JP2004090322A - Print controller, print control program, and print control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem that ink ejection under unsettled state of ink level may be required when high resolution or high speed printing is tried, but high quality printing is difficult when the quantity of ejecting ink is varied. <P>SOLUTION: A printer is arranged to form an image by ejecting ink drops from a plurality of nozzles. When the printer ejects ink again under unsettled state of ink level in the nozzle, the head is subjected to driving control such that ink drops are ejected while compensating for a variation in the quantity of ink from a predetermined reference ink ejection quantity caused by unsettled ink level. Consequently, high quality printing can be carried out with a high resolution at a high speed. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a print control device, a print control program, and a print control method.
[0002]
[Prior art]
In recent years, the performance of inkjet printers has been improved, and high-speed printing and high resolution have been realized. In a print control device for controlling an ink jet printer, dots are formed on a print medium by driving and controlling a head to cause ink to fly from each nozzle. An ink surface is formed in the opening of the nozzle, and the ink surface formed in the opening is stable in a standby state. Become stable. When realizing high-speed printing and high resolution, the waiting time between the ejection of an ink droplet and the ejection of the next ink droplet becomes extremely short. , It is possible to realize high-speed printing at high speed.
[0003]
[Problems to be solved by the invention]
In the above-described conventional print control device, it was difficult to perform high-quality printing. That is, when the ink surface is stable and when the ink surface is unstable, the amount of ink ejected differs even when ink droplets are ejected with the same force, and a change in the amount of ink results in a change in color on the print medium. Therefore, it was difficult to print in the intended color, and it was difficult to print with high quality.
SUMMARY An advantage of some aspects of the invention is to provide a print control apparatus, a print control program, and a print control method that can achieve both high-speed and high-resolution printing and high-quality printing. .
[0004]
Means for Solving the Problems and Effects of the Invention
In order to achieve the above object, according to the first aspect of the present invention, when the ink is ejected again in a state where the ink surface of the nozzle is unstable, the ink amount fluctuates from a predetermined reference ink ejection amount due to the instability of the ink surface. To compensate for the amount of ink used. That is, when ink is ejected with the ink surface being unstable, the ejection amount fluctuates as compared with the ink ejection amount when the ink surface is stable, the ink ejection amount using a specific standard machine, or the like. Disregarding fluctuations in the ink amount when the ink surface is stable and when the ink surface is unstable, the ink amount fluctuates due to dots even in the same machine, and ink amount fluctuations that occur between the standard machine and other machines. If the is ignored, the output result on the standard machine and the output result on other machines will be different.
[0005]
For this reason, if the ink amount fluctuation is not compensated for, the print quality will deteriorate. Can be printed in quality. After the ink is ejected, the ink surface is stabilized with the passage of time, so that when the next ink is ejected after the ink is ejected, the ink can be ejected in a stable state after a sufficient time has elapsed, but the ink amount is compensated. Thus, ink can be ejected even when the ink surface is unstable. Therefore, it is possible to realize a configuration in which the interval when continuously ejecting ink is short, that is, high-speed and high-resolution printing and high-quality printing simultaneously.
[0006]
As the predetermined reference ink ejection amount, as described above, various standards such as a stable state and the ink ejection amount in the standard machine can be adopted as the predetermined reference ink ejection amount. Criteria can be adopted. The ink surface is the liquid surface of the ink formed by the surface tension at the nozzle opening, and the unstable state of the ink surface is a state in which the amount of ink in the ink chamber inside the nozzle fluctuates. As the ink amount fluctuation caused by the ink surface being unstable, there can be various fluctuation amounts due to the vibration of the ink surface.However, it is possible to measure the discharged ink amount at the ink discharge timing in the unstable state, It can be determined by various methods such as statistically summing up the measurement results. Further, this variation is the variation in the amount of ink when the stable state and the unstable state of the ink surface are compared, and the variation when comparing the two is not always strictly constant over time, There is reproducibility. That is, the amount of ink does not change every time an ink droplet is ejected from each nozzle of the printing apparatus, and the amount of change can be specified by the above various methods, and as a result, the amount of change can be compensated for .
[0007]
Further, in the invention according to claim 2, when the head is driven in the main scanning direction, the ink amount fluctuation is compensated for when ink is continuously ejected. In other words, the state in which the frequency at the time of ink ejection is the highest is a state in which ink is continuously ejected. When ink is continuously ejected, the amount of ink ejected after the second time is compensated for by ink compensation. High-quality printing can be performed while suppressing the influence of fluctuations.
[0008]
Even if the ink is continuously ejected, it is not necessary to compensate for the fluctuation of the ink amount when the ink surface reaches a stable state after a predetermined time has elapsed after the ink was ejected. In this sense, a typical example that requires ink amount compensation is a dot that is formed later when ink is ejected to both pixels where dots are continuously formed in the main scanning direction. It is not limited to. That is, as long as the ink is ejected while the ink surface is unstable, various cases, such as the case where ink is ejected to three or more adjacent dots, are applicable.
[0009]
Various methods can be adopted as a method for determining the compensation ink amount. As a preferable example, in the invention described in claim 3, the amount obtained by multiplying the fluctuation ratio of the ink amount by the generation ratio of the ink fluctuation is described. Is increased or decreased from the predetermined reference ink ejection amount to determine the compensation ink amount. That is, the variation ratio of the ink amount is a variation ratio between the ink amount when the ink is ejected with the ink surface being stable and the ink amount when the ink is ejected with the ink surface being unstable. By grasping the variation ratio, the amount of ink compensation in one ink ejection can be determined. The fluctuation ratio can be grasped by, for example, measuring the ink ejection amount when the ink surface is stable and when the ink surface is unstable.
[0010]
The occurrence ratio is the occurrence ratio of the ink ejected when the ink surface is in an unstable state. By grasping the occurrence ratio, the necessary number of compensations can be grasped. The occurrence ratio may be calculated by one main scan, or may be calculated on the assumption that one image is printed. In any case, the occurrence ratio can be totalized at the stage when the algorithm for generating print data for printing a certain image in the printing apparatus is determined. If the fluctuation rate and the occurrence rate can be grasped as described above, the printing apparatus can be controlled so that the printing is executed while performing compensation with an appropriate amount by multiplying them.
[0011]
Here, the variation ratio and the occurrence ratio need only be stored in a predetermined storage medium, and various modes can be adopted. Since the fluctuation ratio depends on the instability of the ink surface as described above, it is considered that the fluctuation ratio is different for each machine of the printing apparatus, and is stored in a storage medium in the printing apparatus. It is preferable that the variation ratio is obtained from the following. As described above, the occurrence ratio depends on the algorithm of print data generation, so that there is no difference for each machine of the printing apparatus as long as the same algorithm is used. Therefore, it may be stored in a recording medium in the printing apparatus, or may be stored in a storage medium in the separate computer when the printing control apparatus is formed by a separate computer from the printing apparatus. It is good. Of course, these are only examples, and the present invention is not limited to these modes as long as the print control device can acquire the fluctuation ratio and the occurrence ratio stored in the storage medium.
[0012]
Various methods can be adopted as a configuration for actually applying the compensation with the ink amount determined as described above. As an example of such a configuration, in the invention according to claim 4, in a series of print control processing, color conversion of image data used by an image device other than the printing device into ink amount data specifying an ink ejection amount in the printing device. In this case, the ink amount fluctuation is compensated for by correcting the ink amount data when performing the processing of FIG.
[0013]
In a normal printing apparatus, halftone processing is performed after the color conversion, and the printing apparatus reduces the ink amount data to a gradation value that can be expressed for each pixel, and performs two or four gradations per dot. Execute printing with the key. Two gradations express gradations when ink is ejected with a constant force and when ink is not ejected. Four gradations indicate cases where ink is ejected with three levels of force and cases where ink is not ejected. Is used for gradation expression. Although the gradation value after color reduction is not limited, in any case, the control process of the printing apparatus is simpler when the ink ejection force in the printing apparatus is constant.
[0014]
Therefore, if the ink amount data itself is corrected, the halftone process can be executed with the ink amount compensated, and there is no need to change the ink ejection force in the printing apparatus. More specifically, even if the algorithm of the halftone process and the gradation per dot that can be expressed by the printing apparatus are various, one dot per halftone process after the halftone process is assumed when certain ink amount data is assumed. Since the gradation is specified, it is possible to grasp the rate of occurrence of ink ejection when the ink surface is unstable with respect to the ink amount data. If this occurrence ratio is stored in a predetermined storage medium, the ink amount can be compensated by correcting the ink amount data by a value obtained by multiplying the variation ratio and the occurrence ratio after the color conversion by the color conversion unit. .
[0015]
In this correction, a value obtained by multiplying the fluctuation rate and the occurrence rate is increased or decreased from the ink amount. That is, when the ink ejection amount when the ink surface is unstable is larger than the predetermined reference ink ejection amount, the above value is subtracted from the ink amount data, and the ink ejection amount when the ink surface is unstable In the case where the discharge amount is smaller than the reference ink discharge amount, the ink amount can be compensated by adding the above value to the ink amount data. According to the above configuration, the ink amount can be compensated while the ink discharging force is set to a specific force. However, it is needless to say that the present invention is not limited to this configuration. You may compensate.
[0016]
Further, in the invention according to claim 5, by referring to the reference color image data in a series of print control processing, the amount of ink ejected by the printing apparatus is specified for the image data used by other image devices other than the printing apparatus. In the case of performing the color conversion processing to the ink amount data, the ink amount is compensated by referring to the reference color image data with the ink amount data compensated in advance. That is, the image data is converted into ink amount data for which ink amount compensation has been performed by color conversion.
[0017]
Also in such a configuration, the gradation per dot after halftone processing is specified when certain ink amount data is assumed, so that the ink ejection in the state where the ink surface is unstable with respect to the ink amount data is specified. The occurrence ratio can be grasped, and the reference color image data may be constituted by a value obtained by multiplying the fluctuation ratio and the occurrence ratio. Here, the reference color image data may be any data that defines the correspondence between the image data and the ink amount data, and may be various data such as a so-called color correction look-up table or a profile that defines this correspondence with a predetermined function. Embodiments can be employed.
[0018]
In a configuration in which color conversion is performed with reference to a color correction lookup table, arbitrary ink amount data is generated by interpolation. Therefore, the reference points are selected so that the ink amount data generated by the interpolation is also the amount of ink that has undergone the above-described compensation, and a table is formed. It can be considered that the ink amount is compensated for the ink amount data.
[0019]
The head driving means only needs to be able to compensate for fluctuations in the ink amount, and various configurations can be adopted as a configuration for compensating the ink amount by correcting the reference ink ejection amount. That is, the compensation may be performed by increasing or decreasing the number of ink droplets to be ejected as in the invention described in claim 6, or by adjusting the ejection amount for each unit ink ejection frequency as in the invention described in claim 7. You may.
[0020]
In the former case, the number of ink droplets to be printed per unit area is varied by a configuration or the like that corrects the data itself as described above, while keeping the ejection amount per unit number of ink ejection times constant. It is possible to adopt a configuration in which ink droplets are ejected at the determined ink amount. In the latter case, it is possible to adopt a configuration in which the volume of the ink chamber is changed by a piezo element or the like and the discharge amount for each unit ink discharge number is changed by changing the voltage level applied to the piezo element or the like.
[0021]
In the present invention, various ink ejection amounts can be adopted as the predetermined reference ink ejection amount, and the ink amount when the ink is ejected with the ink surface being stable as in the invention according to claim 8 is As a reference, it is possible to prevent the ejection ink amount from fluctuating due to dots in the same machine. According to the ninth aspect of the present invention, when the ink amount when the ink is ejected in a state where the ink surface is unstable in a specific standard machine is used as a reference, the difference between each machine is reduced and the color development of the standard machine is performed. Can be compliant.
[0022]
Furthermore, various fluctuation factors can be taken into account when compensating for ink fluctuations due to ink surface instability. In the invention according to claim 10 as a configuration example, ink temperature information is obtained by acquiring ink temperature information. Is different for each temperature. That is, if the temperature is different, the viscosity and the like of the ink are different, which causes a change in the ejection amount of the ink. Therefore, by using a different compensation amount for each temperature, it is possible to accurately cope with an unstable state of the ink surface and fluctuation of the ink amount due to the temperature, and to stably perform high-quality printing.
[0023]
Here, the configuration for acquiring the ink temperature information can be realized by various sensors or the like. For example, a configuration in which the sensor is attached to the head to directly or indirectly acquire the ink temperature may be used. Needless to say, it is only necessary to be able to compensate for the ink amount fluctuation due to the temperature fluctuation, so that it is not essential to detect the temperature value itself, but it is sufficient if the temperature change can be grasped stepwise. There are various methods for reflecting the ink amount with reference to the temperature information. For example, the fluctuation ratio is measured for each temperature, and the fluctuation ratio is stored for each temperature, and an appropriate value is stored based on the acquired temperature information. What is necessary is just to comprise so that the fluctuation | variation rate may be selected.
[0024]
Furthermore, in the present invention, the configuration according to claim 11 may be employed as a configuration for achieving both high-speed and high-resolution printing and high-quality printing. That is, the ink amount fluctuation information and the occurrence ratio information are stored in a predetermined storage medium, and the information is obtained to calculate the ink amount fluctuation compensation amount at each gradation value of the image data. Then, compensated image data reflecting the ink amount variation compensation amount is generated. As a result, printing can be performed with the ink amount that compensates for the ink amount fluctuation at high speed and high resolution, and high-quality printing can be performed.
[0025]
The concept of the present invention is not limited to this, and may include various aspects. For example, the print control apparatus according to the present invention may exist alone or may be used while being incorporated in a certain device. Therefore, it can be changed as appropriate, such as software or hardware. When software for controlling the print control device is used as an embodiment of the idea of the present invention, the software naturally exists and is used on a recording medium on which such software is recorded. To establish. For this reason, the inventions according to the twelfth and thirteenth aspects have a configuration in which a computer implements the functions corresponding to the first and the eleventh aspects. Of course, it is needless to say that a configuration in which a computer realizes the functions corresponding to claims 2 to 10 can also be realized.
[0026]
Of course, the recording medium of this program may be a magnetic recording medium, a magneto-optical recording medium, or any recording medium to be developed in the future. Further, the duplication stages of the primary duplicated product, the secondary duplicated product and the like are equivalent without any question. Although different from the above-described medium, if the supply is performed using a communication line, the communication line is used as a transmission medium and the present invention is used. Further, even when a part is implemented by software and a part is implemented by hardware, the concept of the present invention is not completely different, and a part is stored on a recording medium and appropriately It may be in a form that can be read.
[0027]
In controlling such a printing control apparatus, it is natural that an invention exists in the procedure at the base of each unit performing a process according to a predetermined control procedure. It is possible. For this reason, the invention according to claim 14 and claim 15 is configured to include the steps corresponding to claim 1 and claim 13. It goes without saying that a configuration including the steps corresponding to claims 2 to 10 can be realized.
[0028]
BEST MODE FOR CARRYING OUT THE INVENTION
Here, embodiments of the present invention will be described in the following order.
(1) Configuration of the present invention:
(1-1) Percentage of fluctuation of ink amount due to instability of ink surface:
(1-2) Occurrence ratio of ink amount fluctuation due to instability of ink surface:
(1-3) Print control processing:
(2) Comparison between a case where the ink amount fluctuation is compensated and a case where the ink amount fluctuation is not compensated:
(3) Other embodiments:
[0029]
(1) Configuration of the present invention:
FIG. 1 shows a schematic hardware configuration of a system constituting a print control apparatus according to the present invention, and FIG. 2 shows a schematic hardware configuration of a printer. The computer 10 has a program execution environment including a ROM 13 and a RAM 14, and can execute a predetermined program by transmitting and receiving data via the system bus 12. A hard disk drive (HDD) 15 as an external storage device, a flexible disk drive 16 and a CD-ROM drive 17 are connected to the system bus 12, and an OS 20, an application program (APL) 25 and the like stored in the HDD 15 are stored in a RAM 14. And the program is executed.
[0030]
In the present embodiment, the computer 10 constitutes a print control device by executing a printer driver described later in the program execution environment. Therefore, this printer driver also corresponds to the print control program. Of course, a program execution environment may be constructed in the printer body, and the print control device may be formed by the printer alone. In this case, the print control device and the print control program are built in the printer.
[0031]
Operation input devices such as a keyboard 31 and a mouse 32 are connected to the computer 10 via a serial communication I / O 19a, and a display 18 for display is also connected via a video board (not shown). Further, the printer 40 can be connected via the USB I / O 19b. The computer 10 is a so-called desktop computer, but may be a notebook computer or a mobile computer, and can be realized in various forms. Also, the connection interface between the computer 10 and the printer 40 is not limited to the above-described one, and various connection modes such as a serial interface and a SCSI connection can be adopted, and the same applies to any connection mode developed in the future. .
[0032]
In this example, the programs are stored in the HDD 15, but the recording medium is not limited to this. For example, it may be a flexible disk 16a or a CD-ROM 17a. The programs recorded on these recording media are read by the computer 10 and installed on the HDD 15. After the installation, it is read into the RAM 14 via the HDD 15 to control the computer. The recording medium is not limited to this, and may be a magneto-optical disk or the like. It is also possible to use a non-volatile memory such as a flash card as a semiconductor device, and to use an external file server via a modem or a communication line for downloading, the communication line is a transmission medium. The present invention is utilized.
[0033]
On the other hand, as shown in FIG. 2, a bus 40a provided inside the printer 40 includes a CPU 41, a ROM 42, a RAM 43, an ASIC 44, a control IC 45, a USB I / O 46, and an interface for transmitting image data and drive signals. (I / F) 47 are connected. Then, the CPU 41 controls each unit according to the program written in the ROM 42 while using the RAM 43 as a work area. The ASIC 44 is an IC customized for driving a print head (not shown), and performs processing for driving the print head while transmitting and receiving predetermined signals to and from the CPU 41. Further, it outputs applied voltage data to the head driving unit 49.
[0034]
The control IC 45 controls the cartridge memory, which is a non-volatile memory mounted on each of the ink cartridges 48a to 48f. The control IC 45 controls the reading of information on the color and remaining amount of ink recorded in the cartridge memory by the control of the CPU 41. The information on the remaining amount of ink is updated. The USB I / O 46 is connected to the USB I / O 19b of the computer 10, and the printer 40 receives data transmitted from the computer 10 via the USB I / O 46. The carriage mechanism 47a and the paper feed mechanism 47b are connected to the I / F 47. The paper feed mechanism 47b includes a paper feed motor, a paper feed roller, and the like, and sequentially feeds a print recording medium such as a printing paper to perform sub-scanning. The carriage mechanism 47a includes a carriage on which a print head is mounted, and causes the carriage to reciprocate to cause the print head to perform main scanning.
[0035]
The head driving unit 49 is a circuit including a dedicated IC, a driving transistor, and the like. The head driving unit 49 generates an applied voltage pattern to a piezo element incorporated in the print head based on applied voltage data input from the ASIC 44. The print head is connected to a cartridge holder 48 capable of mounting ink cartridges 48a to 48f filled with inks of six colors of KCMYlclm (black, cyan, magenta, yellow, light cyan, and light magenta in that order) by a tube for each ink. And each ink is supplied.
[0036]
In the ink discharge section of the print head, six sets of nozzle rows for discharging each of the six colors of ink are formed so as to be arranged in the main scanning direction of the print head, and in each of the nozzle rows, a plurality of nozzles are arranged in the sub-scanning direction. They are arranged at regular intervals. FIG. 3 is an enlarged view showing the nozzle and its internal structure. As shown in the figure, the ink in the ink cartridges 48a to 48f and the ink chamber 48g are communicated via the tube, and the ink is supplied to the opening of the nozzle Nz opened below the head.
[0037]
The piezo element PE expands / contracts according to the applied voltage generated by the head drive unit 49, and changes the volume of the ink chamber 48g. As a result, the ink droplets Ip are ejected from the openings of the nozzles Nz, and the ink droplets Ip adhere to the print medium to perform printing. After the ink droplet Ip is ejected, ink that does not fly as the ink droplet Ip remains in the ink chamber 48g. At this time, the ink surface vibrates near the opening of the nozzle Nz. That is, in a normal state where no voltage is applied to the piezo element PE, the ink surface of the nozzle Nz opening stably forms substantially the same surface as the lower surface of the head, but immediately after the ink droplet is ejected. In this state, the ink surface is in an unstable state in which the ink surface vibrates, and returns to a stable state after a predetermined time has elapsed.
[0038]
FIG. 4 is a diagram showing this state. In the figure, the horizontal axis represents time, and the vertical axis represents the displacement of the ink surface. The origin on the horizontal axis is the time at which voltage application to the piezo element PE is started, and the origin on the vertical axis indicates the position of the ink surface in the stable state. That is, when the ink surface is further below the lower end surface of the nozzle, it is indicated by a negative value on the vertical axis, and when it is above the lower end surface of the nozzle, it is indicated by a positive value on the vertical axis. Since the ink surface is stable at the time Tb shown in the figure, even if the ink droplet Ip is continuously ejected in the main scanning direction, the next ink droplet Ip is ejected after reaching the time Tb. In this case, the ejection amount of the ink droplet Ip is stabilized.
[0039]
(1-1) Percentage of fluctuation of ink amount due to instability of ink surface:
However, in order to use only this stable state, it is necessary to wait for the time Tb after discharging one ink droplet Ip until discharging the next ink droplet. In order to achieve high-speed printing, it is preferable that the standby time be as short as possible when continuously discharging ink droplets. Further, in order to realize high-resolution printing, the number of times ink is ejected per main scan increases, so that if the standby time is kept constant, the printing speed is reduced accordingly. Thus, in the present embodiment, high-speed printing and high resolution are realized by, for example, ejecting ink droplets not only after the time Tb but also at the time Ta. . Since the time Ta shown in FIG. 4 is a time interval of 1/4 of the time Tb, the resolution is quadrupled.
[0040]
When the ink droplet is ejected at the time Ta, the ejection amount fluctuates as compared with the ink droplet at the time Tb due to the unstable ink surface. Thus, by applying the ink amount compensation according to the present invention, the ink amount of each ink droplet is allowed to fluctuate, but the final printing result is obtained only after the time Tb. The amount of ink is set to be equal to the amount of ink ejected to prevent print quality from deteriorating.
[0041]
For this reason, in the present embodiment, the fluctuation ratio data 42a is written in the ROM 42, and can be used in processing by a printer driver described later. The fluctuation ratio data 42a is a fluctuation ratio between the ink discharge amount B at the time Tb and the ink discharge amount A at the time Ta, and is a value calculated by D = (AB) / B. The ROM 42 stores data that allows the computer to recognize the value D as the fluctuation ratio data 42a.
[0042]
This value D can be calculated by assembling the printer 40 once, then actually discharging the ink droplets at times Tb and Ta at a factory or the like, and measuring the discharge amount. The ROM 42 may store the variation ratio data 42a and provide it in a readable manner. Therefore, various ROMs may be applied. However, in the sense that the ink amount is measured and then written, the It is preferable to use an EEPROM to which data can be written after assembling. The graph shown in FIG. 4 is an example, and the ink surface changes variously depending on the nozzle shape and the voltage pattern to the piezo element. Further, the ink may be ejected at a time other than the time Ta as the ink ejection timing. That is, the ink ejection timing depends on the resolution.
[0043]
FIG. 5 is a schematic configuration diagram of a main control system of the printing apparatus realized by the computer 10. The printer 40 executes printing under the control of a printer driver installed in the computer 10, and the printer driver causes the computer 10 to function as a print control device. Specifically, a printer driver (PRTDRV) 21, an input device driver (DRV) 22, and a display driver (DRV) 23 are incorporated in the OS 20. The display DRV23 is a driver for controlling display of image data and the like on the display 18, and the input device DRV22 receives a code signal from the keyboard 31 and the mouse 32 input via the serial communication I / O 19a and receives a predetermined signal. Accept input operation.
[0044]
The APL 25 is an application program capable of executing retouching of a color image and the like. The user operates the operation input device under the execution of the APL 25 and issues a print instruction by retouching the image indicated by the image data 15a. It can be carried out. When a print instruction is issued by the APL 25, the PRTDRV 21 is driven, performs color conversion with reference to an LUT 15b described later, creates print data while performing halftone processing, and the like, and sends the print data to the printer 40. Printing is performed by sending.
[0045]
That is, the LUT 15b is a table that defines the correspondence between the RGB data and the KCMYlclm data, and defines a combination of each color gradation value of the RGB data and the KCMYlclm data for a predetermined number of reference points. For example, for RGB data, a reference value is formed by dividing a gradation value range of 256 gradations into 16 for each of the RGB element colors, and a gradation value of “0, 16, 32,. The reference point is defined by specifying all combinations.
[0046]
At the time of color conversion, the color conversion module 21b performs an interpolation operation with reference to each reference point, develops the image into an intermediate table having a larger number of reference points, and performs the above-described image data by the interpolation operation with reference to the reference points of the intermediate table. The RGB data is converted into KCMYlclm data for each pixel 15a. Of course, as the LUT, a different table may be created for each medium and ink set that can be used in the printer 40, and the LUT may be configured to be appropriately selectable. In the present embodiment, the image data 15a is dot matrix data in which each of the RGB element colors is expressed in gradation, and is data conforming to the sRGB standard. Of course, in the LUT 15b, in addition to a configuration having specific values of sRGB data as data, colors are specified for a specific set of RGB data in a predetermined order, and specific values of RGB data are omitted. Is also good.
[0047]
When the color conversion module 21b performs the color conversion, the image is data expressing color components in 256 gradations for each color of KCMYlclm for each dot. In the printer 40 according to the present embodiment, each dot is represented by two gradations in which ink droplets are attached or not attached, and the halftone processing module 21c calculates the KCMYlclm gradation value of each dot for each color component. And performs a halftone process for expressing the recording density of the ink droplets. Note that there are various algorithms for converting the gradation value for each color component and executing the halftone processing. In the present embodiment, the dither method is used. Or the algorithm may be appropriately selected by user selection or the like.
[0048]
In any case, after the halftone processing, the data specifies whether or not to eject ink droplets for each dot of the dot matrix forming the image. In the present embodiment, data of one bit for each pixel is used. In addition, when the data is "0", the ink droplet is not ejected, and when the data is "1", the ink droplet is ejected. Thereafter, the print data generation module 21d performs a nozzle data conversion process. That is, in the printer 40, the ejection nozzles Nz are formed in a row in the head, and a plurality of ejection nozzles are arranged in the sub-scanning direction in the nozzle row. Data is used simultaneously.
[0049]
Therefore, nozzle data conversion processing is performed in which data to be used simultaneously among the data arranged in the main scanning direction is rearranged in order so as to be simultaneously buffered by the printer 40. After this conversion processing, print data is generated by adding predetermined information such as the resolution of the image, and is output to the printer 40 via the USB I / O 19b. The image displayed on the display 18 is printed. The printer 40 executes printing based on the print data.
[0050]
(1-2) Occurrence ratio of ink amount fluctuation due to instability of ink surface:
Looking at the data subjected to the nozzle data conversion processing as described above for each main scanning line, the data for specifying the ejection / non-ejection of ink droplets in each main scanning line is, for example, "0011101100 ...". And so on, and if “1” continues in this data, it can be determined whether or not ink ejection in the time unstable state can occur. That is, when the ink droplets Ip are ejected from both adjacent dots, it is determined whether or not it is necessary to eject the ink droplets Ip of the continuous dots at a timing earlier than the time Tb shown in FIG. It can be determined at the stage where the data bit string, the print resolution, and the print mode for each are specified.
[0051]
Therefore, if the algorithm executed by each module of the printer driver 21 is determined, it is determined whether or not the ink ejection in the unstable state is performed at the time of printing in a specific resolution or a specific mode. In the present embodiment, the occurrence ratio of ink ejection in an unstable state is converted into data in advance for ink amount compensation. FIG. 6 is a diagram illustrating an example of the occurrence ratio. In the same figure, for each gradation value (gradation values 0 to 255) of the KCMYlclm data after the color conversion, the rate of occurrence of ink ejection in an unstable state is shown. In the present embodiment, an unstable state occurs when two or more “1” s are continuous in the bit string, and FIG. is there. Note that the vertical axis of the figure represents the occurrence ratio C in units of%, and the horizontal axis represents each gradation value of the KCMYlclm data.
[0052]
In the figure, the curve indicated by the dashed line is the occurrence ratio C when the resolution is 1440 × 720 dpi. The curve shown by the solid line is the occurrence ratio C when the resolution is 720 × 720 dpi and the so-called full overlap processing for completing one line of dots by two scans is performed. As shown in the figure, since the occurrence ratio C differs depending on the resolution and the print mode, the color conversion module 21b, the halftone processing module 21c, the print data generation for each gradation value of the KCMYlclm data in each resolution and print mode in advance. The processing in the module 21d is performed, and the data shown in FIG. 6 is grasped. Then, it is stored in the HDD 15 as the occurrence ratio data 15c.
[0053]
It is preferable that the occurrence ratio data 15c be created in advance by the manufacturer of the printer 40 and written into the HDD 15 when the printer driver 21 is installed. In any case, the occurrence ratio data 15c, as shown in FIG. 6, which allows the correspondence between each gradation value and the occurrence ratio C to be grasped, is stored for each resolution and print mode, and printing is executed by the printer driver 21. The appropriate generation ratio data 15c is appropriately acquired in accordance with the resolution and the print mode at the time of the execution. When the ejection time Ta during continuous ejection is changed depending on the resolution or the like, the variation ratio data 42a shown in the printer 40 is also different. Therefore, the variation ratio data 42a is stored for each resolution and used appropriately. A configuration may be adopted.
[0054]
(1-3) Print control processing:
In the present invention, when the algorithm to be executed by the color conversion module 21b, the halftone processing module 21c, and the print data generation module 21d is determined, the occurrence ratio data 15c can be specified. The fluctuation rate data 42a can be specified by measuring the amount. Therefore, these data are stored in advance in the HDD 15 and the ROM 42, and a correction process is added to a series of processes executed by the color conversion module 21b, the halftone processing module 21c, and the print data generation module 21d. Ink amount compensation can be realized.
[0055]
Hereinafter, processing for implementing ink amount compensation will be described with reference to a flowchart. When the user instructs the APL 25 to execute printing, the printing process is executed according to the flow shown in FIG. When the printing process is started, the image data obtaining module 21a obtains the image data 15a stored in the RAM 14 in step S100. In step S110, when the number of pixels of the image data 15a and the number of pixels required for printing do not match, resolution conversion for matching the two is executed.
[0056]
That is, when printing is performed by the APL 25, the resolution and the print mode can be determined in advance in accordance with a user's instruction, and the number of pixels required for printing at the determined resolution and the number of pixels of the image data 15a are determined. If they do not match, the number of pixels of the image data 15a is increased or decreased by interpolation or the like. Of course, if the resolutions match, step S110 may be skipped.
[0057]
When the resolution conversion processing is performed, the image data acquisition module 21a activates the color conversion module 21b. The color conversion module 21b acquires the LUT 15b stored in the HDD 15 in step S120, develops the LUT into the intermediate table by interpolation, and stores the LUT in the RAM 14. The color conversion module 21b includes an ink amount correction module 21b1, and in step S130, corrects KCMYlclm data, which is data in the intermediate table and specifies an ink amount.
[0058]
That is, the reference points defined in the intermediate table define the correspondence between the RGB data and the KCMYlclm data, and each gradation value I of the KCMYlclm data is replaced by IICCD. That is, by outputting a predetermined command via the USB I / O 19b, the fluctuation ratio data 42a output by the printer 40 is obtained, and the occurrence ratio data 15c corresponding to the resolution and print mode during printing is obtained from the HDD 15. I do. Here, since the occurrence ratio C differs depending on each value of the KCMYlclm data I as described above, the value of the occurrence ratio C corresponding to each value of the KCMYlclm data I is substituted. As described above, the variation ratio D is defined by (AB) / B. Therefore, when the ejection amount is larger than the ink ejection at the time Tb as in the ink ejection at the time Ta in FIG. The ratio D becomes a positive value.
[0059]
In the KCMYlclm data I, there are dots whose ink amount increases by the variation ratio D by the occurrence ratio C. Therefore, the above I · C · D is caused by the unstable ink surface when the KCMYlclm data I is used. Corresponding to the increasing amount of ink. Therefore, by subtracting I, C, and D from the base value I, the ink amount becomes a state in which the increased ink amount due to the unstable ink surface is compensated. Needless to say, even when the amount of the discharged ink is smaller than that at the time of stable ink discharge at the time Ta in FIG. It is compensated so that the ink amount increases.
[0060]
In this embodiment, for each value of the KCMYlclm data, the value obtained by multiplying the occurrence rate C and the variation rate D for each of the KCMYlclm data defined in the intermediate table as described above is subtracted from the base data value. It is assumed that the ink amount has been compensated, and the processing after step S140 is executed. In step S140, the RGB data acquired in step S100 is converted into dot data of KCMYlclm data with reference to the LUT 15b. Therefore, the converted data is data that has already been subjected to ink amount compensation.
[0061]
When the color conversion module 21b performs color conversion to generate KCMYlclm data in which the amount of ink has been compensated, the halftone processing module 21c is activated in step S150, and the KCMYlclm data is transferred to the halftone processing module 21c. The halftone processing module 21c converts the KCMYlclm data by a dither method, and generates head drive data for attaching ink at the converted recording density. The print data generation module 21d receives the head drive data and rearranges the data in the order used by the printer 40 in step S160. Then, the rearranged data is output as print data.
[0062]
(2) Comparison between a case where the ink amount fluctuation is compensated and a case where the ink amount fluctuation is not compensated:
As described above, in the printing result when printing is performed, the fluctuation of the ink ejection amount due to the unstable ink surface is compensated. A description will be given in comparison with the case where no compensation is performed. FIG. 8 is an explanatory diagram for explaining a case where the ink amount variation is compensated and a case where the ink amount variation is not compensated. FIG. 3 shows a time-series flow in which data is processed from left to right, and shows a case where ink amount compensation is not performed on the upper side and a case where ink amount compensation is performed on the lower side.
[0063]
When the ink amount is not compensated, the RGB data is converted into KCMYlclm data by referring to an intermediate table generated from the LUT 15b, and each main scan is performed by halftone processing and nozzle data conversion processing. With respect to the line, the data of “0” and “1” becomes a continuous bit string R. In the bit string R, when two or more “1” s are continuous at a specific resolution, ink is ejected in a situation where the ink surface is unstable. Therefore, by waiting for the ink surface to stabilize, the ink ejection amount fluctuates as compared with the case where the printing speed is reduced and printing is performed.
[0064]
On the other hand, when compensating for the ink amount, when the LUT 15b is developed in the intermediate table, the KCMYlclm data is changed to K'C'M'Y'lc 'using the occurrence ratio data 15c and the fluctuation ratio data 42a. It is corrected to lm 'data. Accordingly, the RGB data constituting the input image is converted into K'C'M'Y'lc'lm 'data different from the KCMYlclm data by color conversion with reference to the corrected intermediate table. The K'C'M'Y'lc'lm 'data is data for which the ink amount has been compensated, and is subjected to halftone processing and nozzle data conversion processing to obtain "0" for each main scanning line. "1" data becomes a continuous bit string R '.
[0065]
Here, comparing both the case where the ink amount compensation is performed and the case where the ink amount compensation is not performed, even if the same RGB data is processed, the bit string finally generated is different. Also in the former case, since the bit string R 'includes a bit string in which "1" is continuous, when printing is performed using this data, the amount of ink differs depending on whether "1" is continuous or not. . However, since this data is generated by executing a color conversion process or the like after correcting the LUT 15b, it is data that takes into account ink amount fluctuations. That is, in the case of the present embodiment, the bit string R shown in the upper right of FIG. 8 and the bit string R ′ shown in the lower right of FIG. Minute difference. Therefore, it is possible to obtain a printing result in which the fluctuation of the ink amount is compensated.
[0066]
In the present invention, since it is only necessary to be able to compensate for the fluctuation in the amount of ink caused by the instability of the ink surface, the volume of the ink droplet may be adjusted each time by changing the applied voltage pattern. However, although the volume of the ink droplet is not changed as in the present embodiment, if a configuration in which the correction is performed at the time of the KCMYlclm data is adopted, a slight series of printing processes and the same configuration of the printer as in the related art can be performed. Compensation can be performed only by correcting data, and fine adjustment such as changing the applied voltage pattern is not required, and high-quality printing can be performed very easily.
[0067]
(3) Other embodiments:
In the present invention, it is only necessary to be able to compensate for the fluctuating ink amount due to the unstable ink surface, and the configuration according to the first embodiment is not essential. A configuration can be employed.
For example, in the halftone processing module 21c, the halftone processing is performed using the dither method. However, various dither matrices can be used in the dither method. Techniques can be used. In any case, if the method of the halftone processing is determined, the bit string after the halftone processing and the nozzle data conversion processing can be specified for each value of the KCMYlclm data as the conversion result in the color conversion module 21b. The occurrence ratio data 15c can be specified.
[0068]
Of course, a halftone processing method may be configured to be selectable on the property screen of the printer driver 21 or the like, and the occurrence ratio data 15c corresponding to the selected method may be used. It is not essential that the halftone processing module 21c converts each dot into binary. For example, it may be converted into four values. In other words, the present invention may be applied to a case where gradation is expressed in four states, that is, a state in which ink is not ejected for each dot and a state in which ink is ejected at large, medium, and small dot diameters (difference in ink amount).
[0069]
In this case, for example, two bits are assigned to one dot as data after the halftone processing, and each of “00”, “01”, “10”, and “11” expresses non-ink ejection and small-medium-large dot ejection. In such a configuration, when ink is ejected with an unstable ink surface when continuously ejecting ink from adjacent dots, “01”, “10”, and “11” are repeated twice or more. Whether or not to perform the ink amount compensation can be determined depending on whether or not to perform the ink amount compensation.
[0070]
Since the ink surface vibration varies depending on the dot diameter of the ejected ink, the ink amount at the time of continuous ejection at each dot diameter is measured, and if the fluctuation rate data 42a is used, the ejection occurrence rate data at each dot diameter is calculated. By recording 15c, the ink amount can be compensated according to the diameter of the continuous dot. Of course, the vibration varies depending on the dot diameter, and in the case of a small dot, the ink surface is not ejected in an unstable state, but in the case of a large dot, the ink surface is ejected in an unstable state. In this case, the ink amount may be compensated only for the ink ejected with the ink surface being unstable during continuous ejection.
[0071]
In the first embodiment described above, the case where the full overlap processing is performed as the print mode and the case where the full overlap processing is not performed have been described. However, the present invention is applicable to all cases that may affect the amount of ink ejected when the ink surface is unstable. Print mode. That is, when the fluctuation ratio data 42a and the generation ratio data 15c fluctuate due to the difference in the printing mode, the fluctuation ratio data 42a and the generation ratio data 15c are stored for each printing mode, and the ink corresponding to the printing mode is stored. A quantity compensation may be performed.
[0072]
Furthermore, in the first embodiment, the color conversion module 21b performs the correction by the ink amount correction module 21b1 at the stage where the LUT 15b is developed and made into an intermediate table. However, it is necessary to perform the correction at this stage. is not. For example, the above-described I-I-C-D may be applied without correction at the stage of the intermediate table, and assuming that each image data after color conversion by the color conversion module 21b is I. In this example, since the ink amount is compensated for each of the pixels after the color conversion, the ink amount can be specified with an accurate compensation amount for each pixel. On the other hand, in the first embodiment, since the correction is performed at the stage of the intermediate table, it is not necessary to perform the correction for the total number of pixels of the image data. Since ink amount compensation is performed for all pixels, high-speed processing is possible.
[0073]
Further, in the printer 40, six colors of KCMYlclm can be used, but four or seven colors may be used, and the number of colors is not limited. In the first embodiment, the computer 10 performs the process for compensating the ink amount. However, the process may be performed in the printer 40 or the distributed process may be performed by various computers. Further, the fluctuation ratio data 42a and the occurrence ratio data 15c may be obtained at the time of correction, and the storage location is not particularly limited.
[0074]
Further, in the first embodiment, by measuring the amount of ink ejected when the ink surface is stable and the amount of ink ejected when the ink surface is unstable, the ink amount is calculated based on the fluctuation ratio between the two. Although variations have been compensated for, other configurations may be employed. That is, in the first embodiment, the ink ejection amount in a state where the ink surface is stable is set as the predetermined reference ink ejection amount, but various other standards can be adopted as the reference.
[0075]
For example, a configuration may be adopted in which a certain specific machine is used as a standard machine and ink amount fluctuations between the standard machine and the machine to be subjected to ink amount compensation are compensated. In this case, an LUT 15b or the like is created in consideration of continuous ink ejection (ink amount fluctuation due to ink surface instability) in a standard machine, and the ink amount is compensated for in a machine to be subjected to ink amount compensation using the LUT 15b or the like. The printing is performed by the continuous discharge and the non-continuous discharge, and the fluctuation ratio of both is grasped. Then, it is possible to adopt a configuration in which the amount of ink is compensated for in the same manner as described above by the occurrence ratio and the fluctuation ratio during continuous ejection of ink. Of course, in the standard machine, the same ink amount compensation as in the first embodiment is performed, and the difference in the ejection amount from the standard machine is measured in another machine, so that the difference from the standard machine can be compensated. It may be configured to execute.
[0076]
Further, since the viscosity of the ink has a temperature dependency, it is considered that the instability of the ink surface is affected by the temperature, and compensation may be performed in consideration of such an influence of the temperature. For example, the ink is ejected while changing the temperature of the ink, the fluctuation ratio data 42a is stored for each temperature of the ink, and a temperature sensor is provided for the head in which the nozzles are formed. It is possible to adopt a configuration in which the temperature is acquired and the ink amount is compensated using the fluctuation ratio data 42a corresponding to the acquired temperature of the ink. Needless to say, the temperature sensor may be any sensor as long as the temperature of the ink can be obtained directly or indirectly.
[0077]
Further, it is of course possible to adopt a configuration in which the amount of ink is compensated by changing the applied voltage pattern instead of correcting the data as in the first embodiment. In this case, in the computer 10, the color conversion module 21b, the halftone processing module 21c, and the print data generation module 21d do not constitute the ink amount correction module 21b1 and do not perform the correction based on the occurrence ratio data 15c and the fluctuation ratio data 42a. Is performed, and the print data is transferred to the printer 40 in a state where the ink amount fluctuation is not compensated.
[0078]
In the printer 40, the variation ratio data 42a indicating the variation ratio D is also stored in the ROM 42. Then, the transferred print data is buffered in the RAM 43, and the ratio Nr of continuously ejecting ink for all nozzle rows or each color nozzle row is measured with reference to the buffered data. Then, the ink fluctuation amount D · Nr is calculated with reference to the fluctuation ratio data 42a, and data indicating the ink fluctuation amount D · Nr is output to the ASIC 44.
[0079]
The ASIC 44 generates an applied voltage pattern for driving the piezo element PE so as to eject ink droplets of an amount compensating for the ink fluctuation amount D · Nr. As a result, the head drive unit 49 can generate ink droplets with the ink amount compensated for the ink amount fluctuation. The ASIC 44 may store in advance an applied voltage pattern for ejecting ink droplets of an amount compensating for the variation amount D · Nr, or a typical variation amount and an applied voltage pattern for compensating the variation amount. It is also possible to store a table, profile, or the like that defines the correspondence between them and calculate an appropriate applied voltage pattern sequentially.
[0080]
Of course, in such a configuration, when calculating the ratio Nr for all the nozzle arrays, the average value of the ink amount fluctuations in all the nozzle arrays may be obtained in advance and used as the fluctuation ratio data 42a indicating the fluctuation ratio D. When the ratio Nr is calculated for each color nozzle row, a configuration in which the fluctuation rate data 42a indicating the fluctuation rate D is stored for each color nozzle row can be adopted. Further, in this configuration, since the drive voltage is adjusted for every nozzle or for each nozzle row, the amount of each ink droplet ejected from each nozzle is not individually compensated. This means that the amount of ink is compensated.
[0081]
As described above, various other configurations can be adopted as the configuration for adjusting the applied voltage pattern to the piezo element PE. For example, in the ASIC 44, an applied voltage pattern when ink is ejected in a state where the ink surface is stable, and an ink ejection amount in a case where the ink surface is stable when the ink is ejected when the ink surface is unstable. An application voltage pattern for performing the same amount of discharge is configured to be able to be generated, and it is determined from the data buffered by the printer 40 whether or not the discharge at each dot is a continuous discharge. If discontinuous, the piezo element is driven with the former applied voltage pattern, and if continuous, the piezo element is driven with the latter applied voltage pattern. According to such a configuration, it is possible to perform ejection in a state where ink amount variation is compensated for each ink droplet ejected from each nozzle. Of course, in this configuration, when the ink amount varies depending on the print mode and conditions, it is configured to generate more applied voltage patterns, and the ink is ejected with the corresponding applied voltage patterns as appropriate. Such a configuration is also possible.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a schematic hardware configuration of a system constituting a print control apparatus.
FIG. 2 is a diagram illustrating a schematic hardware configuration of a printer.
FIG. 3 is a diagram illustrating an ink ejection unit of the print head.
FIG. 4 is a diagram illustrating a state in which an ink surface vibrates.
FIG. 5 is a diagram illustrating a schematic configuration diagram of a main control system of the printing apparatus.
FIG. 6 is a diagram illustrating an example of an occurrence ratio.
FIG. 7 is a flowchart of a print control process.
FIG. 8 is an explanatory diagram for explaining a case where ink amount fluctuation is compensated and a case where ink amount fluctuation is not compensated.
[Explanation of symbols]
10 ... Computer
11 CPU
12. System bus
13 ROM
14 ... RAM
15 ... Hard disk drive (HDD)
15a: Image data
15b ... LUT
15c: Occurrence ratio data
16 ... Flexible disk drive
17 CD-ROM drive
18 ... Display
20 ... OS
21: Printer driver (PRTDRV)
21a ... Image data acquisition module
21b ... Color conversion module
21b1: Ink amount correction module
21c: Halftone processing module
21d Print data generation module
22 Input device driver (DRV)
23 ... Display driver (DRV)
25 ... Application program (APL)
31 ... Keyboard
32 ... Mouse
40 ... Printer
41 ... CPU
42 ... ROM
42a: Fluctuation ratio data
43 ... RAM
44… ASIC
45 ... Control IC
47a ... Carriage mechanism
47b… Paper feed mechanism
48a to 48f: Ink cartridge
48g… Ink chamber
49 ... Head drive unit

Claims (15)

A print control device that controls a printing device including a head having a plurality of nozzles that eject ink,
When the ink is ejected again while the ink surface of the nozzle is unstable after the ink has been ejected, the ink amount is compensated for by an ink amount that fluctuates from a predetermined reference ink ejection amount due to the unstable ink surface. A printing control device comprising: a head driving unit that drives the head so as to discharge droplets. 2. The head driving unit according to claim 1, wherein the head driving unit discharges ink droplets with the compensated ink amount when continuously discharging ink while driving the head in the main scanning direction. Print control device. Fluctuation ratio between the ink amount when the ink surface is ejected with the ink surface being stable and the ink amount when the ink is ejected with the ink surface being unstable, and the ink amount when the ink surface is unstable The generated ink generation rate is stored in a predetermined storage medium, and the head driving means compensates for the above by increasing / decreasing an amount obtained by multiplying the fluctuation rate and the generation rate from the predetermined reference ink ejection amount. 3. The print control device according to claim 1, wherein the amount of ink is determined. The head driving unit includes a color conversion unit that performs color conversion of image data used in another image device into ink amount data that specifies an ink amount mounted on a printing apparatus, and performs color conversion by the color conversion unit. 4. The print control apparatus according to claim 3, wherein an amount obtained by multiplying the fluctuation rate and the generation rate from the ink amount data to be obtained is increased or decreased. The head driving unit includes a color conversion unit that performs color conversion of image data used by another image device into ink amount data that specifies an ink amount mounted on a printing apparatus. The printing according to any one of claims 1 to 3, wherein the color conversion is executed with reference to reference color image data that defines a correspondence relationship with the ink amount data that specifies the compensated ink amount. Control device. The print control device according to claim 1, wherein the head driving unit compensates for an ink amount that fluctuates from the reference ink discharge amount by increasing or decreasing the number of ejected ink droplets. The head is provided with a micropump mechanism that causes a change in the volume of an ink chamber by an applied voltage, and the head driving unit can discharge ink droplets from the nozzles by controlling the applied voltage. The printing according to any one of claims 1 to 5, wherein the amount of the ejected ink droplet is increased or decreased by adjusting a level to compensate for an ink amount that fluctuates from the predetermined reference ink ejection amount. Control device. 8. The print control apparatus according to claim 1, wherein the predetermined reference ink ejection amount is an ink amount when the ink is ejected in a state where the ink surface is stable. 8. The ink supply device according to claim 1, wherein the predetermined reference ink ejection amount is an ink amount when the ink is ejected in a state where the ink surface is unstable in a specific standard machine. Print control device. Temperature information obtaining means for obtaining the temperature information of the ink, wherein the head driving means refers to the temperature information obtained by the temperature information obtaining means, and discharges ink droplets with a different ink amount for each temperature. The print control device according to claim 1. An applied voltage corresponding to image data is applied to a printing apparatus having a head that performs printing by discharging ink droplets from nozzles by a micropump mechanism that generates a volume change of an ink chamber by an applied voltage generated at a predetermined cycle timing. A print control device that performs control for generating
An ink amount variation information storage unit configured to store ink amount variation information indicating a variation between a second or subsequent ejection ink amount and a predetermined reference ink ejection amount when continuously ejecting ink droplets to adjacent pixels;
An occurrence ratio information storage unit that stores occurrence ratio information indicating a ratio at which the continuously ejected ink droplets are generated at each gradation value of the image data;
Compensated image data generating means for generating compensated image data reflecting the ink amount variation compensation amount at each gradation value of the image data calculated from the ink amount variation information and the occurrence ratio information;
A print control device for controlling the generation of the applied voltage in accordance with the compensated image data. A print control program for controlling a printing apparatus including a head having a plurality of nozzles for discharging ink,
When the ink is ejected again while the ink surface of the nozzle is unstable after the ink has been ejected, the ink amount is compensated for by an ink amount that fluctuates from a predetermined reference ink ejection amount due to the unstable ink surface. A print control program for causing a computer that controls a printing apparatus to realize a head driving function of driving the head so as to discharge droplets. An applied voltage corresponding to image data is applied to a printing apparatus having a head that performs printing by discharging ink droplets from nozzles by a micropump mechanism that generates a volume change of an ink chamber by an applied voltage generated at a predetermined cycle timing. A print control program for performing control for generating,
An ink amount variation information storage function of storing ink amount variation information indicating variation between the second and subsequent ejection ink amounts and a predetermined reference ink ejection amount when continuously ejecting ink droplets to adjacent pixels;
An occurrence ratio information storage function of storing occurrence ratio information indicating a ratio of occurrence of the continuously ejected ink droplets at each gradation value of image data,
A compensated image data generation function of generating compensated image data reflecting an ink amount variation compensation amount at each gradation value of image data calculated from the ink amount variation information and the occurrence ratio information;
A print control program for causing a computer to realize an applied voltage control function for performing control for generating the applied voltage according to the compensated image data. A printing control method for controlling a printing apparatus that performs printing by discharging ink from a plurality of nozzles,
When the ink is ejected again while the ink surface of the nozzle is unstable after the ink has been ejected, the ink amount is compensated for by an ink amount that fluctuates from a predetermined reference ink ejection amount due to the unstable ink surface. A printing control method, characterized by discharging droplets. An applied voltage corresponding to image data is applied to a printing apparatus having a head that performs printing by discharging ink droplets from nozzles by a micropump mechanism that generates a volume change of an ink chamber by an applied voltage generated at a predetermined cycle timing. A print control method for performing control for generating, comprising:
Ink amount fluctuation information and an image stored in a predetermined storage medium and indicating the fluctuation between the second and subsequent discharge ink amounts and a predetermined reference ink discharge amount when continuously discharging ink droplets to adjacent pixels. The ink amount variation compensation amount at each gradation value of the image data is calculated from the occurrence ratio information indicating the ratio at which the continuously ejected ink droplets are generated at each gradation value of the data, and the ink amount variation compensation amount is calculated. A print control method comprising: generating compensated image data that is reflected and performing control for generating the applied voltage according to the compensated image data.

Images