阅读说明：本技术 消除喷头拼接道的方法、装置、设备及存储介质 (Method, device and equipment for eliminating nozzle splicing channel and storage medium ) 是由 何伟 陈艳 黄中琨 于 2020-06-30 设计创作，主要内容包括：本发明涉及喷墨打印技术领域,具体涉及一种消除喷头拼接道的方法、装置、设备及存储介质。所述方法包括：获取打印数据集,打印数据集包括第一数据集和第二数据集；对第一数据集和第二数据集进行处理,得到第一抽点数据集和第二抽点数据集；第一抽点数据集对应的喷墨量少于第一数据集对应的喷墨量,第二抽点数据集对应的喷墨量少于所述第二数据集对应的喷墨量；其中,第一抽点数据集用于驱动第一喷头打印待打印图像中的第一区域,第二抽点数据集用于驱动第二喷头打印待打印图像中的第二区域；第一区域和第二区域之间的间距小于等于设定距离。本发明能够在一定程度上消除喷头拼接位置的黑道,提升图像的打印效果。(The invention relates to the technical field of ink-jet printing, in particular to a method, a device, equipment and a storage medium for eliminating a nozzle splicing channel. The method comprises the following steps: acquiring a printing data set, wherein the printing data set comprises a first data set and a second data set; processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than that corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than that corresponding to the second data set; the first snapshot data set is used for driving a first nozzle to print a first area in the image to be printed, and the second snapshot data set is used for driving a second nozzle to print a second area in the image to be printed; the distance between the first area and the second area is smaller than or equal to a set distance. The invention can eliminate the black channel at the splicing position of the spray head to a certain extent and improve the printing effect of the image.)

1. A method of eliminating a nozzle splice channel, the method comprising:

acquiring a print data set, wherein the print data set comprises a first data set and a second data set;

processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set;

the first snapshot data set is used for driving a first nozzle to print a first area in the image to be printed, and the second snapshot data set is used for driving a second nozzle to print a second area in the image to be printed; the distance between the first area and the second area is smaller than or equal to a set distance.

2. The method of claim 1, wherein the first spray head is adjacent to the second spray head and the first spray head and the second spray head overlap at a nozzle portion of the splice.

3. The method of claim 1, wherein the first data set and/or the second data set comprises: image dot matrix data including a data set of one or more control nozzles ejecting the first set amount of ink, the data set in the image dot matrix data corresponding to each pixel of an original image, the first set amount being greater than 0;

processing the first data set and the second data set, including:

changing one of the image dot matrix data to the data set in which the corresponding ink ejection amount is smaller than the first set amount, the data set being adjacent to at least one of the data sets in which the corresponding ink ejection amount is smaller than the first set amount before the change;

the data set includes one or more data of the image dot matrix data.

4. The method according to claim 3, wherein changing a data set in the image dot matrix data, which controls the nozzles to eject the ink in the first set amount and which is adjacent to at least one data set in which the ink ejection amount is the first set amount, to the data set in which the corresponding ink ejection amount is smaller than the first set amount comprises:

and changing one data set in the image dot matrix data into the corresponding data set with the ink jetting amount of 0, wherein the ink jetting amount corresponding to the data set before the change is the first set amount, and the data set is adjacent to at least two data sets with the ink jetting amount of the first set amount.

5. The method according to claim 3, wherein changing a data set in the image dot matrix data, which controls the nozzles to eject the ink in the first set amount and which is adjacent to at least one data set in which the ink ejection amount is the first set amount, to the data set in which the corresponding ink ejection amount is smaller than the first set amount comprises:

changing one data set in the image dot matrix data to a data set in which the corresponding ink ejection amount is the second set amount, wherein the ink ejection amount corresponding to the data set before the change is the first set amount, and the data set is respectively adjacent to one data set in which the corresponding ink ejection amount is the first set amount and at least two data sets in which the corresponding ink ejection amount is the second set amount;

the second set amount is greater than 0, and the second set amount is less than the first set amount.

6. The method according to any one of claims 3 to 5, wherein changing one of said data sets in said image dot matrix data to said data set corresponding to said ink ejection amount smaller than said first set amount, said ink ejection amount corresponding to said data set before the change being said first set amount, and said data set being adjacent to at least one of said data sets corresponding to said ink ejection amount being said first set amount, comprises:

aiming at a data set which is adjacent to a data set of which the corresponding ink jet amount is the first set amount and at least one corresponding ink jet amount is the first set amount in the image dot matrix data, acquiring a feathering data set corresponding to the data set, wherein the feathering data set corresponding to the data set is different from the data set;

and performing logical operation on the data set and the eclosion data set to obtain a data set with the corresponding ink jet amount less than that of the data set.

7. The method of claim 3, wherein the first dataset and the second dataset are processed to obtain a first snapshot dataset and a second snapshot dataset; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and after the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, the method further includes:

judging whether the quantity of the data of the first set amount of ink sprayed by the first snapshot data centralized control nozzle is greater than a first preset value or not;

if the number is larger than the first preset value, the data of the first snapshot data which control the nozzles to eject the first set amount of ink in a centralized manner are reprocessed, so that the number of the nozzles which eject the first set amount of ink in the centralized manner according to the reprocessed first snapshot data is not larger than the first preset value;

the first preset value is a positive integer.

8. The method according to claim 1, wherein the print data set comprises data controlling nozzles to eject four set amounts, a fifth set amount of ink;

processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, including:

processing a portion of the data for controlling the nozzles to eject a fourth set amount of ink in the first data set and the second data set;

controlling the nozzle to jet partial data of a fifth set amount of ink in the first data set and the second data set to process to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set;

the fifth set amount is greater than 0, and the fourth set amount is greater than the fifth set amount.

9. An apparatus for eliminating a nozzle splice channel, the apparatus comprising:

an acquisition module for acquiring a print data set, the print data set comprising a first data set and a second data set;

the first processing module is used for processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set;

the first snapshot data set is used for driving a first nozzle to print a first area in the image to be printed, and the second snapshot data set is used for driving a second nozzle to print a second area in the image to be printed; the distance between the first area and the second area is smaller than or equal to a set distance.

10. An apparatus for eliminating a nozzle splice channel, the apparatus comprising:

at least one processor; and

a memory communicatively coupled to the at least one processor; wherein the content of the first and second substances,

the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the method of any one of claims 1-8.

11. A computer storage medium having computer program instructions stored thereon, wherein,

the computer program instructions, when executed by a processor, implement the method of any one of claims 1-8.

Technical Field

The invention relates to the technical field of ink-jet printing, in particular to a method, a device, equipment and a storage medium for eliminating a nozzle splicing channel.

Background

At present, in the working process of an industrial ink-jet printer, a printer nozzle sprays ink drops to form pictures and texts in an image to be printed. In the area where the two spray heads are spliced, because the trolley moves during printing, a wind wall is easily formed at the spliced part of the two spray heads. Because the air flow speed in the air wall is higher than the air flow speed around, the air pressure is lower, ink drops ejected from the holes at the edge of the splicing part of the two nozzles are easily sucked into the air wall and are overlapped in a cross way, so that the ink volume concentration at the overlapping part is higher than that around, and a splicing channel with dark color is visually formed, which is called as a black channel.

The black stripes seriously affect the display effect of the printed image and seriously degrade the printing quality of the image.

Disclosure of Invention

The embodiment of the invention provides a method, a device, equipment and a storage medium for eliminating a nozzle splicing channel. The method, the device, the equipment and the storage medium for eliminating the nozzle splicing channels can prevent the formation of black channels at the nozzle splicing positions to a certain extent, and improve the printing effect of images.

In a first aspect, an embodiment of the present invention provides a method for eliminating a nozzle splice channel, where the method includes:

acquiring a print data set, wherein the print data set comprises a first data set and a second data set;

processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set;

the first snapshot data set is used for driving a first nozzle to print a first area in the image to be printed, and the second snapshot data set is used for driving a second nozzle to print a second area in the image to be printed; the distance between the first area and the second area is smaller than or equal to a set distance.

In a second aspect, an embodiment of the present invention provides an apparatus for eliminating a nozzle splice, where the apparatus includes:

an acquisition module for acquiring a print data set, the print data set comprising a first data set and a second data set;

the first processing module is used for processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set;

the first snapshot data set is used for driving a first nozzle to print a first area in the image to be printed, and the second snapshot data set is used for driving a second nozzle to print a second area in the image to be printed; the distance between the first area and the second area is smaller than or equal to a set distance.

In a third aspect, an embodiment of the present invention provides an apparatus for eliminating a channel splice of a nozzle, where the apparatus includes:

at least one processor; and

a memory communicatively coupled to the at least one processor; wherein the content of the first and second substances,

the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the method of eliminating a shower head splice channel.

In a fourth aspect, an embodiment of the present invention provides a computer storage medium having computer program instructions stored thereon, wherein the computer program instructions, when executed by a processor, implement the method for eliminating a nozzle splice channel.

In summary, according to the method, the apparatus, and the device for eliminating the nozzle splicing channel provided in the embodiments of the present invention, the first data set and the second data set are processed to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than that corresponding to the first data set, the ink jetting amount corresponding to the second snapshot data set is less than that corresponding to the second data set, black channels can be prevented from being generated at the splicing position of the spray heads to a certain extent, and the printing effect of the image is improved.

Drawings

FIG. 1 is a schematic diagram of the printing effect of the splicing position of the nozzles when printing according to the prior art;

FIG. 2 is a schematic flow chart illustrating a method for eliminating a channel splice from a showerhead in an embodiment of the present invention;

FIG. 3 is a schematic view of a connecting structure of two adjacent nozzles according to the present invention;

fig. 4 is a schematic flow chart of steps involved in step S2 in fig. 2 for reducing the amount of ink ejected according to the processed image dot data by performing a logical operation using the feathered data set and the data set in the image dot data.

5-6 are schematic diagrams of application scenarios of data processing by using the method for eliminating the nozzle splicing channel provided by the invention;

fig. 7 is a flowchart of steps included in step S2 for making the number of nozzles ejecting a first set amount of ink according to the processed print data set not greater than a first preset value;

fig. 8 is a flowchart of steps included in step S2 for making the number of nozzles for ejecting a second set amount of ink according to the processed print data set not larger than a second preset value;

fig. 9 is a flowchart of steps included in step S2 for making the number of nozzles for ejecting a third set amount of ink according to the processed print data set not greater than a third preset value;

fig. 10 is a flowchart illustrating steps involved in processing the first data set and the second data set in step S2;

FIG. 11 is a schematic view of a connection of an apparatus for eliminating a nozzle patch channel in an embodiment of the present invention;

FIG. 12 is a schematic view showing the connection of sub-modules included in the first processing module of FIG. 11 for performing a logical operation using the feathered data set and the data set in the image dot matrix data to reduce the amount of ink ejected according to the processed image dot matrix data;

FIG. 13 is a schematic connection diagram of sub-modules included in the first processing module of FIG. 11 for processing data for controlling the nozzles to eject ink in a first set amount and a second set amount, respectively;

FIG. 14 is a schematic diagram of the connection of modules included in the print data set after processing to enable the number of nozzles ejecting a first set amount of ink to be no greater than a first preset value;

FIG. 15 is a schematic view of the connection of the components of an apparatus for eliminating a shower head splice channel in one embodiment of the present invention.

Detailed Description

Features and exemplary embodiments of various aspects of the present invention will be described in detail below, and in order to make objects, technical solutions and advantages of the present invention more apparent, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not to be construed as limiting the invention. It will be apparent to one skilled in the art that the present invention may be practiced without some of these specific details. The following description of the embodiments is merely intended to provide a better understanding of the present invention by illustrating examples of the present invention.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

At present, in the working process of an industrial ink-jet printer, a printer nozzle sprays ink drops to form pictures and texts in an image to be printed. In the area where the two spray heads are spliced, because the trolley moves during printing, a wind wall is easily formed at the spliced part of the two spray heads. Because the air flow speed in the air wall is higher than the air flow speed around, the air pressure is lower, ink drops ejected from the holes at the edge of the splicing part of the two nozzles are easily sucked into the air wall and are overlapped in a cross way, so that the ink volume concentration at the overlapping part is higher than that around, and a splicing channel with dark color is visually formed, which is called as a black channel.

As shown in fig. 1, the dotted rectangle in the figure indicates that, during printing, due to the influence of external factors, two rows of ink drops fall on the back of the dot, and overlapped ink dots appear, visually presenting an elongated "black channel" with a darker color than the surroundings.

The invention provides a method, a device, equipment and a storage medium for eliminating a nozzle splicing channel, which can solve the phenomenon of ink dot overlapping to a certain extent.

An embodiment of the present invention provides a method for eliminating a nozzle splicing channel, as shown in fig. 2, the method includes the following steps S1-S2.

Step S1: a print data set is obtained, the print data set including a first data set and a second data set.

The first data set corresponds to a first area in the image to be printed and is used for controlling the first nozzle to print the first area. The second data set corresponds to a second region in the image to be printed for controlling the second nozzle to print the second region. The first spray head is adjacent to the second spray head, and the first spray head and the second spray head are spliced and overlapped. The distance between the first area and the second area is smaller than or equal to a set distance. The set distance is equal to or greater than 0.

The print data set includes data for controlling the ejection of ink from the head. During printing, the ink jetting amount of the nozzle is controlled by the printing data set.

In the printing process, the nozzles in the spray head respectively print different areas in the image to be printed. The amount of ink ejected by the heads in each of the different areas may be different for printing to form the image to be printed. When the ink quantities of two areas in the image to be printed are different, the printing data sets respectively corresponding to the two areas are controlled to be different by the nozzle.

The method comprises the steps that a printing data set is obtained, wherein the printing data set comprises a first data set and a second data set, and the first data set and the second data set can be processed to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set.

In the printing process, in order to improve the printing speed, a plurality of spray heads are usually spliced and are simultaneously printed by utilizing the plurality of spray heads which are spliced into a whole. And a black channel is printed and formed on the area of the printing medium corresponding to the splicing position of the two adjacent spray heads. The printing data set corresponding to the area below the nozzle splicing position in the printing process in the image to be printed is obtained, and the printing data set is processed, so that the black channel generated in the area below the nozzle splicing area in the printing process in the image to be printed can be prevented.

And a boundary between the first area and the second area is positioned below the splicing position of two adjacent spray heads, and a black channel is printed and formed at the boundary between the first area and the second area in the printing process.

In one embodiment, the first area is located in an area of the image to be printed, which is printed by one of two adjacent nozzles, and a distance between the first area and a boundary of the second area is smaller than a fifth setting value. Said fifth set value is equal to 0.5 mm.

In an embodiment, the second area is located in an area printed by one of two adjacent nozzles in the image to be printed, and a distance between the second area and a boundary between the first area and the second area is smaller than a sixth preset value. Said sixth set value is equal to 0.5 mm.

In one embodiment, as shown in fig. 3, two adjacent nozzles include a first nozzle 1 and a second nozzle 2. In order to increase the printing speed, the first nozzle 1 and the second nozzle 2 are usually spliced to print. The first spray head 1 is one of two adjacent spray heads, and the second spray head 2 is the other of the two adjacent spray heads. The spliced first nozzle 1 and the spliced second nozzle 2 usually have nozzles with overlapped printing areas in normal printing. The first head 1 has a first boundary line 4 at a position adjacent to the second head 2. The first spray head 1 further comprises a third borderline 8 parallel to the first borderline 4. The second sprinkling head 2 has a second borderline 3 at a position adjacent to the first sprinkling head 1. The second sprinkling head 2 further comprises a fourth borderline 9 parallel to the second borderline 3. The first boundary line 4 and the second boundary line 3 are both parallel to the paper feed direction 6. A centre line 5 is present between the first 4 and the second 3 border line. The centre line 5 is at the same distance from the first boundary line 4 and from the second boundary line 3 in a direction perpendicular to the direction of paper feed 6.

The paper feeding direction 6 is a relative moving direction of the printing medium and the first head 1.

The first head 1 prints with nozzles located between the centre line 5 and the third borderline 8. The second head 2 prints with nozzles located between the centre line 5 and the fourth borderline 9. The borderlines of the first and second areas coincide with the centre line 5. The edge lines at a distance m from the boundary line coincide with a first straight line 10 below the centre line 5 and with a second straight line 7 above the centre line 5, respectively, m being 0.5 mm. The first area and the second area are located directly below the area between the first line 10 and the middle line 5 and the area between the second line 7 and the middle line 5, respectively, in the image to be printed. The dots within the dashed box in fig. 1 are located directly below the center line 5.

Step S2: processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set.

The black mark formed by printing at the position of the boundary line between the first area and the second area in the image to be printed is caused by a large amount of ink ejected to the boundary line. By processing the first data set and the second data set, the ink ejection amount of the first area and the second area can be reduced, and the black track is prevented from being printed at the boundary of the first area and the second area.

In one embodiment, the print data set includes data that controls the nozzles to eject a first set amount of ink.

In step S2, processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, including: controlling the nozzle to jet partial data of a first set amount of ink in the first data set or the second data set to process to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set. The first set value is greater than 0.

During printing, each data in the first data set and the second data set respectively controls a nozzle in the spray head to spray ink. The ink ejected from each nozzle solidifies to form dots in the image to be printed. The ink dots formed by the nozzles in different areas of the image to be printed constitute the image to be printed.

The size of the ink dots formed by ejection in the image to be printed may vary. When the head performs one ejection, data for controlling one nozzle is different from data for controlling the other nozzles, and the amount of ink ejected from the nozzle may be different from the amount of ink ejected from the other nozzles. By modifying the print data set, the amount of ink ejection from the nozzles controlled by the print data set can be changed.

The first set amount is an amount of ink ejected by the nozzles under control of the print data set. When the print data set includes data for controlling the nozzles to eject a first set amount of ink, the nozzles in the head will eject ink drops of the first set amount under control of the data for controlling the nozzles to eject ink of the first set amount during printing.

Controlling the nozzle to jet partial data of a first set amount of ink in the first data set or the second data set to process to obtain a first snapshot data set and a second snapshot data set; the ink ejection amount corresponding to the first snapshot data set is less than the ink ejection amount corresponding to the first data set, the ink ejection amount corresponding to the second snapshot data set is less than the ink ejection amount corresponding to the second data set, and the data for controlling the ejection of the first set amount of ink can be changed into the data for controlling the nozzles not to eject the ink or the data for controlling the nozzles to eject the amount of ink smaller than the first set amount, so that the purpose of preventing the generation of black channels below the head splicing position can be achieved.

In one embodiment, the first data set and/or the second data set comprises: image dot matrix data including a data set of one or more control nozzles ejecting the first set amount of ink, the data set in the image dot matrix data corresponding to each pixel of an original image, the first set amount being greater than 0.

The original image is processed to form image dot matrix data. The data processing is performed on each pixel in the original image, and image dot matrix data can be processed and formed.

The data group in the image dot matrix data corresponds to each pixel of the original image, and the method comprises the following steps: for any data set in the image dot matrix data, the position order of the data set among the data sets in the image dot matrix data is the same as the position order of the original image pixels processed to form the data set among the pixels in the original image.

If no printing error exists, the original image is the same as the image to be printed which is printed and formed according to the image dot matrix data.

At step S2, the processing of the first data set and the second data set includes: and changing one data set in the image dot matrix data to the data set corresponding to the ink jetting amount smaller than the first set amount, wherein the ink jetting amount corresponding to the data set before the change is the first set amount, and the data set is adjacent to at least one data set corresponding to the ink jetting amount which is the first set amount.

The ink jet amount corresponding to one data set is the ink amount jetted by the nozzle controlled by the data set.

Through will control the nozzle sprays first setting amount printing ink, and with at least one control the nozzle sprays first setting amount printing ink the data set that the data set is adjacent changes into the data set that control nozzle jet printing ink volume is less than first setting amount, can make the image color that prints according to the image dot matrix data after the processing more even, obvious black track or black spot can not appear.

Changing one of the image dot matrix data to the data set in which the corresponding ink ejection amount is smaller than the first set amount, the data set controlling the nozzles to eject the ink in the first set amount before the change, the data set being adjacent to at least one of the data sets in which the corresponding ink ejection amount is the first set amount, includes: traversing each of the data sets in the image dot matrix data, changing any one of the data sets in the image dot matrix data to the data set in which the corresponding ink ejection amount is smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets in which the corresponding ink ejection amount is the first set amount.

The data set includes one or more data of the image dot matrix data.

The image dot matrix data includes a plurality of data sets distributed in an array, each data set corresponding to a nozzle in the head. During printing, the image dot matrix data is stored in an internal buffer provided on the data processing board. And the spray head control module for controlling the spray head sequentially reads the data groups from the internal buffer, and controls the spray head to perform ink jet output action by using the nozzles corresponding to the data groups after reading one data group each time. The data set includes one or more data of the image dot matrix data.

In one embodiment, the image lattice data is generated from raw image processing. The original image is the same as or similar to the image to be printed.

The data sets in the image dot matrix data correspond to the original pixels. When a pixel in an image to be printed is formed by printing one data in the image dot matrix data, the data group includes one data. The position order of any data in the image dot matrix data is the same as the position order of the pixels processed to form the data in the original image. If no printing error exists, the image to be printed which is the same as the original image can be printed in the image to be printed according to the image dot matrix data.

In one embodiment, the image dot matrix data is composed of data sets 00, 01, 10, 11. One line of data in the image dot matrix data corresponds to one row of nozzles in the spray head. And after acquiring a line of data in the image dot matrix data, the spray head control module controls a row of nozzles in the spray head to spray ink by using each data group in the line of data. When the data set corresponding to a nozzle in the nozzle is 00, the nozzle control module controls the nozzle not to eject ink. When a data set received by a nozzle in the nozzle is 01, the nozzle control module controls the nozzle to jet a third set amount of ink. When a data set received by a nozzle in the head is 10, the head control module controls the nozzle to eject a second set amount of ink. When a data set received by a nozzle in the head is 11, the head control module controls the nozzle to eject a first set amount of ink. Wherein the first set amount is greater than the second set amount, which is greater than the third set amount.

The image dot matrix data is obtained from the internal buffer, one or more data groups in the obtained image dot matrix data are processed, the processed image dot matrix data are stored in the internal buffer at the position where the image dot matrix data before processing are stored, the processed image dot matrix data can be used for controlling the spray head to spray, and the ink spraying amount of the spray head sprayed by the processed image dot matrix data is smaller than that sprayed by the image dot matrix data before processing.

The data set includes one or two data of the image dot matrix data.

When the data set includes one data, the data set is 0 or 1, and when the data set is 0, the nozzles do not eject ink under the control of the data; when the data set is 1, the nozzles eject ink under the control of the data.

In one embodiment, when the data set is 00, the nozzles do not eject ink under the control of the data; when the data set is 01, the nozzle ejects a third set amount of ink under the control of the data; when the data set is 10, the nozzle ejects a second set amount of ink under the control of the data; when the data set is 11, the nozzles eject a first set amount of ink under the control of the data.

Traversing each data set in the image lattice data, including: and sequentially processing each data set from a starting data set of the image dot matrix data. The starting data set of the image dot matrix data includes a first data set located on a first line of the image dot matrix data.

Traversing each of the data sets in the image dot matrix data, changing any one of the data sets in the image dot matrix data to the data set in which the corresponding ink ejection amount is smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets in which the corresponding ink ejection amount is the first set amount, includes: the method includes the steps of sequentially processing each of the data sets in image dot matrix data from a start data set of the image dot matrix data, changing any one of the data sets in the image dot matrix data to the data set in which the corresponding ink ejection amount is smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets in which the corresponding ink ejection amount is the first set amount.

In one embodiment, traversing each of the data sets in the image dot matrix data, changing any one of the data sets in the image dot matrix data to the data set corresponding to the ink ejection amount smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets corresponding to the ink ejection amount being the first set amount, includes: the first set of snapshot data and the second set of snapshot data are obtained by sequentially determining each of the data sets in the image dot matrix data from a start data set of the image dot matrix data, determining whether each data set is adjacent to a data set in which at least one control nozzle ejects ink in a first set amount, and if any of the data sets is adjacent to a data set in which at least two control nozzles ejects ink in a first set amount, changing the data set to the data set in which the amount of ink ejected from the control nozzles is smaller than the first set amount.

In one embodiment, as shown in fig. 4, in step S2, changing one of the data sets of the image dot matrix data to the data set corresponding to the ink ejection amount smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets corresponding to the ink ejection amount being the first set amount includes step S21: aiming at a data set which is adjacent to a data set of which the corresponding ink jet amount is the first set amount and at least one corresponding ink jet amount is the first set amount in the image dot matrix data, acquiring a feathering data set corresponding to the data set, wherein the feathering data set corresponding to the data set is different from the data set; step S22: and performing logical operation on the data set and the eclosion data set to obtain a data set with the corresponding ink jet amount less than that of the data set.

The logical operation includes an AND operation, a NOT operation, and the like. The emergence data set includes one or more data.

In one embodiment, the feathered data set contains the same amount of data as the data set to be altered.

In one embodiment, changing one of the data sets in the image dot matrix data to the data set corresponding to the ink ejection amount smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets corresponding to the ink ejection amount being the first set amount includes: and changing one data set in the image dot matrix data into the corresponding data set with the ink jetting amount of 0, wherein the ink jetting amount corresponding to the data set before the change is the first set amount, and the data set is adjacent to at least two data sets with the ink jetting amount of the first set amount.

In one embodiment, changing one of the data sets in the image dot matrix data to the data set corresponding to the ink ejection amount smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets corresponding to the ink ejection amount being the first set amount includes: traversing each data set in the image dot matrix data, changing any one data set in the image dot matrix data into the corresponding data set with the ink jetting amount of 0, wherein the ink jetting amount corresponding to the data set before the change is the first set amount, and the data set is adjacent to at least two data sets with the ink jetting amount of the first set amount.

When the number of data included in a data group and the data group corresponding to the data group is the same, and for any data in the data group, when the data is different from the data in the data group to be changed in the same position order as the data, the data group to be changed and the data group to be changed are subjected to an and operation, and the data group corresponding to the ink ejection amount of 0 can be obtained.

In one embodiment, changing one of the data sets in the image dot matrix data to the data set corresponding to the ink ejection amount smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets corresponding to the ink ejection amount being the first set amount includes: and changing one data set in the image dot matrix data into the data set of which the corresponding ink jetting amount is the second set amount, wherein the ink jetting amount corresponding to the data set before the change is the first set amount, and the data set is respectively adjacent to one data set of which the corresponding ink jetting amount is the first set amount and at least two data sets of which the corresponding ink jetting amount is the second set amount.

If the data set is 11, the nozzle ejects a first set amount of ink under the control of the data set, if the data set for feathering is 10, the data set for feathering and the data set for feathering are subjected to an AND operation, and a data set for 10 is obtained, and the nozzle ejects a second set amount of ink under the control of 10.

In one embodiment, changing one of the data sets in the image dot matrix data to the data set corresponding to the ink ejection amount smaller than the first set amount, the ink ejection amount corresponding to the data set before the change being the first set amount, and the data set being adjacent to at least one of the data sets corresponding to the ink ejection amount being the first set amount includes: traversing each data set in the image dot matrix data, changing any one data set in the image dot matrix data into the data set of which the corresponding ink jetting amount is a second set amount, wherein the ink jetting amount corresponding to the data set before the change is the first set amount, and the data set is respectively adjacent to one corresponding data set of which the ink jetting amount is the first set amount and at least two corresponding data sets of which the ink jetting amount is the second set amount.

As shown in fig. 5, the data set for changing the data set for controlling the nozzles to eject the ink in the first set amount to the data set for controlling the nozzles not to eject the ink includes: the data set is changed from "11" to "00". Traversing each data group in the image dot matrix data, judging the data groups around the data group aiming at any data group of which the image dot matrix data is '11', and if the data groups around the data group comprise at least two '11', changing the data group from '11' to '00'.

The second set amount is greater than 0 and the second set amount is less than the first set amount.

As shown in fig. 6, modifying the data set includes: the data set is changed from "11" to "10". And judging the data groups around any data group of 11, and if the data groups around the data group comprise one data group of 11 and at least one data group of 10, changing the data group from 11 to 10.

In one embodiment, as shown in fig. 7, in step S2, the first data set and the second data set are processed to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and after the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, the method further includes: step S23: judging whether the quantity of the data of the first set amount of ink sprayed by the first snapshot data centralized control nozzle is greater than a first preset value or not; step S24: and if the number is larger than the first preset value, the data of the first snapshot data which collectively control the nozzles to eject the first set amount of ink is reprocessed, so that the number of the nozzles which collectively eject the first set amount of ink according to the reprocessed first snapshot data is not larger than the first preset value.

The first preset value is a positive integer.

In one embodiment, in step S24, if the number is greater than the first preset value, performing reprocessing on the data of the first snapshot data set for controlling the nozzles to eject the first set amount of ink so that the number of nozzles ejecting the first set amount of ink according to the first snapshot data set after reprocessing is not greater than the first preset value includes: acquiring a number d1 of first set amount of ink droplets ejected according to the first snapshot data set, the ink droplets being formed by one ejection from the nozzle; subtracting the first preset value from the quantity d1 to obtain a numerical value d 2; the data set in which the numerical value d2 in the first snapshot data set ejected the first set amount of ink was changed to a data set in which the control nozzles ejected an amount of ink smaller than the first set amount.

In step S2, processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and after the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, the method further includes: judging whether the quantity of the data of the first set amount of ink sprayed by the second snapshot data centralized control nozzle is greater than a fourth preset value or not; and if the number is larger than the fourth preset value, the second snapshot data set controls the nozzles to eject the data of the first set amount of ink to be processed again, so that the number of the nozzles which eject the first set amount of ink in the second snapshot data set after being processed again is not larger than the fourth preset value.

In one embodiment, step S2, processing the first data set and the second data set includes: acquiring first feathering dot matrix data including only a data set for controlling the nozzles not to discharge ink and a data set for controlling the nozzles to eject a first set amount of ink; the first feathered dot matrix data and the image dot matrix data are logically operated to reduce the amount of ink ejected according to the processed image dot matrix data.

The arrangement of the data set of the first set amount of ink ejected by each control nozzle in the first eclosion dot matrix data is different from the arrangement of the data set of the first set amount of ink ejected by each control nozzle in the image dot matrix data before processing.

By making the arrangement of the data group in which each control nozzle ejects the first set amount of ink in the first feathering dot matrix data different from the arrangement in the image dot matrix data before processing, the first feathering dot matrix data and the image dot matrix data are subjected to logical operation so that the amount of ink ejected from the processed image dot matrix data is reduced, and thus processed image dot matrix data with a smaller amount of ejected ink can be obtained. The logical operation comprises an AND operation. The logical operation includes an AND operation.

In one embodiment, the print data set includes: and image dot matrix data including a plurality of data sets for controlling the nozzles to eject the ink in the first and second set amounts.

Processing the first data set and the second data set, further comprising: and controlling the nozzles to eject a part of the data of the second set amount of ink in the image dot matrix data to process the data so that the ink ejection amount when printing is performed according to the processed printing data set is smaller than the ink ejection amount when printing is performed according to the printing data set before processing.

The second set amount is greater than 0, and the first set amount is greater than the second set amount.

Processing the data group in which the corresponding ink ejection amount in the image dot matrix data is the second set amount, including: and changing one data set in the image dot matrix data into a data set corresponding to the ink jetting amount smaller than the second set amount, wherein the ink jetting amount corresponding to the data set before the change is the second set amount, and the data set is respectively adjacent to at least one data set corresponding to the ink jetting amount of the first set amount and at least two data sets corresponding to the ink jetting amount of the second set amount.

In one embodiment, changing one of the data sets in the image dot matrix data to a data set corresponding to the ink ejection amount smaller than the second set amount, the ink ejection amount corresponding to the data set before the change being the second set amount, and the data set being adjacent to at least one data set corresponding to the ink ejection amount being the first set amount and at least two data sets corresponding to the ink ejection amount being the second set amount, respectively, includes: and traversing each data set in the image dot matrix data, changing any one data set in the image dot matrix data into a data set of which the corresponding ink jetting amount is smaller than the second set amount, wherein the ink jetting amount corresponding to the data set before the change is the second set amount, and the data set is respectively adjacent to at least one data set of which the corresponding ink jetting amount is the first set amount and at least two data sets of which the corresponding ink jetting amount is the second set amount.

In one embodiment, changing one of the data sets in the image dot matrix data to a data set corresponding to the ink ejection amount smaller than the second set amount, the ink ejection amount corresponding to the data set before the change being the second set amount, and the data set being adjacent to at least one data set corresponding to the ink ejection amount being the first set amount and at least two data sets corresponding to the ink ejection amount being the second set amount, respectively, includes: aiming at a data set which corresponds to the image dot matrix data and has the ink jet amount as the second set amount, at least one data set which corresponds to the data set and has the ink jet amount as the first set amount and at least two data sets which correspond to the data sets and have the ink jet amount as the second set amount and are adjacent to each other, acquiring a feathering data set corresponding to the data set, wherein the feathering data set corresponding to the data set is different from the data set; and performing logical operation on the data set and the feathering data set to obtain a data set with the corresponding ink jet amount less than that of the data set, so as to achieve the purpose of changing the data set.

In one embodiment, changing one of the data sets in the image dot matrix data to a data set corresponding to the ink ejection amount smaller than the second set amount, the ink ejection amount corresponding to the data set before the change being the second set amount, and the data set being adjacent to at least one data set corresponding to the ink ejection amount being the first set amount and at least two data sets corresponding to the ink ejection amount being the second set amount, respectively, includes: and changing one data set in the image dot matrix data into a data set of which the corresponding ink jetting amount is the third set amount, wherein the ink jetting amount corresponding to the data set before the change is the second set amount, and the data set is respectively adjacent to at least one data set of which the corresponding ink jetting amount is the first set amount and at least two data sets of which the corresponding ink jetting amount is the second set amount.

The third set amount is greater than 0 and the third set amount is less than the second set amount.

If a data set is 10, the data set controls the nozzles to eject the ink of the second set amount, and the data set is not calculated to obtain a data set of 01, and the nozzles eject the ink of the third set amount under the control of the data set of 01.

In one embodiment, changing one of the data sets in the image dot matrix data to a data set corresponding to the ink ejection amount smaller than the second set amount, the ink ejection amount corresponding to the data set before the change being the second set amount, and the data set being adjacent to at least one data set corresponding to the ink ejection amount being the first set amount and at least two data sets corresponding to the ink ejection amount being the second set amount, respectively, includes: and traversing each data set in the image dot matrix data, changing any one data set in the image dot matrix data into a data set with the corresponding ink jetting amount smaller than a second set amount, wherein the ink jetting amount corresponding to the data set before the change is the second set amount, and the data set is respectively adjacent to at least one data set with the corresponding ink jetting amount being the first set amount and at least two data sets with the corresponding ink jetting amount being the second set amount.

In one embodiment, changing one of the data sets in the image dot matrix data to a data set corresponding to the ink ejection amount smaller than the second set amount, the ink ejection amount corresponding to the data set before the change being the second set amount, and the data set being adjacent to at least one data set corresponding to the ink ejection amount being the first set amount and at least two data sets corresponding to the ink ejection amount being the second set amount, respectively, includes: traversing each data set in the image dot matrix data, changing any one data set in the image dot matrix data into a data set of which the corresponding ink jetting amount is 0, wherein the ink jetting amount corresponding to the data set before the change is a second set amount, and the data set is respectively adjacent to at least two data sets of which the corresponding ink jetting amount is a first set amount and at least two data sets of which the corresponding ink jetting amount is a second set amount.

In one embodiment, changing one of the data sets in the image dot matrix data to a data set corresponding to the ink ejection amount smaller than the second set amount, the ink ejection amount corresponding to the data set before the change being the second set amount, and the data set being adjacent to at least one data set corresponding to the ink ejection amount being the first set amount and at least two data sets corresponding to the ink ejection amount being the second set amount, respectively, includes: and the data set of which the ink jetting amount is 0 corresponding to one data set in the image dot matrix data is adjacent to at least two data sets of which the ink jetting amount is the first set amount and at least two data sets of which the ink jetting amount is the second set amount respectively before the data set is changed.

In an embodiment, as shown in fig. 8, after the step S2 processes the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set, the method further includes: step S25: judging whether the quantity of the data of the first snapshot data centralized control nozzle for jetting the second set amount of ink is larger than a second preset value or not; step S26: and if the number is larger than the first preset value, the data of the first snapshot data which collectively control the nozzles to eject the second set amount of ink is reprocessed, so that the number of the nozzles which collectively eject the second set amount of ink according to the reprocessed first snapshot data is not larger than the second preset value.

The second preset value is a positive integer.

In one embodiment, in step S26, if the number is greater than the first preset value, performing a reprocessing on the data of the first snapshot data set that controls the nozzles to eject the second set amount of ink so that the number of nozzles to eject the second set amount of ink according to the reprocessed e-th snapshot data set and the second snapshot data set is not greater than the second preset value includes: acquiring a number f1 of second set amount of ink droplets ejected according to the first snapshot data set, the ink droplets being formed by one ejection from the nozzle; subtracting a second preset value from the quantity f1 to obtain a value f 2; the data set in which the numerical value f2 in the first snapshot data set ejected the second set amount of ink was changed to a data set in which the control nozzles ejected an amount of ink smaller than the second set amount.

In step S2, after the processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set, the method further includes: judging whether the quantity of the data of the second set amount of ink sprayed by the second snapshot data centralized control nozzle is greater than a fifth preset value or not; and if the number is larger than the fifth preset value, the data of the second snapshot data which collectively control the nozzles to eject the second set amount of ink is reprocessed, so that the number of the nozzles which collectively eject the second set amount of ink according to the reprocessed second snapshot data is not larger than the fifth preset value.

In one embodiment, the step S2, processing partial data for controlling the nozzles to eject the second set amount of ink in the image dot matrix data, includes: acquiring second feathering dot matrix data including only a data set for controlling the nozzles not to discharge ink and a data set for controlling the nozzles to eject a second set amount of ink; the second feathering dot matrix data is logically operated with the image dot matrix data to reduce the amount of ink ejected according to the processed image dot matrix data.

The arrangement of the data set of the second set amount of ink ejected by each control nozzle in the second eclosion dot matrix data is different from the arrangement of the data set of the second set amount of ink ejected by each control nozzle in the image dot matrix data before processing.

In one embodiment, the print data set includes data that controls the nozzles to eject a first set amount, a second set amount, and a third set amount of ink.

The image dot matrix data, after processing partial data for controlling the nozzles to eject the ink with the second set amount, further includes: and processing part of the image dot matrix data for controlling the nozzle to eject the third set amount of ink so that the amount of ink ejected when printing is performed according to the processed image dot matrix data is smaller than the amount of ink ejected when printing is performed according to the image dot matrix data before processing.

The third set amount is greater than 0, and the second set amount is greater than the third set amount.

In one embodiment, processing the first data set and the second data set further comprises: and controlling the nozzles to eject a part of the data of a third set amount of ink in the image dot matrix data to process the data so that the ink ejection amount when printing is performed according to the processed image dot matrix data is smaller than the ink ejection amount when printing is performed according to the image dot matrix data before processing.

The third set amount is greater than 0, and the first set amount is greater than the third set amount.

The method for controlling the nozzles to eject ink in a second set amount in the image dot matrix data to process the partial data so that the ink ejection amount when printing is performed according to the processed printing data set is smaller than the ink ejection amount when printing is performed according to the printing data set before processing, includes: and changing one data set in the image dot matrix data into a data set of which the corresponding ink jetting amount is 0, wherein the ink jetting amount corresponding to the data set before the change is a third set amount, and the data set is adjacent to at least two data sets of which the corresponding ink jetting amount is the first set amount respectively.

When a data set is 01, the data set controls the nozzles to eject the ink with the third set amount, a feathering data set of 00 or 10 is obtained, and the feathering data set and the data set are subjected to an AND operation, so that a data set of 00 can be obtained, and the nozzles do not eject the ink under the control of the data set 00.

In one embodiment, changing one of the data sets in the image dot matrix data to a data set corresponding to a first ink ejection amount of 0, the ink ejection amount corresponding to the data set before the change is a third set amount, and the data sets are respectively adjacent to at least two data sets corresponding to a first set amount of ink ejection amount, includes: traversing each data set in the image dot matrix data, changing any one data set in the image dot matrix data into a data set of which the corresponding ink jetting amount is 0, wherein the ink jetting amount corresponding to the data set before the change is a third set amount, and the data set is respectively adjacent to at least two data sets of which the corresponding ink jetting amount is a first set amount.

In one embodiment, as shown in fig. 9, in step S2, the first data set and the second data set are processed to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and after the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, the method further includes: step S27: judging whether the quantity of the data of the first snapshot data centralized control nozzle for jetting the third set quantity of ink is larger than a third preset value or not; step S28: and if the number is larger than the first preset value, the data of the first snapshot data which collectively control the nozzles to eject the third set amount of ink is reprocessed, so that the number of the nozzles which collectively eject the third set amount of ink according to the reprocessed first snapshot data is not larger than the third preset value.

The third preset value is a positive integer.

In one embodiment, the first preset value is smaller than the second preset value, and the second preset value is smaller than the third preset value. The first preset value is less than 50% of the total amount of the data group contained in the image dot matrix data. The second preset value is less than 60% of the total amount of the data group included in the image dot matrix data. The third preset value is less than 80% of the total amount of the data group included in the image dot matrix data.

In one embodiment, in step S28, if the number is greater than the first preset value, the reprocessing the data in the first snapshot data set and the second snapshot data set that control the nozzles to eject the third set amount of ink such that the number of nozzles to eject the third set amount of ink according to the first snapshot data set and the second snapshot data set after the reprocessing is not greater than the third preset value includes: acquiring the number a1 of ink droplets of a third set amount ejected according to the first snapshot data set and the second snapshot data set, the ink droplets being formed by one ejection from the nozzle; subtracting a third preset value from the quantity a1 to obtain a numerical value a 2; and changing a data set of the first snapshot data set and the second snapshot data set, wherein the data set comprises a plurality of a1 control nozzles which jet a third set amount of ink, into a data set which does not jet ink.

In step S2, processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and after the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, the method further includes: judging whether the quantity of the data of the second snapshot data centralized control nozzle for jetting the third set quantity of ink is larger than a sixth preset value or not; and if the number is larger than the sixth preset value, the data of the second snapshot data which collectively control the nozzles to eject the third set amount of ink is reprocessed, so that the number of the nozzles which collectively eject the third set amount of ink according to the reprocessed second snapshot data is not larger than the sixth preset value.

In one embodiment, the step S2, processing the partial data for controlling the nozzles to eject the third set amount of ink in the image dot matrix data, includes: acquiring three-feathered dot matrix data including only a data set for controlling the nozzles not to discharge ink and a data set for controlling the nozzles to eject a third set amount of ink; and performing logical operation on the third feathered dot matrix data and the image dot matrix data to reduce the amount of ink ejected according to the processed image dot matrix data.

The arrangement of the data set of the third set amount of ink ejected by each control nozzle in the third eclosion dot matrix data is different from the arrangement of the data set of the third set amount of ink ejected by each control nozzle in the image dot matrix data before processing.

In one embodiment, the print data set includes data that controls the nozzles to eject four set amounts of ink, a fifth set amount of ink;

in step S2, processing the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, including: step S201: processing a portion of the data for controlling the nozzles to eject a fourth set amount of ink in the first data set and the second data set; step S202: controlling the nozzle to jet partial data of a fifth set amount of ink in the first data set and the second data set to process to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set.

The fifth set amount is greater than 0, and the fourth set amount is greater than the fifth set amount.

An embodiment of the present invention provides an apparatus for eliminating a nozzle splicing channel, as shown in fig. 11, the apparatus includes an obtaining module 01 and a first processing module 02.

The obtaining module 01 is configured to obtain a print data set, where the print data set includes a first data set and a second data set;

the first processing module 02 is configured to process the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set;

the first snapshot data set is used for driving a first nozzle to print a first area in the image to be printed, and the second snapshot data set is used for driving a second nozzle to print a second area in the image to be printed; the distance between the first area and the second area is smaller than or equal to a set distance.

In one embodiment, the first spray head is adjacent to the second spray head and the first and second spray heads overlap at a nozzle portion of the splice.

In one embodiment, the first data set and/or the second data set comprises: image dot matrix data including a data set of one or more control nozzles ejecting the first set amount of ink, the data set in the image dot matrix data corresponding to each pixel of an original image, the first set amount being greater than 0;

the first processing module 02 is further configured to change one of the data sets of the image dot matrix data to the data set having the corresponding ink ejection amount smaller than the first set amount, where the ink ejection amount corresponding to the data set before the change is the first set amount, and the data set is adjacent to at least one of the data sets having the corresponding ink ejection amount of the first set amount;

the data set includes one or more data of the image dot matrix data.

In an embodiment, the first processing module 02 is further configured to change one data set of the image dot matrix data to a corresponding data set of which the ink ejection amount is 0, where the ink ejection amount corresponding to the data set before the change is the first set amount, and the data set is adjacent to at least two corresponding data sets of which the ink ejection amounts are the first set amount.

In one embodiment, the first processing module 02 is further configured to change one data set of the image dot matrix data to a data set of which the corresponding ink ejection amount is the second set amount, where the ink ejection amount corresponding to the data set before the change is the first set amount, and the data set is adjacent to one data set of which the corresponding ink ejection amount is the first set amount and at least two data sets of which the corresponding ink ejection amounts are the second set amount, respectively;

the second set amount is greater than 0, and the second set amount is less than the first set amount.

In one embodiment, as shown in fig. 12, the first processing module 02 includes: acquiring a submodule 023 and an operation submodule 024;

the obtaining sub-module 023 is configured to, for a data set, where a corresponding ink ejection amount in the image dot matrix data is the first set amount and is adjacent to at least one data set, where the corresponding ink ejection amount is the first set amount, obtain a feathering data set corresponding to the data set, where the feathering data set corresponding to the data set is different from the data set;

the operation submodule 024 is configured to perform logical operation on the data set and the feathering data set to obtain a data set with the corresponding ink ejection amount smaller than that of the data set.

In one embodiment, the print data set includes data that controls the nozzles to eject a set amount of ink, a second set amount of ink;

as shown in fig. 13, the first processing module 02 includes a first processing sub-module 021 and a second processing sub-module 022;

the first processing sub-module 021 is used for processing partial data of the first data set and the second data set, which controls the nozzle to jet a fourth set amount of ink;

the second processing sub-module 022 is configured to control the nozzles to eject a portion of data of a fifth set amount of ink in the first data set and the second data set to be processed to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set, and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set;

the fifth set amount is greater than 0, and the fourth set amount is greater than the fifth set amount.

In one embodiment, as shown in fig. 14, the apparatus further comprises: a judgment module 05 and a second processing module 06;

the judging module 05 is configured to process the first data set and the second data set to obtain a first snapshot data set and a second snapshot data set; after the ink jetting amount corresponding to the first snapshot data set is less than the ink jetting amount corresponding to the first data set and the ink jetting amount corresponding to the second snapshot data set is less than the ink jetting amount corresponding to the second data set, whether the number of data for controlling the nozzle to jet the first set amount of ink in the first snapshot data set is greater than a first preset value or not is judged;

the second processing module 06, configured to, if the number is greater than the first preset value, perform reprocessing on the data obtained by collectively controlling the nozzles to eject the first set amount of ink according to the first snapshot data, so that the number of nozzles that collectively eject the first set amount of ink according to the reprocessed first snapshot data is not greater than the first preset value;

the first preset value is a positive integer.

When the device is used for data processing, the operation method of each module in the device is the same as the method for eliminating the nozzle splicing channel provided by the invention, so the using method of each module in the device is also the same as the method for eliminating the nozzle splicing channel. The use method and the operation method of each module and each sub-module in the device for eliminating the nozzle splicing channel can refer to the method for eliminating the nozzle splicing channel, and are not repeated here.

Referring to fig. 15, the printing method according to the embodiment of the present invention further provides a device for eliminating a channel splicing between nozzles, where the device mainly includes:

at least one processor 401; and the number of the first and second groups,

a memory 402 communicatively coupled to the at least one processor; wherein the content of the first and second substances,

the memory 402 stores instructions executable by the at least one processor to be executed by the at least one processor 401 to enable the at least one processor 401 to perform the method described in the embodiments of the present invention. For a detailed description of the apparatus, please refer to the embodiments, which are not repeated herein.

In particular, the processor 401 may include a Central Processing Unit (CPU), or an Application Specific Integrated Circuit (ASIC), or may be configured as one or more Integrated circuits implementing embodiments of the present invention.

Memory 402 may include mass storage for data or instructions. By way of example, and not limitation, memory 402 may include a Hard Disk Drive (HDD), floppy Disk Drive, flash memory, optical Disk, magneto-optical Disk, tape, or Universal Serial Bus (USB) Drive or a combination of two or more of these. Memory 402 may include removable or non-removable (or fixed) media, where appropriate. The memory 402 may be internal or external to the data processing apparatus, where appropriate. In a particular embodiment, the memory 402 is a non-volatile solid-state memory. In a particular embodiment, the memory 402 includes Read Only Memory (ROM). Where appropriate, the ROM may be mask-programmed ROM, Programmable ROM (PROM), Erasable PROM (EPROM), Electrically Erasable PROM (EEPROM), electrically rewritable ROM (EAROM), or flash memory or a combination of two or more of these.

The processor 401 reads and executes the computer program instructions stored in the memory 402 to implement any of the methods for eliminating a nozzle patch channel in the embodiments described herein.

In one example, the apparatus to eliminate a lane splice of jets can also include a communication interface 403 and a bus 410. As shown in fig. 15, the processor 401, the memory 402, and the communication interface 403 are connected by a bus 410 to complete communication therebetween.

The communication interface 403 is mainly used for implementing communication between modules, apparatuses, units and/or devices in the embodiments of the present invention.

Bus 410 may include hardware, software, or both to couple components including equipment to eliminate shower splice channels to one another. By way of example, and not limitation, a bus may include an Accelerated Graphics Port (AGP) or other graphics bus, an Enhanced Industry Standard Architecture (EISA) bus, a Front Side Bus (FSB), a Hypertransport (HT) interconnect, an Industry Standard Architecture (ISA) bus, an infiniband interconnect, a Low Pin Count (LPC) bus, a memory bus, a Micro Channel Architecture (MCA) bus, a Peripheral Component Interconnect (PCI) bus, a PCI-Express (PCI-X) bus, a Serial Advanced Technology Attachment (SATA) bus, a video electronics standards association local (VLB) bus, or other suitable bus or a combination of two or more of these. Bus 410 may include one or more buses, where appropriate. Although specific buses have been described and shown in the embodiments of the invention, any suitable buses or interconnects are contemplated by the invention.

In addition, in combination with the method for eliminating the nozzle splicing channel in the embodiment, the embodiment of the invention can be implemented by providing a computer-readable storage medium. The computer readable storage medium having stored thereon computer program instructions; the computer program instructions, when executed by a processor, implement any of the described embodiments of the method for eliminating a nozzle patch channel.

In summary, according to the method, the apparatus, the device, and the storage medium for eliminating the nozzle splicing channel provided in the embodiments of the present invention, the first data set and the second data set are processed to obtain a first snapshot data set and a second snapshot data set; the ink jetting amount corresponding to the first snapshot data set is less than that corresponding to the first data set, the ink jetting amount corresponding to the second snapshot data set is less than that corresponding to the second data set, black channels can be prevented from being generated at the splicing position of the spray heads to a certain extent, and the printing effect of the image is improved.

It is to be understood that the invention is not limited to the specific arrangements and instrumentality described above and shown in the drawings. A detailed description of known methods is omitted herein for the sake of brevity. In the described embodiments, several specific steps are described and shown as examples. However, the method processes of the present invention are not limited to the specific steps described and illustrated, and those skilled in the art can make various changes, modifications and additions or change the order between the steps after comprehending the spirit of the present invention. These are all intended to be covered by the scope of protection of the present invention.