in two rows as shown in FIG.  6 . Therefore, based on an instruction from the timing control unit  72 , from the waveform memory  70 , three types of color drive waveform data WDc 1  through  3 , and monochrome drive waveform data WDk 1  through  3  are outputted simultaneously. Further, from the waveform memory  70 , a waveform generation timing signal WRT is also simultaneously outputted, that is to be a standard clock for generating a drive waveform. 
     To the image memory  48 , printing data sent from the host computer  38  shown in FIGS. 5A and 5B is processed by the CPU  40  and written. In the printing data sent from the host computer  38 , there are monochrome data, color data, and further, intermingled data of monochrome and color data. Therefore, as to the color data, three storage areas of Y plain  74 , M plain  76  and C plain  78  are provided for the image memory  48 , corresponding to the individual color elements of Y, M and C. Also, as to the monochrome data, two areas of K 1  plain  80  and K 2  plain  82  are provided, corresponding to public section. 
     The parallel/serial conversion unit  66  reads out the data of the individual color elements of the Y, M, and C plains  74 ,  76  and  78  stored in the image memory  48  in synchronization with a single scanning of the head carrier  36 , and converts the read-out parallel data into serial data and supplies to the color head drive unit  58  on the side of the head carrier  36  shown in FIGS. 5A and 5B, as the individual serial data of the Y data, M data and the C data. As to the two monochrome image data of the K 1  plain  80  and the K 2  plain  82  stored in the image memory  48 , the parallel/serial conversion unit  66  similarly reads out the data on a single scanning-to-scanning basis, in synchronization with scanning of the head carrier  36 , and after converting the read-out parallel data into serial data, supplies to the monochrome head drive unit  60  on the side of the head carrier  36  shown in FIG. 3 as serial data in terms of the K 1  data and the K 2  data. The timing control unit  72  controls the image memory  48 , the parallel/serial conversion units  66  and  68 , and timing of the waveform memory  70 , receiving a control instruction from the CPU  40 , and further outputs a clock signal and a latch signal to the color head drive unit  58  and the monochrome head drive unit  60  of the head carrier  36 . 
     FIG. 10 is a flowchart showing the color data and the monochrome data processing procedure by the CPU  40  as to the image memory  48  shown in FIG.  9 . When receiving a printing data from the host computer at step S1, the CPU determines data type at step S2. The printing data to be received from the host computer consists of four elements of Y, M, C and K, but the data type is classified into a vector data type and a raster data type. In the raster data type, every dot consists of four elements of Y, M, C and K. While in the vector data type, for instance, character data has data types of font, size, Y, M, C and K. First of all, if the data type is the vector data type, the program goes to step S3, and extracts the K element to separate it from the color elements of Y, M and C. After the K element was extracted, the remaining Y, M and C elements are rasterized at step S4 with a basic resolution. While the K element is rasterized at step S5 with a twice-higher resolution. Next, at step S6, as to the Y, M, and C elements, color separation is performed on the element-by-element basis, and at step S7, intensity level change is performed. In other words, the color elements of Y, M and C are, for instance, 256 intensities, however, because the color head  62  shown in FIG. 6 can express 4 intensities, intensity level is changed from 256 intensities to 4 intensities. Next at step S8, data shift is performed as to the elements of Y, M and C. where intensity change corresponding to the color head  62  has been finished, and at step S9, the data is stored in each of the Y plain  74 , M plain  76  and the C plain  78  of the image memory  48  as print data. While, if the data type is a raster data type at step S2, at step  10 , the data is separated into the color elements of Y, M and C, and the monochrome element of K. As to the color separated color elements of Y, M and C, at step S7, like the vector type, after intensity level change was performed, data shift is performed at step S8, and at step S9, the data is stored in each of the plains  74 ,  76  and  78  of Y, M and C in the image memory  48 . As to the K element, where color separation was performed at step S10, data interpolation is performed at step S11 for processing with twice-higher resolution. Next, the program goes to step S12, and as to the monochrome data resolved with a twice-higher resolution, odd numbered lines and even numbered lines are separated, and at step S13, these separated lines are converted into monochrome dot patterns in binary, with the odd numbered lines as the K 1  monochrome data, and the even numbered lines as the K 2  monochrome data. After the binary conversion into dot patterns, the K 1  monochrome data and the K 2  monochrome data are individually stored in the K 1  plain  80  and the K 2  plain  82  of the image memory  48  at step S9, after the K 1  monochrome data and the K 2  monochrome data are data shifted at step S8. Also as to the monochrome data of the K element that was rasterized with a twice-higher resolution after being extracted from the vector data at step S5, after the data is separated into odd numbered lines and even numbered lines at step S12, at step S13, the lines are converted into binary dot patterns, and eventually stored in the K 1  plain  80  and the K 2  plain  82  of the image memory  48 , in the same manner as described above. 
     FIGS. 11A and 11B are circuit block diagrams of the color drive waveform generation unit  54  and the monochrome drive waveform generation unit  56  installed to the control unit  34  shown in FIGS. 5A and 5B. FIG. 11A shows the color drive waveform generation unit  54 , comprising a DA converters  84 ,  86  and  88 , and amplifiers  90 ,  92  and  94 . To the DA converters  84 ,  86  and  88 , the color drive waveform signals WDc 1 , WDc 2  and WDc 3  read from the waveform memory  70  installed to the controller  46  shown in FIG. 8, and a waveform generation timing signal WRT are supplied, and after these signals are converted into analog signals, and amplified with the amplifiers  90 ,  92  and  94 , the resultant three types of color drive waveform signals Vwc 1 , Vwc 2  and Vwc 3  are supplied to the color head drive unit  58 . FIG. 11B is a circuit block diagram of the monochrome drive waveform generation unit  56  shown in FIGS. 5A and 5B. The monochrome drive waveform generation unit  56  also comprises DA converters  96 ,  98  and  100 , and amplifiers  102 ,  104  and  106 . To the DA converters  96 ,  98  and  100 , the monochrome drive waveform signals WDk 1  through WDk 3  read from the waveform memory  70  installed to the controller  46  shown in FIG. 8 are individually supplied, and further, a waveform generation timing signal WRT is supplied in common, together with the monochrome drive waveform signals, and after these signals are converted into analog signals, and amplified with the amplifiers  102 ,  104  and  106 , resultant three types of monochrome drive waveform signals Vwk 1 , Vwk 2  and Vwk 3  are eventually supplied to the monochrome head drive unit  60 . 
     FIGS. 12A to  12 G illustrate waveforms of each drive waveform signal of color and monochrome outputted from the color drive waveform generation unit  54  and the monochrome drive waveform generation unit  56  shown in FIGS. 11A and 11B, and printing states of color dots and monochrome dots corresponding to each waveform drive signal. 
     FIGS. 12A to  12 C show color drive waveform signals Vwc 1  through  3  corresponding to intensity levels  1 ,  2  and  3 , and FIGS. 12K,  12 L and  12 M show color dots printed by each color drive waveform. Further, FIGS. 12D,  12 E and  12 F show three types of monochrome drive signals Vwk 1 , Vwk 2  and Vwk 3 , and FIGS. 12N,  12 O and  12 P show monochrome dots corresponding to each drive waveform signal. Moreover, FIGS. 12G,  12 H and  12 I and  12 J show time charts of color data to be used for selecting a color drive signal, monochrome data, clock and latch. The color drive waveform signals Vwc 1  through  3  shown in FIGS. 12A to C print color image of intensity levels  1 ,  2  and  3  having different dot sizes as shown in FIGS. 12K to  12 M, by controlling the amount of ink to be injected. While, waveforms of the monochrome drive waveform signals Vwk 1  through  3  shown in FIGS. 12D to  12 F have double the frequencies of the color drive waveform signals Vwc 1  through  3 . Of these, the monochrome drive waveform signal Vwk 1  shown in FIG. 12D is a single-appearing waveform of the first half within the waveform of two-fold frequency, and the monochrome drive waveform signal Vwk 2  shown in FIG. 12E is a single-appearing waveform of the second half within the waveform of two-fold frequency. Further, the monochrome drive waveform signal Vwk 3  shown in FIG. 12F can allow the printer to make monochrome printing with a twice-fold resolution like shown in FIG. 12P, as this signal forms a double waveform, having two waveforms both at the first half and the second half. As to the generation of the color drive waveform signals Vwc 1  through  3 , and the monochrome drive waveform signals Vwk 1  through  3 , the color data and the monochrome data are simultaneously generated as a head control signal, and further, head control signals of the clock and the latch are also generated in common, therefore, by this generation method, the printer can embody high-speed printing, by substantially switching between the color printing mode and the monochrome printing mode, even if the color data and the monochrome data are intermingled while the head carrier  36  is scanning in its stroke once. In other words, according to the present invention, the printer can perform both of color printing and monochrome printing by a single scanning of the head carrier  36 , regardless of the difference between the color printing mode with multi-intensities, and the monochrome printing mode with a high resolution, thereby allowing the printer to embody high-speed and high-quality printing. 
     FIGS. 13A and 13B show circuit block diagrams of the color head drive unit  58  and the monochrome head drive unit  60  installed to the head carrier  36 , shown in FIGS. 5A and 5B. First, FIG. 13A relates to the color head drive unit  58 , and shows a circuit unit corresponding to, for instance, the Y head  124  installed to the color head  62  shown in FIG.  6 . The color head drive unit  58  comprises a shift register  108 , a latch  110 , a decoder  112  and analog multiplexers  114 - 1 ,  114 - 2 , . . .  114 -n, the number of which corresponds to the number of nozzles of the Y head  124 . To the shift register  108 , the color dot data corresponding to the number of nozzles (n) in the vertical scanning direction of the Y head  124  shown in FIG. 6 is continuously inputted by clock, after being connected in the horizontal scanning direction. To the latch  110 , a latch signal is given, in synchronization with the entry of n pieces of dots same as the n pieces of nozzles of the Y head  124  against the shift register  108 , and n pieces of dot data is latched corresponding to the n pieces of nozzles. As the dot data held in the latch  110  is 2-bit data indicating four intensities, the decoder  112  converts the 2-bit data into a selection signal of the analog multiplexers  114 - 1  through  114 -n. The analog multiplexers  114 - 1  through  114 -n have three switches SW 1 , SW 2 , and SW 3 , and here, the analog multiplexer  114 - 1  is taken to show a typical case. The switch SW 1  selects the color drive waveform signal Vwc 1  of intensity level  1 , and supplies the selected signal to the piezoelectric element of the corresponding nozzle. The switch SW 2  selects the color drive waveform signal Vwc 2  of intensity level  2 , and supplies the selected signal to the piezoelectric element of the corresponding nozzle. Further, the switch SW 3  selects the color drive waveform signal Vwc 3  of intensity level  3 , and supplies the selected signal to the piezoelectric element of the corresponding nozzle. 
     FIGS. 14A to  14 C show a time chart of the Y data shift, latch and drive waveform output of the color head drive unit corresponding to the Y head shown in FIG.  13 A. First, as shown in FIG. 14A, to the shift register  108 , the n pieces of dot data of the Y element corresponding to the arrangement direction of nozzles for the Y head  124  shown in FIG. 6 are continuously shifted as the data Y 1 , Y 2  and Y 3  that are arranged in the horizontal scanning direction, on n pieces-to-n pieces basis in the vertical scanning direction. When the Y 1  data including the color dot data, the number of which corresponds to the n pieces of nozzles of the Y head  124  is shifted to the shift register  108 , the latch  110  performs latching movement in that timing, and like the drive waveform output shown in FIG. 14C, during the next period T2 of single pixel scanning in the main direction, from the decoder  112 , a selection signal (including not-selecting all) of the switches SW 1  through SW 3  that already decoded the n pieces of the dot data (2 bits) of the Y element is individually outputted to the analog multiplexers  114 - 1  through  114 -n. At this time, the data Y 2  of the Y element for the n pieces of the next nozzles is already shifted to the shift register  108 . After that, the process is repeatedly performed every period T2 of single pixel scanning in the horizontal scanning direction. 
     FIGS. 15A to  15 C show shift of the Y 1  data and clock, and further latch shown in FIGS. 14A to  14 C, more specifically. FIG. 15A shows the Y data, and the dot data of 2 bits, b 1  and b 2 , corresponding to the nozzles  124 - 1  through  124 -n of the Y head  124  shown in FIG. 6, is shifted in synchronization with the clock shown in FIG.  15 B. And, in the timing after the dot data of 2 bits corresponding to the n pieces of the nozzles was shifted, a latch signal is obtained as shown in FIG. 15C, and after the decoder  112  decoded the latched n pieces of 2 bit data, whichever one of the color drive waveform signals Vwc 1  through  3  by the switch selection of the analog multiplexers  114 - 1  through  114 -n will be selectively outputted, or not-selecting all will be performed. 
     While, FIG. 13B shows a circuit block diagram of the monochrome head drive unit  60  installed to the head carrier  36 , shown in FIGS. 5A and 5B. In the monochrome head drive unit  60 , the circuit configuration is basically the same as the configuration in the color head drive unit  58  shown in FIG.  13 A. In other words, the monochrome head drive unit  60  comprises a shift register  116 , a latch  118  and analog multiplexers  120 - 1  through  120 -n, the number of which corresponds to the n pieces of the nozzles for the K 1  head and the K 2  heads  130  and  132  shown in FIG.  6 . Clock and latch signals to the shift register  116  and the latch  118  from the controller  46  are the same signal as the signals to be sent to the latch  110  and the shift register  108  of the color head drive unit  58  shown in FIG.  13 A. In addition, as the individual monochrome data for the n pieces of nozzles of the monochrome head, in other words, the K 1  head or the K 2  head, to be latched by the latch  118  is 2-bit data, it is so programmed that at the bit  01 , the monochrome drive waveform signal Vwk 1  is selected, with, for instance, the switch SW 1 , representing the analog multiplexer  120 - 1 , turned ON, at the monochrome data bit  10 , the monochrome drive waveform signal Vwk 2  is selected, with the switch SW 2  selected, and further, at the monochrome data bit  11 , the monochrome drive waveform signal Vwk 3  is to be selected. 
     A logic chart shown in FIG. 16 shows systematically arranged conditions for selecting drive waveforms based on the individual color and monochrome dot data of the color head drive unit  58  shown in FIG.  13 A and the monochrome head drive unit  60  shown in FIG.  13 B. In the logic chart, the color or monochrome dot data is 2-bit data of “b 1  and b 2 ” bits, and depending on the 2-bit data “b 1 , b 2 ”, selection of drive waveforms by the analog multiplexers  114 - 1  through  114 -n is determined. In other words, as to the color data of Y, M and C, at the dot data “00”, any drive waveform is not selected, at “01”, the drive wave form Vwc 1 , at “10”, the drive waveform Vwc 2 , and at the “11”, the drive waveform Vwc 3  will be individually selected. Also, as to the monochrome heads of the K 1  and the K 2 , any drive waveform is not selected at the dot data “00”, the drive waveform Vwk 1  at “01”, at “10”, the drive waveform Vwk 2 , and at “11”, the drive waveform Vwk 3  will be individually selected. 
     FIGS. 17A to  17 N are time charts of the color waveform data, the color data and the monochrome data, and further a head control signal to be outputted from the controller  46  shown in FIG.  8  throughout the drive waveform period T3 to output drive waveform signals to each of the n pieces of the nozzle rows at each of the color head  62  and the monochrome head  64  shown in FIG.  6 . 
     FIGS. 17A to  17 C show color waveform data WDc 1  through  3  to be outputted from the waveform memory  70  shown in FIG. 8, and each block has digital value, for instance, 8 bits corresponding to each analog level at the color drive waveform signals Vwc 1  through  3 , individually shown in FIGS. 12A to  12 C. 
     Also, FIGS. 17D to  17 F show monochrome drive waveform signals Vwk 1  through  3  to be outputted from the waveform memory  70  shown in FIG. 9, and each block has digital value, for instance, 8 bits corresponding to the individual analog level of the monochrome drive waveform signals Vwk 1  through  3  shown in FIGS. 12D to  12 F. The color and the monochrome waveform data shown in FIGS. 17A to  17 F are supplied to the color drive waveform generation unit  54  and the monochrome drive waveform generation unit  56  shown in FIGS. 11A and 11B, together with the waveform generation timing signal WRT shown in FIG. 17G, and converted into analog drive waveform signals shown in FIGS. 12A to  12 F by the DA converters  84 ,  86 ,  88 ,  96 ,  98  and  100 . 
     Together with the color drive waveform data and the monochrome drive waveform data, the color data of Y, M and C shown in FIGS. 17H to  17 L, and the monochrome data of K 1  and K 2  are supplied to the parallel/serial conversion unit  66  and the parallel/serial conversion unit  68  installed to the controller  46 , as n pieces of dot data corresponding to 2 bits b 1  and b 2  per one nozzle as shown for the Y data. Also, simultaneously with the supply of these color data and monochrome data, a clock signal shown in FIG. 17M and a latch signal shown in FIG. 17N are supplied, so that the printer can make high-speed and high-quality printing, changing the printing mode while the head carrier  36  is scanning once, selecting the appropriate color drive waveform signal or the monochrome drive waveform signal depending on the color data or the monochrome data, being ready for different printing modes, like multi-intensity color printing mode by the color head, or high-resolution monochrome printing mode by the monochrome head. 
     FIG. 18 illustrates nozzle layout as another embodiment of the color head and the monochrome head to be used by the ink jet printer in accordance with the present invention. In the nozzle layout in the embodiment shown in FIG. 6, the nozzles of the Y head  124 , the C head  126 , the M head  128  and the K 1  head  130  are placed in the same line, but the position of the nozzle of the K 2  head is staggered by a half pitch. Due to the layout, when processing (UCR processing) is performed to replace the gray section in the color image with monochrome ink, as represented by diagonally shaded monochrome dots shown in FIG. 19A, the dots marked by the K 2  head  132  partly cover the color dots of Y, M and C denoted by circles (◯), thereby causing a problem that the color dots become unclear and dirty image. While in the nozzle layout shown in FIG. 18, against the side of the color head  62  of the Y head  124 , the C head  126  and the M head  128  that have the same nozzle layout, a configuration is made so that the nozzles  130 - 1  through  130 -n of the K 1  head  130  for the monochrome head  64  are shifted, for instance, by ¼ pitch upward as indicated in the drawing, and at the same time, the nozzles of the K 2  head are shifted by ¼ pitch downward, to be opposite to the state indicated in the drawing. By this configuration of the nozzle layout of the monochrome head  64 , if processing (UCR processing) is performed to replace the gray area in the color image with monochrome ink, as shown in FIG. 19B, the possibility of the monochrome dots represented by diagonal lines to partly cover the color dots represented by (◯) can be lower so that the image quality can be improved. In addition, monochrome printing uses 2×2 dots as one pixel, and when the number of the monochrome dots within one pixel is changed, even if monochrome printing of two intensities, intensity expression can be made. In other words, by mixing of different printing modes, like the color printing mode using dot intensity with variable color dot diameter, and the monochrome printing mode using area intensity where number of dots within a pixel can be varied within the range of 1 through 4, high image quality can be made, even if in the color image treated with UCR processing. 
     Moreover, the embodiment described above takes the case as an example, where the resolution of the monochrome head both in the horizontal scanning direction and the vertical scanning direction is set twice as high as the resolution of the color head, however, the resolution of the monochrome head is not limited to double the resolution of the color head, and it is needless to say that the embodiment can include a high-resolution of appropriate multiple. Also, a higher-resolution mode of the monochrome head compared to the color head can be embodied, only when the following conditions have been set: 
     (1) To set an integral multiple of the resolution of the color head  62  for the resolution of the monochrome head  64  in the horizontal scanning direction; 
     (2) To set an integral multiple of the color head  62  for the ink injection cycle of the monochrome head  64 ; 
     (3) To set the same multiple of the ink injection cycle of the monochrome head  64  for the ink injection cycle of the color head  62 , as the multiple of the resolution in the vertical scanning direction of the monochrome head  64  set for the resolution in the vertical scanning direction of the color head  62 ; 
     (4) To set an integral multiple of the resolution in the vertical scanning direction of the color head  62  for the resolution in the vertical scanning direction of the monochrome head  64 ; 
     (5) To set an integral multiple of the number of nozzle lines for each color of the color head  62  for the number of nozzle lines of the monochrome head  64 ; and 
     (6) To set the same multiple of the number of nozzle lines of the monochrome head  64  for the number of nozzle lines for each color of the color head  62 , as the multiple of the resolution of the monochrome head  64  set for the resolution of the color head  62  in the horizontal scanning direction. 
     The present invention also includes any appropriate variations that would not impair the object and advantage of the present invention. Further, the present invention is not restricted by numerical values given in the embodiments as shown above. 
     Industrial Applicability 
     According to the present invention, with the color head and the monochrome head, both of which are mounted on the same head carrier, the printer can make printing, while switching between the color printing mode and the monochrome printing mode to be selected depending on the color data or the monochrome data, within a single scanning, and in addition, since the printer can make intermingled printing of color printing and monochrome printing during a single scanning of the head carrier, as to a report or a text, containing a mixture of a color image rich in gradation expression, such as a photo or full-color picture, etc., and a detailed and clear monochrome line-drawing, the ink jet printer that prints with high-speed can be embodied. 
     By means of setting a multivalued intensity mode for the color printing mode, and a high-resolution mode for the monochrome printing mode, the printer can make color and monochrome intermingled printing with high-speed within a single scanning of the head carrier, and at the same time, in color printing and monochrome printing, high image quality can be embodied.