JPWO2019065578A1 - Image analysis equipment, printing equipment, image analysis methods, and programs - Google Patents

Abstract

Provided are an image analysis device, a printing device, an image analysis method, and a program capable of specifying an image pickup position of the image pickup data in the medium transport direction in the image pickup data caused by the feed unevenness of the medium. When the imaging data (60A) of the printed image captured at the imaging timing of each region in which the printed image (14) is divided into a plurality of regions is acquired and the imaging data is analyzed, each imaging timing is obtained. The imaged data (60E) is obtained by adding the integrated value (54) of the number of pulses of the timing signal, which is a pulse signal representing the position or phase of the transport unit, to the imaged data, and the integrated value is used for imaging. The data analysis target area (60E) is specified.

Description

The present invention relates to an image analysis device, a printing device, an image analysis method, and a program, and particularly relates to image analysis of a printed image.

Patent Document 1 is based on an inspection target image based on a difference value between a sample image information obtained by reading a sample image contained in a sample printed matter recognized as a non-defective product and an inspection image information obtained by reading the inspection target image. An image evaluation device that extracts streaky defects in a specific direction is described.

Patent Document 2 describes an image inspection method for acquiring an inspection image obtained by imaging a printed matter using an imaging means and extracting streaky defects from the inspection image.

In Patent Document 3, the position of the center of gravity of the pixel of the inspection image with respect to the light receiving element is acquired from the profile along the main scanning direction obtained by reading the inspection image, and the phase difference which is the deviation of the position of the center of gravity of the line with respect to the light receiving center of the light receiving element. Based on the above, an image position inspection device for specifying a position along the main scanning direction of each pixel of the inspection image with respect to the light receiving element is described.

JP 2015-179090 JP-A-2016-193504 Japanese Unexamined Patent Publication No. 2013-609003

In a printing process using a single-pass type inkjet printer, a transfer drum method may be applied to transfer a medium. The transport drum may be equipped with an encoder that monitors the rotation angle phase of the transport drum.

An inkjet head that ejects ink onto a medium is mounted on the upper part of the transport drum. When using black ink, cyan ink, magenta ink, and yellow ink, an inkjet head is provided for each color.

In addition, an in-line scanner that captures an image printed by the inkjet head may be mounted at a position on the downstream side of the inkjet head in the transport path of the medium using the transport drum.

[problem]
In the above configuration, there are the following problems between the in-line scanner and the printing process.

Image structure distortion in the medium transport direction of imaging data occurs due to uneven feeding of the medium. The rotation of the transport drum has uneven rotation speed. On the other hand, a jetting timing pulse is generated from the encoder measurement signal, and the jetting timing of the inkjet head is controlled by using the jetting timing pulse. As a result, the occurrence of printing unevenness due to the uneven rotation speed of the transport drum is suppressed.

Similarly, in the case of imaging using an in-line scanner, when the imaging timing in the medium transport direction is controlled based on the encoder measurement signal, the occurrence of image structure distortion in the medium transport direction of the image data can be suppressed.

When an image pickup device equipped with a CCD image sensor and an image pickup device typified by a CMOS image sensor is used, it is common practice to generate a fixed image pickup cycle pulse that is inexpensively generated by using a crystal oscillator or the like. CCD is an abbreviation for charge coupled device, which represents a charge coupled device. CMOS is an abbreviation for complementary metal-oxide semiconductor, which is an English notation for complementary metal-oxide semiconductor.

If the imaging period is changed for each imaging line in the medium transport direction, the optical linearity of the imaging data cannot be guaranteed. Then, it becomes difficult to appropriately perform various image processes using the imaging data such as correction of density unevenness of the printed image. Therefore, it is difficult to practically adopt the control of the imaging timing in the medium transport direction based on the encoder measurement signal.

It is possible to control the imaging start timing based on the encoder measurement signal. A device that employs control of the timing of starting imaging based on an encoder measurement signal is known. The imaging start timing is the first imaging timing.

In imaging using an in-line scanner, it becomes difficult to specify the imaging position in the medium transport direction in the imaging data due to the influence of uneven feeding of the medium. In particular, the effect of uneven feed of the medium is integrated toward the rear end side of the medium. Then, the variation in the imaging position in the medium transport direction in the imaging data becomes large. The rear end of the medium is the upstream end of the medium in the medium transport direction.

In addition, the degree of this problem may vary due to individual variations in the transport performance of the medium. A technical solution to this problem is desired.

Here, the case where the medium is conveyed along the arc using the conveying drum has been described, but the same problem may exist when the medium is conveyed along the straight line using the conveying belt or the like. Further, even in a printing apparatus other than the inkjet method, there may be a similar problem when printing and imaging are performed in-line.

Patent Documents 1 to 3 do not describe the specification of the imaging position of the imaging data in the media transporting direction in the imaging data caused by the uneven feeding of the medium.

The present invention has been made in view of such circumstances, and is an image analysis device, a printing device, an image analysis method, and an image analysis device capable of specifying an image pickup position of the image pickup data in the medium transport direction in the image pickup data caused by the feed unevenness of the medium. The purpose is to provide a program.

In order to achieve the above object, the following aspects of the invention are provided.

The image analysis device according to the first aspect is imaged using an image pickup device arranged in the transport path of the transport unit, and is imaged at the imaging timing of each region in which the printed image is divided into a plurality of regions in the transport direction of the medium. The imaging data acquisition unit includes an imaging data acquisition unit that acquires the imaging data of the printed image and an analysis processing unit that analyzes the imaging data acquired by using the imaging data acquisition unit. The imaging data acquisition unit includes imaging data for each imaging timing. On the other hand, the imaging data to which the integrated value of the number of pulses of the timing signal, which is a pulse signal representing the position or phase of the transport unit, is added is acquired, and the analysis processing unit analyzes the imaging data using the integrated value. This is an image analysis device that identifies a target area.

According to the first aspect, it is possible to specify the imaging position in the medium transport direction in the imaging data by using the integrated value of the number of pulses of the timing signal. As a result, the stability of the process for specifying the imaging position in the medium transport direction in the image data is maintained. In addition, the processing cost for specifying the imaging position in the medium transport direction in the image data is suppressed.

The printed image includes a pattern for detecting an abnormality in the printing unit printed on the medium using the printing unit.

The imaging data includes imaging data of a test pattern for inspection of the printing unit.

In the first aspect, the same items as those specified in the following third to eleventh aspects can be appropriately combined. In that case, the component responsible for the process or function specified in the printing device can be grasped as the component of the image analysis device responsible for the corresponding process or function.

The printing apparatus according to the second aspect includes a transport unit that transports the medium along the medium transport direction, a printing unit that prints on the medium transported by the transport unit, and an imaging image arranged in the transport path of the transport unit. An imaging data acquisition unit and an imaging data acquisition unit that acquire the imaging data of the printed image captured by the apparatus and acquired at the imaging timing of each region in which the printed image is divided into a plurality of regions in the transport direction of the medium. An analysis processing unit that analyzes the imaging data acquired using the above, a measurement unit that acquires a timing signal that is a pulse signal representing the position or phase of the transport unit, and an integrated value that acquires the integrated value of the number of pulses of the timing signal. The imaging data acquisition unit includes an acquisition unit, and the imaging data acquisition unit acquires imaging data in which an integrated value is added to the imaging data for each imaging timing, and the analysis processing unit analyzes the imaging data using the integrated value. It is a printing device that specifies a target area.

According to the second aspect, it is possible to obtain the same action and effect as in the first aspect.

The imaging data acquisition unit may include an imaging control unit that controls the imaging device. The image pickup control unit can generate image pickup data using an electric signal output from the image pickup apparatus. Further, additional information may be added to the imaging data generated by the imaging control unit. The integrated value of the number of pulses of the timing signal may be used as additional information.

The integrated value of the number of pulses of the timing signal may include the integrated value of the number of pulses of the timing signal in each imaging period. The integrated value of the number of pulses of the timing signal can be a relative value for each imaging period.

Examples of the transfer unit include a rotary transfer method in which the medium is conveyed along an arc, a linear transfer method in which the medium is conveyed along a straight line, and the like. In the case of the linear transfer method, the measuring unit can output a timing signal indicating the position of the transfer unit. In the case of the rotary transfer method, the measuring unit can output a timing signal indicating the phase of the transfer unit.

An example of an image pickup device is a line sensor type image pickup device in which a plurality of image pickup elements are arranged over the entire length of the medium in the medium width direction orthogonal to the medium transfer direction. As the image pickup device, an area sensor type image pickup device in which a plurality of image pickup elements are arranged two-dimensionally can be applied.

The third aspect may be a configuration in which the printing apparatus of the second aspect includes a printing control unit that controls the printing unit using a timing signal.

According to the third aspect, the influence of the feed unevenness of the medium can be corrected for the printed image printed on the medium. Further, the timing signal used for correcting the printed image can be incorporated into the imaging data for each imaging timing. This makes it possible to correct the captured data using the same mechanism as the correction of the printed image.

As an example of the timing signal for controlling the printing unit, there is a jetting timing pulse signal in the case of an inkjet printing apparatus. An example of a timing signal for controlling a printing unit is an exposure timing pulse signal in the case of an electrophotographic printing apparatus.

A fourth aspect is the printing apparatus of the third aspect, wherein the measuring unit includes an encoder that measures the position or phase of the conveying unit and outputs a measurement signal, and sets the resolution of the encoder to the printing resolution of the printing unit. When the converted first print resolution conversion value is less than the print resolution, the measurement signal is interpolated and the second print resolution conversion value representing the period converted into the value of the unit representing the print resolution is printed. It may be configured to acquire a timing signal having a resolution higher than the resolution.

According to the fourth aspect, it is possible to acquire a timing signal corresponding to the print resolution even when the resolution of the encoder is lower than the print resolution.

In the fifth aspect, in the printing apparatus of any one of the second to fourth aspects, the medium information acquisition unit that acquires the size information of the medium and the image information acquisition that acquires the position information of the printed image on the medium. The analysis processing unit acquires information on the print area on which the image to be analyzed is printed, which is specified by using the information on the size of the medium and the information on the position of the print image. Based on the information, the print-compatible area in the imaging data corresponding to the print area may be extracted, and the analysis target area may be specified from the print-compatible area.

According to the fifth aspect, the imaging data is subjected to two-step region identification. In the first stage of area identification, information on the print area on which the image to be analyzed is printed is acquired. As a result, random access to the storage unit in which the imaging data is stored becomes possible.

In the sixth aspect, in the printing apparatus of any one of the second to fifth aspects, the printing unit prints a test pattern used for detecting an abnormal printing element, and the analysis processing unit is an analysis target area. As a result, the area where the test pattern is printed may be specified.

According to the sixth aspect, it is possible to specify the position of the test pattern in the imaging data.

In the seventh aspect, in the printing apparatus of the sixth aspect, the printing unit may be configured to print the test pattern in a non-commodity image area other than the product image area in which the product image is printed.

According to the seventh aspect, it is possible to specify the position in the imaging data of the test pattern printed in the non-commodity image area. In particular, when a non-commodity image area is printed at the rear end of the medium in the medium transport direction, the effect of suppressing the effect of integrating the feed unevenness of the medium is great.

In the eighth aspect, in the printing apparatus of the seventh aspect, the printing unit may be configured to print the test pattern on the non-commodity image area of the rear end portion of the medium in the medium transport direction.

According to the eighth aspect, it is possible to specify the position of the test pattern of the rear end portion of the medium in the medium transport direction in the imaging data, which is easily affected by the uneven feeding of the medium.

The rear end portion of the medium in the medium transport direction represents the upstream end portion of the medium in the medium transport direction. The end is a region having a predetermined length from the end.

In the ninth aspect, in the printing apparatus of the seventh aspect or the eighth aspect, the analysis processing unit may be configured to specify the product image area by using the integrated value of the timing signal.

According to the ninth aspect, the influence of the feed unevenness of the medium can be suppressed in specifying the product image area.

In the tenth aspect, in the printing apparatus of the ninth aspect, the imaging data acquisition unit acquires the imaging data captured by applying an imaging resolution lower than the printing resolution of the printed image, and the analysis processing unit is the product image area. The imaged data may be configured to correct distortion caused by uneven feeding of the medium and to increase the resolution.

According to the tenth aspect, distortion of the imaging data due to uneven feeding of the medium in the medium transport direction is corrected by using the integrated value of the number of pulses of the timing signal, and the resolution of the imaging data in the medium transport direction is increased. Will be done. As a result, deterioration of the analysis accuracy of the imaging data due to distortion of the imaging data and insufficient resolution of the imaging data with respect to the resolution of the printed image in the medium transport direction can be suppressed.

In the eleventh aspect, in the printing apparatus of the tenth aspect, the analysis processing unit has a number corresponding to the integrated value of the number of pulses of the timing signal added to the imaged data for one pixel of the imaged data in the product image area. The configuration may be such that pixels are interpolated.

According to the eleventh aspect, the number of pixels corresponding to the integrated value of the number of pulses of the timing signal is interpolated for one pixel of the imaging data for each imaging timing. As a result, distortion correction of imaging data and high resolution can be performed efficiently and with high accuracy.

In the twelfth aspect, in the printing apparatus of the tenth aspect or the eleventh aspect, the analysis processing unit performs distortion correction due to uneven feeding of the medium, image pickup data of the product image area subjected to high resolution, and the product image. The image inspection may be performed to determine the presence or absence of image defects in the product image based on the difference from the reference image of.

According to the twelfth aspect, highly accurate and efficient image inspection can be performed in which deterioration of analysis accuracy of imaging data is suppressed.

In the thirteenth aspect, in the printing apparatus of any one of the second to twelfth aspects, the imaging data acquisition unit acquires the imaging data captured by applying an imaging resolution lower than the printing resolution of the printed image. The analysis processing unit may be configured to perform distortion correction due to uneven feeding of the medium and increase the resolution of the analysis target region.

According to the thirteenth aspect, the analysis accuracy is expected to be improved. In addition, the influence of insufficient resolution of the imaged data can be eliminated.

In the image analysis method according to the fourteenth aspect, an image is taken using an imaging device arranged in a transfer path of a transfer unit, and a printed image is imaged at an imaging timing for each region in which a printed image is divided into a plurality of regions in the transport direction of the medium. The imaging data acquisition process includes an imaging data acquisition step of acquiring the imaging data of the printed image and an analysis processing step of analyzing the imaging data acquired in the imaging data acquisition step, and the imaging data acquisition process is performed on the imaging data for each imaging timing. Then, the imaging data to which the integrated value of the number of pulses of the timing signal, which is the pulse signal representing the position or phase of the transport unit, is added is acquired, and the analysis processing step uses the integrated value to analyze the imaged data. It is an image analysis method to specify.

According to the fourteenth aspect, the same effect as that of the first aspect can be obtained.

In the 14th aspect, the same items as those specified in the 2nd to 13th aspects can be appropriately combined. In that case, the components responsible for the processes and functions specified in the image analysis device and the printing device can be grasped as the components of the image analysis method responsible for the corresponding processes and functions.

The program according to the fifteenth aspect is imaged by a computer using an imaging device arranged in the transport path of the transport unit, and at the imaging timing for each region in which the printed image is divided into a plurality of regions in the transport direction of the medium. It is a program that realizes the imaging data acquisition function that acquires the imaging data of the captured printed image and the analysis processing function that analyzes the imaging data acquired using the imaging data acquisition function. The imaging data acquisition function is the imaging timing. The imaging data obtained by adding the integrated value of the number of pulses of the timing signal, which is a pulse signal representing the position or phase of the transport unit, to the imaging data for each image is acquired, and the analysis processing function uses the integrated value to obtain the imaging data. This is a program that specifies the analysis target area of the imaging data.

According to the fifteenth aspect, the same effect as that of the first aspect can be obtained.

In the fifteenth aspect, the same items as those specified in the second to thirteenth aspects can be appropriately combined. In that case, the components responsible for the processes and functions specified in the image analysis device and the printing device can be grasped as the components of the program responsible for the corresponding processes and functions.

According to the present invention, it is possible to specify the imaging position in the medium transport direction in the imaging data by using the integrated value of the number of pulses of the timing signal. As a result, the stability of the process for specifying the imaging position in the medium transport direction in the image data is maintained. In addition, the processing cost for specifying the imaging position in the medium transport direction in the image data is suppressed.

FIG. 1 is an overall configuration diagram showing a schematic configuration of an inkjet printing apparatus. FIG. 2 is a schematic configuration diagram of a printing unit of the inkjet printing apparatus shown in FIG. FIG. 3 is a schematic diagram of imaging data. FIG. 4 is a block diagram of the inkjet printing apparatus shown in FIG. FIG. 5 is a schematic diagram of a nozzle inspection pattern. FIG. 6 is an explanatory diagram of a problem in searching for the position of the nozzle inspection pattern in the imaging data. FIG. 7 is an explanatory diagram of the jetting timing pulse. FIG. 8 is an explanatory diagram of a jetting timing pulse number integrated value. FIG. 9 is an explanatory diagram of an imaging start position in the imaging data and a cutting position of the imaging data of the nozzle inspection pattern. FIG. 10 is an explanatory diagram of an imaging start timing in the imaging data and a cutting timing of the imaging data of the nozzle inspection pattern. FIG. 11 is a flowchart showing the flow of the procedure of the defective nozzle detection method. FIG. 12 is a flowchart showing the flow of the procedure of the printing process shown in FIG. FIG. 13 is a flowchart showing the flow of the procedure of the imaging process shown in FIG. FIG. 14 is an explanatory diagram of defective nozzle detection according to a modified example. FIG. 15 is a flowchart showing the flow of the procedure of the defective nozzle check method according to the modified example. FIG. 16 is an explanatory diagram when image inspection and defective nozzle detection are used in combination.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same components are designated by the same reference numerals, and duplicate description is omitted.

[Configuration example of an inkjet printing device]
〔overall structure〕
FIG. 1 is an overall configuration diagram showing a schematic configuration of an inkjet printing apparatus. The inkjet printing device 10 is a printing device that prints a product image on a sheet-fed medium 12. In FIG. 1, the illustration of the product image is omitted. The product image is illustrated with reference numeral 14 in FIG.

The inkjet printing device 10 includes a transport unit 20, a printing unit 30, and an imaging unit 40. Further, the inkjet printing device 10 includes a medium supply unit and a medium discharge unit (not shown).

[Transport section]
The transport unit 20 includes a transport drum 22 and an encoder 24. The transport drum 22 transports the medium 12 in the medium transport direction. The transport drum 22 includes a gripper that grips the tip of the medium 12.

The outer peripheral surface 22A of the transport drum 22 is provided with suction holes for sucking and supporting the medium 12. The gripper and the suction hole are not shown. The transport drum 22 generates a negative pressure in the suction holes by using a suction pressure applying portion (not shown). As a result, the medium 12 is attracted and supported by the outer peripheral surface 22A of the transport drum 22.

The encoder 24 is attached to the rotating shaft of the transport drum 22. The encoder 24 may be attached to either the shaft of the motor that drives the transport drum 22 or a rotating member that is connected to the shaft of the motor. The motor and the rotating member are not shown.

The encoder 24 outputs the encoder measurement signal 50. The encoder measurement signal 50 represents the angular phase of the transport drum 22. Details of the encoder measurement signal 50 will be described later. The encoder 24 is an example of a component of the measuring unit.

When the first print resolution conversion value obtained by converting the encoder resolution into the unit value representing the print resolution is the print resolution or higher, the encoder measurement signal 50 is an example of a timing signal.

[Printing section]
The printing unit 30 includes an inkjet head 32K, an inkjet head 32C, an inkjet head 32M, and an inkjet head 32Y. The inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y discharge black ink, cyan ink, magenta ink, and yellow ink, respectively.

The inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y include a plurality of nozzles, and as an example of arranging a plurality of nozzles, a matrix arrangement can be mentioned. The nozzle is an example of a printing element. Another example of the printing element is an exposure element in an electrophotographic printing apparatus.

[Image pickup unit]
The imaging unit 40 includes an in-line scanner 42. The in-line scanner 42 is arranged at a position on the downstream side of the printing unit 30 in the medium transport direction in the transport path of the medium 12. The in-line scanner 42 includes an image sensor such as a CCD image sensor and a CMOS image sensor. The in-line scanner 42 captures an image printed on the medium 12 using the printing unit 30. The image to be captured includes a nozzle inspection pattern. The image to be imaged may include a product image.

Hereinafter, a case where both the product image and the nozzle inspection pattern are imaged by using the image pickup unit 40 will be described. The nozzle inspection pattern is illustrated with reference numeral 14A in FIG.

The imaging unit 40 is an example of a component of an imaging data acquisition unit that acquires imaging data captured by using an imaging device. The in-line scanner 42 is an example of an imaging device that captures a printed image at an imaging timing for each region divided into a plurality of regions in the medium transport direction. Further, the in-line scanner 42 is an example of an imaging device that applies an imaging resolution lower than the printing resolution to perform imaging.

[Action of inkjet printing device]
The operation of the inkjet printing apparatus 10 shown in FIG. 1 will be described. The medium 12 is supplied to the transport drum 22 from a medium supply unit (not shown). The transport drum 22 attracts and supports the medium 12 supplied from the medium supply unit to the outer peripheral surface 22A.

The transport drum 22 rotates by adsorbing and supporting the medium 12 on the outer peripheral surface 22A. The medium 12 moves along the outer peripheral surface 22A of the transport drum 22. The arrow line shown on the transport drum 22 indicates the medium transport direction of the transport drum 22.

The printing unit 30 prints the product image on the medium 12 which is attracted to and supported by the outer peripheral surface 22A of the transport drum 22 and is transported along the outer peripheral surface 22A of the transport drum 22. The printing unit 30 controls the jetting timing by using the jetting timing pulse 52 generated from the encoder measurement signal 50.

The jetting timing pulse 52 is generated for each of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y.

In other words, the jetting timing of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y is controlled by using the jetting timing pulse 52 corresponding to each.

When the first print resolution conversion value obtained by converting the encoder resolution into the unit value representing the print resolution is less than the print resolution, the jetting timing pulse 52 is an example of a timing signal.

The medium 12 on which the product image is printed using the printing unit 30 is conveyed to the imaging region of the imaging unit 40. The image capturing unit 40 captures a product image printed on the medium 12. The imaging unit 40 controls the imaging timing using the imaging timing control signal 56 generated from the encoder measurement signal 50.

In other words, the imaging unit 40 uses the imaging timing control signal 56 as a trigger signal to image the nozzle inspection pattern printed on the medium 12. Of the encoder measurement signals 50, the Z-phase signal or the origin signal is applied to generate the imaging timing control signal 56. Details of the Z-phase signal or the origin signal will be described later.

The imaging unit 40 images the product image printed on the medium 12 and the nozzle inspection pattern, and acquires the imaging data. The imaging data generated by the imaging unit 40 is used for image inspection and defective nozzle check. The jetting timing pulse number integrated value 54 is synchronously added to the imaging data at the end or the beginning. The term "synchronized at the end or the beginning of the imaging data" as used herein includes the meaning of being associated with the imaging data as information different from the imaging data.

The jetting timing pulse number integrated value 54 is an example of the integrated value of the pulse number of the timing signal. The details of the jetting timing pulse number integrated value 54 will be described later.

[Outline configuration of printing section]
FIG. 2 is a schematic configuration diagram of a printing unit of the inkjet printing apparatus shown in FIG. FIG. 2 is a schematic view of the outer peripheral surface 22A of the transport drum 22 shown in FIG. 1 in the medium transport direction.

The inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y shown in FIG. 2 have an inkjet head 32K, an inkjet head 32C, an inkjet head 32M, and an inkjet head from the upstream side to the downstream side in the medium transport direction. The heads 32Y are arranged in this order.

The inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y are arranged at equal intervals along the medium transport direction.

The in-line scanner 42 is arranged at a position further downstream of the inkjet head 32Y arranged at the most downstream position in the medium transport direction of the printing unit 30 in the transport path of the medium 12.

[Explanation of imaging data]
FIG. 3 is a schematic diagram of imaging data. The imaging data 60 shown in FIG. 3 is generated by imaging the product image 14 shown in FIG. Reference numeral 62 shown in FIG. 3 represents an arbitrary pixel of the imaging data 60. In FIG. 3, the illustration of the imaging data of the nozzle inspection pattern is omitted.

The resolution of the imaging data 60 shown in FIG. 3 in the medium transport direction is 200 dots per inch. The resolution of the imaging data 60 in the medium width direction is 476 dots per inch. Inch per dot, which represents a unit of resolution, represents the number of pixels per inch. Dots per inch may be described as dpi. The medium width direction is a direction orthogonal to the medium transport direction shown in FIG.

The in-line scanner 42 shown in FIG. 2 is a line sensor type image pickup device in which a plurality of image pickup elements are arranged over a length corresponding to the entire width of the medium 12 in the medium width direction. The in-line scanner 42 can capture a single line along the media width direction having a constant length in the medium transport direction in one imaging.

The imaging data 60 shown in FIG. 3 has an imaging line 64 including a plurality of pixels 62 along the medium width direction. The image pickup data 60 has a plurality of image pickup lines 64 along the medium transport direction.

The in-line scanner 42 performs a plurality of times of imaging on the medium 12 conveyed along the medium conveying direction at a fixed cycle, and acquires imaging data of the entire region of the medium 12. The imaging data of the imaging line 64 is given a jetting timing pulse number integrated value 54 corresponding to the imaging timing.

The jetting timing pulse number integrated value 54 is applied to the process of specifying the position in the medium transport direction in the imaging data 60. Further, the jetting timing pulse number integrated value 54 can be applied to processing such as distortion correction of imaging data and high resolution of imaging data 60.

[Control system configuration example]
FIG. 4 is a block diagram of the inkjet printing apparatus shown in FIG. The inkjet printing device 10 includes a system controller 100. The system controller 100 may be configured to include a CPU (not shown), a ROM (not shown), and a RAM (not shown).

The system controller 100 is an overall control unit that comprehensively controls each unit of the inkjet printing apparatus 10. The system controller 100 is a calculation unit that performs various calculation processes. The system controller 100 is a memory controller that controls reading and writing of data in the memory.

The inkjet printing device 10 includes a communication unit 102 and an image memory 104. The communication unit 102 includes a communication interface (not shown). The communication unit 102 transmits / receives data between the communication interface and the connected host computer 103.

The image memory 104 functions as a temporary storage unit for various data including image data. Data is read / written from the image memory 104 through the system controller 100. The image data taken in from the host computer 103 via the communication unit 102 is temporarily stored in the image memory 104.

The inkjet printing device 10 includes a transport control unit 110 and a print control unit 112. The transport control unit 110 controls the transport unit 20 based on a command signal transmitted from the system controller 100.

The print control unit 112 controls the print unit 30 based on the command signal transmitted from the system controller 100. The print control unit 112 controls the ink ejection of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y shown in FIG. Ink ejection is synonymous with jetting.

The print control unit 112 includes an image processing unit (not shown). The image processing unit forms dot data from the input image data. The image processing unit includes a color separation processing unit (not shown), a color conversion processing unit (not shown), a correction processing unit (not shown), and a halftone processing unit (not shown).

The color separation processing unit performs color separation processing on the input image data. For example, when the input image data is represented by RGB, the input image data is decomposed into data for each color of R, G, and B. Here, R represents red. G represents green. B represents blue.

The color conversion processing unit converts the image data for each color decomposed into R, G, and B into C, M, Y, and K corresponding to the ink color. Here, C represents cyan. M represents magenta. Y represents yellow. K represents black.

The correction processing unit performs correction processing on the image data for each color converted into C, M, Y, and K. Examples of the correction processing include a gamma correction processing, a density unevenness correction processing, an abnormality recording element correction processing, and the like.

The halftone processing unit converts image data represented by a multi-gradation number such as 0 to 255 into dot data represented by a binary value or a multi-valued value of three or more values less than the number of gradations of the input image data. Convert. The halftone processing unit applies a predetermined halftone processing rule. Examples of halftone processing rules include a dither method and an error diffusion method.

The print control unit 112 includes a waveform generation unit (not shown), a waveform storage unit (not shown), and a drive circuit (not shown). The waveform generator generates a waveform of the drive voltage. The waveform storage unit stores the waveform of the drive voltage.

The drive circuit generates a drive voltage having a drive waveform corresponding to the dot data. The drive circuit supplies the drive voltage to the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y shown in FIG.

That is, the jetting timing of each pixel position and the ink ejection amount are determined based on the dot data generated through the processing by the image processing unit. A control signal for determining the jetting timing of each pixel position, the drive voltage according to the ink ejection amount, and the jetting timing of each pixel is generated. A drive voltage and a control signal are supplied to the inkjet head, and dots are formed on the paper using the ink ejected from the inkjet head.

The inkjet heads not described with reference numerals may be any one of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y shown in FIG. 1, or the inkjet head 32K, the inkjet head 32C, and the inkjet head 32M. And the generic term for the inkjet head 32Y. The same applies to an inkjet head that does not have the following reference numerals.

The inkjet printing device 10 includes an operation unit 114 and a display unit 116. The operation unit 114 includes operation members such as operation buttons, a keyboard, and a touch panel. The operation unit 114 may include a plurality of types of operation members. The illustration of the operating member is omitted.

The information input using the operation unit 114 is transmitted to the system controller 100. The system controller 100 generates a command signal for executing various processes according to the information transmitted from the operation unit 114. The system controller 100 transmits a command signal to a processing unit that performs various processes.

The display unit 116 includes a display device (not shown) such as a liquid crystal panel, and a display driver (not shown). The display unit 116 causes the display device to display various setting information of the device and various information such as abnormality information in response to a command from the system controller 100.

The inkjet printing device 10 includes a parameter storage unit 118 and a program storage unit 120.

The parameter storage unit 118 stores various parameters used in the inkjet printing device 10. Various parameters stored in the parameter storage unit 118 are read out using the system controller 100. Various parameters are set in each part of the device using the system controller 100.

The program storage unit 120 stores programs used in each unit of the inkjet printing apparatus 10. Various programs stored in the program storage unit 120 are read out via the system controller 100 and executed in each unit of the device.

The inkjet printing device 10 includes an image pickup control unit 122. The image pickup control unit 122 controls the image pickup of the inline scanner 42. The image pickup control unit 122 acquires the image pickup data of the inline scanner 42. The imaged data is used for various processes such as defective nozzle check and image inspection. The image pickup control unit 122 is an example of a component of the image pickup data acquisition unit. Acquisition of imaging data includes generation of imaging data. The image pickup control unit 122 is a component that generates image pickup data using an image pickup signal.

The inkjet printing apparatus 10 includes a jetting timing pulse generation unit 126, a jetting timing pulse number integrated value calculation unit 128, and an analysis processing unit 130.

The jetting timing pulse generation unit 126 generates a jetting timing pulse by using the encoder measurement signal output from the encoder 24. The jetting timing pulse generation unit 126 generates individual jetting timing pulses for each of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y shown in FIG. The process of generating the jetting timing pulse from the encoder measurement signal is to increase the resolution of the signal by using the interpolation process.

The jetting timing pulse is transmitted to the print control unit 112 via the system controller 100. The print control unit 112 uses the jetting timing pulse to control the jetting timing of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y shown in FIG. The jetting timing pulse generation unit 126 is an example of a component of the measurement unit.

The jetting timing pulse number integrated value calculation unit 128 shown in FIG. 4 counts the jetting timing pulses and calculates the jetting timing pulse number integrated value for each imaging timing.

The jetting timing pulse number integrated value calculation unit 128 may include a counter for counting the jetting timing pulses and a storage unit for storing the jetting timing pulse number integrated value for each imaging timing in association with the imaging timing. The counter and the storage unit are not shown.

The jetting timing pulse number integrated value calculation unit 128 may calculate the jetting timing pulse number integrated value for each of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y.

The jetting timing pulse number integrated value calculation unit 128 calculates the jetting timing pulse number integrated value for any one head of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y, or any plurality of heads. You may.

The latest value is added to the imaging data for each imaging timing as the integrated value of the number of jetting timing pulses for each imaging timing. The jetting timing pulse number integrated value is used to specify the position of the nozzle inspection pattern in the medium transport direction in the imaging data when analyzing the imaging data. The jetting timing pulse number integrated value may be applied to the correction of distortion of the imaging data and the increase in resolution when analyzing the imaging data.

The jetting timing pulse number integrated value is initialized each time the imaging timing start signal is output. That is, the jetting timing pulse number integrated value at the imaging start timing of one medium is set to zero or a predetermined initial value.

The imaging start timing at which the imaging timing start signal is output is indicated by reference numeral 220 and is shown in FIG. The jetting timing pulse number integrated value calculation unit 128 is an example of an integrated value acquisition unit. The jetting timing pulse number integrated value is an example of the integrated value of the timing signal.

The analysis processing unit 130 analyzes the imaging data of the nozzle inspection pattern to detect defective nozzles. A defective nozzle is a nozzle in which a discharge abnormality such as non-discharge, discharge bending, or discharge amount abnormality has occurred.

The analysis processing unit 130 may execute analysis processing in image inspection such as correction of distortion of imaging data and high resolution. The analysis processing unit 130 may read a dedicated program from the program storage unit 120 and execute the analysis processing.

The inkjet printing apparatus 10 shown in FIG. 4 includes a medium size information storage unit 132 and an image information storage unit 134. The medium size information storage unit 132 stores information on the size of the medium. Information on the size of the medium may be obtained from a paper feeding unit (not shown), or may be input using the operation unit 114. The medium size information storage unit 132 is an example of a medium information acquisition unit. The acquisition in the present specification may include a mode of reading out the information stored in the storage unit.

The image information storage unit 134 stores information on the position of the nozzle inspection pattern in the input image data and information on the position of the product image. The position referred to here includes at least a position in the medium transport direction. As the position, two-dimensional coordinates expressed by using a set of a position in the medium transport direction and a position in the medium width direction may be applied. The image information storage unit 134 is an example of an image information acquisition unit.

The various processing units shown in FIG. 4 may be expressed as a processing unit using English notation. Processor is sometimes referred to as processor using English notation. The processing unit referred to here includes a substantial processing unit that executes some processing even if the name of the processing unit is not used.

Various processors execute specific processes such as CPU, which is a general-purpose processor that executes a program and functions as various processing units, PLD, which is a processor whose circuit configuration can be changed after manufacturing such as FPGA, and ASIC. It includes a dedicated electric circuit, which is a processor having a circuit configuration specially designed for the CPU. Program is synonymous with software.

FPGA is an abbreviation for Field Programmable Gate Array. PLD is an abbreviation for Programmable Logic Device. ASIC is an abbreviation for Application Specific Integrated Circuit.

One processing unit may be composed of one of these various processors, or may be composed of two or more processors of the same type or different types. For example, one processing unit may be configured by a plurality of FPGAs or a combination of a CPU and an FPGA. Further, a plurality of processing units may be configured by using one processor.

As an example of configuring a plurality of processing units with one processor, first, as represented by a computer such as a client or a server, one processor is configured by combining one or more CPUs and software. There is a form in which this processor functions as a plurality of processing units.

As typified by SoC, there is a form of using a processor that realizes the functions of the entire system including a plurality of processing units with one IC chip. As described above, the various processing units are configured by using one or more of the above-mentioned various processors as a hardware structure. Further, the hardware structure of these various processors is, more specifically, an electric circuit in which circuit elements such as semiconductor elements are combined.

Note that SoC is an abbreviation for System On Chip, which is an English notation for system on chip. IC is an abbreviation for Integrated Circuit, which is an English notation for integrated circuits. The electric circuit is sometimes expressed as circuitry using English notation.

[Explanation of nozzle inspection pattern]
FIG. 5 is a schematic diagram of a nozzle inspection pattern. FIG. 5 shows an example in which the nozzle inspection pattern 14A is printed on the rear end portion 12A of the medium 12. The rear end portion 12A of the medium 12 is a region between the rear end 12B of the medium 12 and the product image 14. The tip 12C of the medium 12 is a region between the product image 14 and the tip 12D of the medium 12.

A part of the nozzle inspection pattern 14A is enlarged and shown in the circle with reference numeral 14B in FIG. The nozzle inspection pattern 14A shown in FIG. 5 is a 1-on-N-off pattern. N is an integer of 1 or more. FIG. 5 illustrates a 1-on-4-off pattern.

The pattern element 14C constituting the 1-on-N-off pattern is formed by using each nozzle included in the inkjet head. The presence / absence, position, shape, and the like of the pattern element 14C can be analyzed to determine the presence / absence of an abnormality in each nozzle corresponding to each pattern element 14C. The defective nozzle in the following description represents a nozzle in which an abnormality has occurred.

The nozzle inspection pattern 14A is not limited to 1 on N off. A pattern that can determine the presence or absence of defects for each nozzle can be applied.

The area on which the product image 14 is printed on the medium 12 corresponds to the product image area. The area on which the nozzle inspection pattern 14A is printed corresponds to a non-commodity image area. The non-product image area is an example of an area other than the product image area.

[Problems of detecting defective nozzles using nozzle inspection patterns]
In a single-pass type inkjet printing device, if the nozzle of the inkjet head is clogged, the product image becomes uneven and becomes an image defect. It should be noted that streaks are synonymous with streaks.

In order to prevent streaks, a nozzle inspection pattern is added to a part of the printed image, the nozzle inspection pattern is imaged using an in-line scanner, and the imaged data is analyzed to detect the defective nozzle. Detection is possible.

It is practically appropriate that the nozzle inspection pattern is arranged at at least one of the front end portion of the medium other than the product image printing area and the rear end portion of the medium. It is common for the user of the printed matter to decide whether to place the nozzle inspection pattern at the front end of the medium or at the rear end of the medium in consideration of the cooperation with the post-processing process of the printed matter. ..

Then, it is appropriately determined whether the imaging region of the nozzle inspection pattern is the front end portion, the rear end portion, or both the front end portion and the rear end portion of the medium, and the in-line scanner is used. It needs to be controlled properly.

FIG. 6 is an explanatory diagram of a problem in searching for the position of the nozzle inspection pattern in the imaging data. Consider a case where defective nozzle detection using the nozzle inspection pattern 14A printed on the rear end portion 12A of the medium 12 and image inspection of the product image 14 are performed on one printed matter shown in FIG. An in-line scanner (not shown in FIG. 6) starts imaging from the front end 12D of the medium 12, executes imaging up to the rear end 12B of the medium 12, and acquires imaging data of a product image and imaging data of a nozzle inspection pattern. The method is considered to be efficient control.

[1]
Due to the influence of the problem of image structure distortion in the medium transport direction described above, there is a problem that the position of the nozzle inspection pattern 14A of the rear end portion 12A of the medium 12 becomes unstable in the image data of the in-line scanner. Occurs. That is, there is a problem that it is necessary to search for the cutting start position of the imaging data 61B of the nozzle inspection pattern in the imaging data 60.

Even if the image pickup start position 12E on the medium 12 can be grasped, the image pickup start position 12F of the nozzle inspection pattern 14A becomes unstable due to the influence of the feed unevenness of the medium 12. Then, even when the imaging start position 60B in the imaging data 60 is grasped, it is difficult to search for the position of the imaging data 61A of the product image 14 and the cutting start position 60C of the imaging data 61B of the nozzle inspection pattern.

Although a method of identifying the position of the nozzle inspection pattern 14A in the imaging data by performing image analysis of the imaging data can be considered, it may adversely affect both the processing stability and the processing cost. The adverse effect on the processing cost is considered to be due to the long processing period and the increase in the processing load.

[2]
The imaging data immediately after imaging by the in-line scanner is generally stored in a storage device such as a hard disk, or stored in a local memory provided in the in-line scanner. When performing image analysis of imaging data using a computer or the like, it is necessary to load the temporarily stored imaging data into the internal memory of the computer used for analysis.

However, the imaging data 60 obtained by imaging the entire surface of one medium 12 including the product image 14 has a large data size, and the processing cost is large in order to load the entire imaging data 60 into the internal memory of the computer. To become.

When the entire image pickup data 60 can be loaded into the internal memory of the computer, the image analysis of the image pickup data is performed to identify the nozzle inspection pattern 14A. Then, the processing cost may increase. That is, there is a problem that the processing cost is increased in the search for the imaging data of the nozzle inspection pattern 14A.

Here, the problem when the nozzle inspection pattern 14A is printed on the rear end portion 12A of the medium 12 has been described, but the position where the nozzle inspection pattern 14A is printed is on the medium 12 such as the front end portion 12C of the medium 12. A similar problem exists in cases other than the rear end portion 12A. In particular, when the nozzle inspection pattern 14A is printed on the rear end portion 12A of the medium 12 where uneven feeding of the medium can be accumulated, the above problem becomes remarkable.

[Identification of position in imaging data using integrated jetting timing pulse count]
In order to solve the above-mentioned problems, as a basic technique, jetting that is derived from the encoder measurement signal and represents information on the position of the transport unit with respect to the imaging data obtained by imaging using an in-line scanner. A timing pulse number integrated value 54 is added. Further, the jetting timing pulse number integrated value 54 is synchronously given to the end or the beginning of the imaging data for each imaging timing.

Then, when performing image processing using the imaging data, processing for dealing with the above-mentioned problems is performed by software using the jetting timing pulse number integrated value 54. As a result, it is possible to suppress the influence of uneven feeding of the medium and suppress the processing cost in specifying the position in the imaging data.

The generation of the jetting timing pulse and the calculation of the integrated value of the number of jetting timing pulses will be described in detail below.

[Explanation of jetting timing pulse generation]
FIG. 7 is an explanatory diagram of the jetting timing pulse. FIG. 7 shows a specific example of processing the encoder measurement signal 50 to generate the jetting timing pulse 52. The jetting timing pulse 52 shown in FIG. 7 is supplied to any one of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32Y shown in FIG.

FIG. 7 schematically shows the relationship between the printed image 76, the encoder measurement signal 50, and the jetting timing pulse 52. The horizontal axis of the encoder measurement signal 50 and the jetting timing pulse 52 represents the time. The vertical axis of the encoder measurement signal 50 and the jetting timing pulse 52 represents the voltage. The same applies to FIGS. 8, 10, and 16.

The printed image 76 includes a nozzle inspection pattern 14A. The nozzle inspection pattern 14A is printed on the rear end of the printed image 76. The rear end portion of the printed image 76 has the same meaning as the rear end portion 12A of the medium 12 shown in FIG.

The encoder measurement signal 50 includes a Z-phase signal 206 and an A-phase signal 208. The encoder measurement signal 50 may include a B-phase signal whose phase is shifted by a half cycle with respect to the A-phase signal 208. In the present embodiment, the Z-phase signal 206 and the A-phase signal 208 are positive logic pulse signals.

The Z-phase signal 206 is a pulse signal output in a predetermined angular phase during one rotation of the transport drum 22 shown in FIG. The Z-phase signal 206 shown in FIG. 7 has one pulse per rotation of the transport drum 22.

The print timing of the printed image 76 and the imaging timing of the in-line scanner 42 shown in FIG. 1 are synchronized with the Z-phase signal 206 using the Z-phase signal 206 as a reference signal.

The A-phase signal 208 is a pulse signal output for each displacement of a predetermined angular phase during one rotation of the transport drum 22. For example, the A-phase signal 208 may have 5000 pulses per rotation of the transport drum 22.

When the diameter of the transport drum 22 is 450 mm and the resolution of the encoder 24 is 5000 pulses per rotation, the resolution conversion value of the encoder obtained by converting the resolution of the encoder 24 into dots, which is a unit representing the imaging resolution, is about 91 dots. It will be every inch. When the imaging resolution is 200 dots per inch, the resolution conversion value of the encoder is less than the imaging resolution.

When the print resolution is 1200 dots per inch, the present embodiment corresponds to the case where the first print resolution conversion value obtained by converting the resolution of the encoder into the print resolution of the printing unit is less than the print resolution. 91 dots per inch is an example of the first print resolution conversion value.

The period of the A-phase signal 208 varies according to the uneven rotation speed of the transport drum 22. When the rotation speed of the transport drum 22 becomes relatively high, the period of the A-phase signal 208 becomes short. On the other hand, when the rotation speed of the transport drum 22 is relatively slow, the period of the A-phase signal 208 becomes long. The angular phase of the transport drum 22 can be calculated using the A-phase signal 208.

The jetting timing pulse generation unit 126 shown in FIG. 4 performs interpolation interpolation processing on the A-phase signal 208 shown in FIG. 7 to generate a jetting timing pulse 52. The jetting timing pulse 52 is an example of a timing signal in which the second print resolution conversion value, which represents a period in which the measurement signal is interpolated and converted into a unit value representing the print resolution, is equal to or higher than the print resolution. is there. The value obtained by converting the period of the jetting timing pulse 52 into a unit representing the print resolution is an example of the second print resolution conversion value.

Thereby, the influence of the rotation speed unevenness of the transport drum 22 can be canceled. Then, the printed image 76 becomes a distortion-free image without being affected by the rotation speed unevenness of the transport drum 22. The uneven rotation speed of the transport drum 22 corresponds to the uneven feed of the medium 12.

As the interpolation interpolation process, linear interpolation, which is a simple interpolation process, can be applied. As the interpolation interpolation process, spline interpolation, which is an interpolation process in which derivatives are smoothly connected, and polynomial approximation can be applied. The combination of smoothing and interpolation using a moving average can be applied to interpolation interpolation processing, although the signal after processing is slightly blunted. That is, various interpolation methods can be applied to the interpolation interpolation processing.

FIG. 7 shows an example in which the first pulse of the jetting timing pulse is output at the same timing as the Z-phase signal 206. Generally, the Z-phase signal 206 is output at the machine origin position of the transport drum 22.

If the machine origin position of the transfer drum 22 does not match the position of the inkjet head, one of the Z-phase signal 206 and the jetting timing pulse depends on the distance between the machine origin position of the transfer drum 22 and the position of the inkjet head. The delay period with the pulse is determined.

That is, the timing of the first pulse of the jetting timing pulse shown in FIG. 7 may be based on the Z-phase signal 206. The relationship between the Z-phase signal 206 shown in FIG. 8 and the imaging start timing is also the same.

[Explanation of jetting timing pulse number integrated value]
FIG. 8 is an explanatory diagram of a jetting timing pulse number integrated value. The jetting timing pulse number integrated value calculation unit 128 shown in FIG. 4 sequentially counts up the jetting timing pulse 52 shown in FIG. 8 for each pulse, and calculates the jetting timing pulse number integrated value 54.

Note that FIG. 8 shows an example of the relationship between the output timing of the Z-phase signal 206 and the imaging start timing, and shows an example of the relationship between the output timing of the Z-phase signal 206 and the jetting timing pulse 52. It is not intended to represent the relationship of.

In FIG. 8, the output timing of the Z-phase signal 206 coincides with the jetting start timing, and the output timing of the Z-phase signal 206 coincides with the imaging start timing. However, as shown in FIG. 1, the positions of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32K do not actually match the positions of the in-line scanner 42.

For example, when the output timing of the Z-phase signal 206 is the imaging start timing of the in-line scanner 42, the jetting start timings of the inkjet head 32K, the inkjet head 32C, the inkjet head 32M, and the inkjet head 32K and the imaging of the in-line scanner 42 A predetermined period is set between the start timing and the start timing. The same applies to FIGS. 10 and 12.

During the generation process of the jetting timing pulse 52 and the calculation process of the jetting timing pulse number integrated value 54, the image of the printed image 76 using the in-line scanner 42 shown in FIG. 1 is executed. The imaging control unit 122 shown in FIG. 4 generates an imaging start timing signal 220 indicating an imaging start timing with reference to the Z-phase signal 206 shown in FIG.

The imaging start timing is the first imaging timing in the imaging of the printed image 76 shown in FIG. There is a certain cycle between the second and subsequent imaging timings in the imaging of the printed image 76. In other words, the imaging timing control signal 56 is a pulse signal having a predetermined fixed value period.

The imaging performed by the in-line scanner 42 at one imaging timing is referred to as a sub-scanning scan. The first sub-scan scan is executed with the imaging start timing signal 220 shown in FIG. 8 as a trigger. The second and subsequent sub-scan scans are executed in a fixed value cycle triggered by the imaging timing control signal 56.

The image pickup control unit 122 acquires the jetting timing pulse number integrated value 54 for each sub-scan scan. The image pickup control unit 122 uses the image pickup timing control signal 56 as a trigger signal to acquire the jetting timing pulse number integrated value 54 at each image pickup timing. Each sub-scan scan may be read as each imaging timing.

Reference numeral 60A-1 shown in FIG. 8 represents the imaging data acquired in the first sub-scan scan. Reference numeral 60A-2 represents the imaging data acquired in the second sub-scan scan.

Reference numeral 54-1 represents a jetting timing pulse number integrated value acquired at the imaging start timing, which is the first imaging timing. Reference numeral 54-2 represents the integrated value of the number of jetting timing pulses acquired at the imaging start timing, which is the second imaging timing.

The imaging control unit 122 sets the jetting timing pulse number integrated value 54-1 acquired at the imaging start timing, which is the first imaging timing, with respect to the imaging data 60A-1 acquired in the first sub-scan scan. Add. In the example shown in FIG. 8, the jetting timing pulse number integrated value 54-1 is 0 pulse.

Similarly, the imaging control unit 122 adds the jetting timing pulse number integrated value 54-2 acquired at the second imaging timing to the imaging data 60A-2 acquired in the second sub-scanning scan. In the example shown in FIG. 8, the jetting timing pulse number integrated value 54-2 is 2 pulses.

The imaging control unit 122 adds the jetting timing pulse number integrated value acquired at each imaging timing to each of the imaging data acquired in the third and subsequent sub-scan scans.

In FIG. 8, the numerical value shown at each imaging timing is the integrated value of the number of jetting timing pulses added at each imaging timing. The same applies to FIGS. 10 and 16.

For the cycle of the jetting timing pulse 52, a value in which the image resolution conversion value converted into a value representing the unit of the image resolution exceeds the image resolution is applied. Further, in the example shown in FIG. 8, the imaging resolution conversion value of the jetting timing pulse 52 is twice the imaging resolution. The image resolution conversion value of the jetting timing pulse 52 may be an integral multiple of the image resolution. The integer here is two or more.

The jetting timing pulse number integrated value 54 represents the actual rotation phase of the transport drum 22 shown in FIG. In other words, the jetting timing pulse number integrated value 54 can be converted into a moving distance from an arbitrary reference position on the outer peripheral surface of the transport drum 22.

[Both imaging start control and defective nozzle detection during print job]
FIG. 9 is an explanatory diagram of an imaging start position in the imaging data and a cutting position of the imaging data of the nozzle inspection pattern. The imaging start position 60B in the imaging data 60A and the cutting start position 60C in the imaging data 61B of the nozzle inspection pattern can be identified by utilizing the jetting timing pulse number integrated value 54 for each imaging timing.

FIG. 9 schematically illustrates image data 60A of the product image 14, the medium 12 on which the nozzle inspection pattern 14A is printed, and the medium 12 on which the product image 14 and the nozzle inspection pattern 14A are printed.

Imaging of the medium 12 is performed from the front end 12D to the rear end 12B. The imaging start position 12E of the medium 12 is the tip 12D of the medium 12. Reference numeral 12F indicates an imaging start position of the nozzle inspection pattern 14A. The imaging region of the nozzle inspection pattern 14A is the rear end portion 12A of the medium 12.

First, the size of the medium 12 and the position of the nozzle inspection pattern 14A in the image data are known. Information on the size of the medium 12 is acquired from the medium size information storage unit 132 shown in FIG. Further, information on the position of the nozzle inspection pattern 14A in the image data is acquired as image information from the image information storage unit 134 shown in FIG.

Using the size information of the medium 12 and the image information, the number of jetting timing pulses from the imaging start position 60B in the imaging data 60A shown in FIG. 9 to the cutting start position 60C of the imaging data 61B of the nozzle inspection pattern. The integrated value 54 is calculated.

The imaging start position 60B in the imaging data 60A can be grasped by using the output timing of the imaging start timing signal 220 shown in FIG. In other words, the imaging start position 60B in the imaging data 60A can be grasped by using the imaging timing of the tip 12D of the medium 12.

The analysis processing unit 130 shown in FIG. 4 has a jetting timing pulse number integrated value 54 from the imaging start position 60B in the imaging data 60A shown in FIG. 9 to the cutting start position 60C of the nozzle inspection pattern imaging data 61B. By comparing the calculated value of the jetting timing pulse number integrated value at the cutting start position with the jetting timing pulse number integrated value 54 for each imaging timing, the cutting start of the imaging data 61B of the nozzle inspection pattern is performed. Search for position 60C.

The calculated value of the jetting timing pulse number integrated value at the cutting start position is shown in FIG. 10 with reference numeral 54A.

In other words, the analysis processing unit 130 shown in FIG. 4 searches for the sub-scanning pixel line 60D to which the jetting timing pulse number integrated value 54 corresponding to the cutting start position 60C in the imaging data 60A shown in FIG. 9 is added. To do. The sub-scanning pixel line is imaging data for each imaging timing, and is configured by using a plurality of pixels along the medium width direction. The sub-scanning pixel line is a pixel group for one pixel in the medium transport direction.

The analysis processing unit 130 shown in FIG. 4 acquires imaging data 61B of the nozzle inspection pattern in order from the sub-scanning pixel line 60D shown in FIG. The length of the image pickup data 61B of the nozzle inspection pattern in the medium transport direction can be grasped from the image information.

Reference numeral 60E indicates a cutout region. The cutout area 60E is a region cut out from the image pickup data 60A as the image pickup data 61B of the nozzle inspection pattern. The cutout region 60E is an example of the analysis target region.

FIG. 10 is an explanatory diagram of an imaging start timing in the imaging data and a cutting timing of the imaging data of the nozzle inspection pattern. Reference numeral 54-3 shown in FIG. 10 is an integrated value of the number of jetting timing pulses at the cutting start position 60C of the imaging data 61B of the nozzle inspection pattern.

Reference numeral 60A-3 represents a sub-scanning pixel line corresponding to the jetting timing pulse number integrated value 54-3. Reference numeral 54-4 is a jetting timing pulse number integrated value of the cutting end position of the imaging data 61B of the nozzle inspection pattern. Reference numeral 60A-4 represents a sub-scanning pixel line corresponding to the jetting timing pulse number integrated value 54-4.

[Explanation of procedure for detecting defective nozzles]
<< Overall procedure of defective nozzle detection method >>
FIG. 11 is a flowchart showing the flow of the procedure of the defective nozzle detection method. In the following description, FIGS. 4 and 7 to 10 and the like will be referred to as appropriate. The defective nozzle detection method described below includes an image analysis method. FIG. 11 lists the steps performed on a single medium according to the procedure.

First, the printing step S10 is executed. In the printing step S10, the product image 14 and the nozzle inspection pattern 14A shown in FIG. 9 are printed on the medium 12 by using the printing unit 30 shown in FIG. The details of the printing step S10 shown in FIG. 11 will be described later, but the printing step S10 includes a jetting step, an encoder measurement signal acquisition step, a jetting timing pulse generation step, and a jetting timing pulse number integrated value calculation step.

After the printing step S10, the imaging step S12 is executed. In the imaging step S12, imaging of the medium 12 shown in FIG. 9 is executed using the in-line scanner 42 shown in FIG. The details of the imaging step S12 shown in FIG. 11 will be described later, but the imaging step S12 includes a scanning step, a jetting timing pulse number integrated value acquisition step, a jetting timing pulse number integrated value addition step, and an imaging data storage step. Is done. In the imaging step S12, the imaging data 60A to which the jetting timing pulse number integrated value shown in FIG. 9 is added is acquired.

After the imaging step S12 shown in FIG. 11, the process proceeds to the imaging data acquisition step S14. In the imaging data acquisition step S14, the analysis processing unit 130 shown in FIG. 4 acquires the imaging data 60A to which the jetting timing pulse number integrated value shown in FIG. 9 is added.

After the imaging data acquisition step S14 shown in FIG. 11, the medium size information acquisition step S16 is executed. In the medium size information acquisition step S16, the analysis processing unit 130 shown in FIG. 4 acquires the size information of the medium from the medium size information storage unit 132.

After the medium size information acquisition step S16 shown in FIG. 11, the process proceeds to the image information acquisition step S18. In the image information acquisition step S18, the analysis processing unit 130 shown in FIG. 4 acquires image information from the image information storage unit 134. The order of the medium size information acquisition step S16 and the image information acquisition step S18 shown in FIG. 11 may be changed.

After the image information acquisition step S18, the process proceeds to the cutting start position jetting timing pulse number integrated value calculation step S20. Cutting start position In the jetting timing pulse number integrated value calculation step S20, the analysis processing unit 130 shown in FIG. 4 has a jet corresponding to the cutting start position 60C of the imaging data 61B of the nozzle inspection pattern shown in FIG. Calculate the integrated value of the number of ting timing pulses.

After the cutting start position jetting timing pulse number integrated value calculation step S20 shown in FIG. 11, the process proceeds to the cutting start position search step S22. In the cutting start position search step S22, the analysis processing unit 130 shown in FIG. 4 has a jetting timing pulse number integrated value corresponding to the cutting start position 60C of the imaging data 61B of the nozzle inspection pattern shown in FIG. Using the calculated value 54A, the cutting start position 60C of the imaging data 61B of the nozzle inspection pattern is searched.

After the cutting start position search step S22 shown in FIG. 11, the process proceeds to the cutting region imaging data acquisition step S24. In the cutout region imaging data acquisition step S24, the imaging data of the cutout region 60E shown in FIG. 9 is acquired and stored.

After the cutout region imaging data acquisition step S24 shown in FIG. 11, the process proceeds to the imaging data analysis step S26. In the imaging data analysis step S26, the analysis processing unit 130 shown in FIG. 4 analyzes the imaging data of the cutout region 60E shown in FIG. The analysis processing unit 130 identifies a defective nozzle based on the analysis result. The imaging data analysis step S26 is an example of an analysis processing step.

After the imaging data analysis step S26 shown in FIG. 11, the process proceeds to the analysis result storage step S28. In the analysis result storage step S28, the analysis processing unit 130 shown in FIG. 4 stores the number of the nozzle specified as the defective nozzle. After the analysis result storage step S28 shown in FIG. 11, the defective nozzle detection method for one medium is completed.

《Printing process》
FIG. 12 is a flowchart showing the flow of the procedure of the printing process shown in FIG. The printing step S10 shown in FIG. 11 includes a jetting step S100, an encoder measurement signal acquisition step S102, a jetting timing pulse generation step S104, and a jetting timing pulse number integrated value calculation step S106 shown in FIG.

When printing on the medium 12 using the printing unit 30 shown in FIG. 1, each step shown in FIG. 12 is executed in parallel. In the jetting step S100 shown in FIG. 12, the product image 14 based on the input image data is printed using the printing unit 30 shown in FIG.

Further, in the jetting step S100 shown in FIG. 12, the nozzle inspection pattern 14A shown in FIG. 9 is printed by using the printing unit 30 shown in FIG. The encoder measurement signal acquisition step S102 is executed in parallel with the jetting step S100 shown in FIG. In the encoder measurement signal acquisition step S102, the encoder 24 shown in FIG. 1 outputs an encoder measurement signal.

Further, in parallel with the jetting step S100 shown in FIG. 12, the jetting timing pulse generation step S104 is executed. In the jetting timing pulse generation step S104, the jetting timing pulse generation unit 126 shown in FIG. 4 generates a jetting timing pulse based on the encoder measurement signal.

Furthermore, in parallel with the jetting step S100, the jetting timing pulse number integrated value calculation step S106 is executed. In the jetting timing pulse number integrated value calculation step S106, the jetting timing pulse number integrated value calculation unit 128 shown in FIG. 4 calculates the jetting timing pulse number integrated value for each imaging timing.

For example, the jetting timing pulse number integrated value for each imaging timing is calculated by setting the jetting timing pulse number integrated value at the imaging start timing to zero or a predetermined initial value other than zero.

In this way, in the printing step S10 shown in FIG. 11, the jetting step S100, the encoder measurement signal acquisition step S102, the jetting timing pulse generation step S104, and the jetting timing pulse number integrated value calculation step S106 are performed in parallel. Will be executed.

<< Imaging process >>
FIG. 13 is a flowchart showing the flow of the procedure of the imaging process shown in FIG. The imaging step S12 shown in FIG. 11 includes a scanning step S120 shown in FIG. 13, a jetting timing pulse number integrated value acquisition step S122, a jetting timing pulse number integrated value addition step S124, and an imaging data storage step S126. ..

At the time of imaging using the in-line scanner 42 shown in FIG. 1, each step shown in FIG. 13 is executed in parallel. In the scanning step S120, the product image 14 and the nozzle inspection pattern 14A shown in FIG. 9 are imaged by using the in-line scanner 42.

Further, in parallel with the scanning step S120, the jetting timing pulse number integrated value acquisition step S122 is executed. In the jetting timing pulse number integrated value acquisition step S122, the imaging control unit 122 shown in FIG. 4 acquires the jetting timing pulse number integrated value for each imaging timing.

Further, in parallel with the scanning step S120 shown in FIG. 13, the jetting timing pulse number integrated value addition step S124 is executed. In the jetting timing pulse number integrated value addition step S124, the imaging control unit 122 shown in FIG. 4 adds the jetting timing pulse number integrated value for each imaging timing to the imaging data for each imaging timing.

Furthermore, the imaging data storage step S126 is executed in parallel with the scanning step S120 shown in FIG. In the imaging data storage step S126, the imaging control unit 122 shown in FIG. 4 stores imaging data for each imaging timing to which a jetting timing pulse number integrated value for each imaging timing is added.

Note that the term "execution in parallel" here may include a case where the processing periods of each process are asynchronously overlapped.

The imaging step S12 shown in FIG. 11 includes a series of steps from imaging to storage of imaging data for each imaging timing to which an integrated value of jetting timing pulses for each imaging timing is added.

Each process shown in FIG. 11, each process included in the printing process shown in FIG. 12, and each process included in the imaging process shown in FIG. 13 are distinguished for convenience, and are appropriately changed, added, and deleted. Etc. are possible. The replacement, division, and integration of each step may be carried out as appropriate.

[Action effect]
According to the printing apparatus configured as described above, the following effects can be obtained.

<< 1 >>
A jetting timing pulse number integrated value corresponding to an integrated value of the rotation phase of the transport drum is added to the imaging data for each imaging timing. Information on the size of the medium and information on the position of the nozzle inspection pattern in the image data are acquired. Using the information on the size of the medium and the information on the position of the nozzle inspection pattern in the image data, the jetting timing pulse number integrated value of the cutting start position in the imaging data is calculated.

The cutting start position in the imaging data is searched for using the calculated value of the jetting timing pulse number integrated value of the cutting start position in the imaging data. This facilitates the search for the cutting start position in the imaging data when analyzing the imaging data. In addition, the influence of uneven feeding during analysis of imaging data is suppressed.

<< 2 >>
The imaging data of the nozzle inspection pattern is cut out, and random access to the imaging data of the nozzle inspection pattern becomes possible. As a result, the increase in processing cost in the search for the imaging data of the nozzle inspection pattern is suppressed.

When a nozzle inspection pattern is printed on the rear end of the medium and imaging is started from the front end of the medium, the cumulative effect of the feed unevenness of the medium generated on the rear end side of the medium is large. In such a case, the effect of suppressing the increase in processing cost in the search for the imaging data of the nozzle inspection pattern is great.

<< 3 >>
Jetting timing The jetting timing is controlled using a pulse. As a result, the product image corrected for the influence of the uneven feeding of the medium is printed. The pulse number integrated value of the jetting timing pulse used for correcting the influence of the feed unevenness of the medium in the product image is acquired for each imaging data for each imaging timing. This makes it possible to specify the position of the imaging data of the nozzle inspection pattern in which the influence of uneven feeding of the medium is suppressed. The position here can be read as an area.

[Modified example of acquiring imaging data of nozzle inspection pattern]
Next, the defective nozzle detection according to the modified example will be described. FIG. 14 is an explanatory diagram of defective nozzle detection according to a modified example. The difference from the defective nozzle detection described above will be mainly described below.

[Explanation of issues]
Depending on the system configuration of the printing device, when searching for the cutout start position 60C from the imaging data 60A shown in FIG. 14, the process may not be executed until the entire imaging data 60A is loaded into the memory. ..

In such a case, the cutout start position 60C and the cutout area 60E can be searched from the imaging data 60A by using the following procedure.

[Explanation of the configuration for realizing defective nozzle detection according to the modified example]
In the defective nozzle detection according to the modified example, the imaging data is cut out in two stages. The analysis processing unit 130 shown in FIG. 4 ensures that the nozzle inspection pattern is in the imaging data 60A shown in FIG. 14 based on the size information of the medium 12 and the position information of the nozzle inspection pattern in the image data. The rough read area 60F, which is an imaged area, is specified.

Next, the memory in which the imaging data 60A is loaded is randomly accessed to load the rough read area 60F of the imaging data. For the rough read area 60F of the imaging data, the cutting start position 60C and the cutting area 60E are searched using the integrated value of the jetting timing pulses. The analysis processing unit 130 shown in FIG. 4 analyzes the cutout region 60E to identify defective nozzles.

[Explanation of procedure of defective nozzle detection method according to modified example]
FIG. 15 is a flowchart showing the flow of the procedure of the defective nozzle check method according to the modified example. In the flowchart shown in FIG. 15, a rough read area information acquisition step S30 and a rough read area read step S32 are added to the flowchart shown in FIG.

Further, the analysis step S34 shown in FIG. 15 includes a cutting start position jetting timing pulse number integrated value calculation step S20, a cutting start position search step S22, a cutting region imaging data acquisition step S24, and imaging. The data analysis step S26 and the analysis result storage step S28 are included.

In the rough read area information acquisition step S30 shown in FIG. 15, the analysis processing unit 130 shown in FIG. 4 acquires information for identifying the rough read area 60F shown in FIG. An example of the information for specifying the rough read area 60F is the address of the storage area of the rough read area 60F in the memory in which the imaging data 60A is loaded.

After the rough read area information acquisition step S30 shown in FIG. 15, the process proceeds to the rough read area read step S32. In the rough read area read step S32, the analysis processing unit 130 shown in FIG. 4 reads the rough read area 60F from the memory in which the imaging data 60A is loaded, using the information for identifying the rough read area 60F.

After the rough read area read step S32 shown in FIG. 15, the analysis step S34 is executed. In the analysis step S34, the imaging data of the nozzle inspection pattern 14A is extracted from the rough reading area 60F, the imaging data of the nozzle inspection pattern 14A is analyzed, and the defective nozzle is identified and stored. The rough read area 60F is an example of a printable area.

[Action and effect of modified example]
According to the printing apparatus configured as described above and the image inspection method, when the entire imaging data is loaded into the memory, the medium size information and the position information of the nozzle inspection pattern in the image data are used. In the imaged data, a rough read area that is guaranteed to include a pattern for nozzle inspection is specified. This allows random access to the storage unit in which the entire imaging data is stored.

The cutting start position and the cutting area are specified from the rough read area using the jetting timing pulse number integrated value. Analyze the cutout area to identify defective nozzles. As a result, it is possible to suppress an increase in processing cost when extracting the cutout region.

[Example of application to the mode of performing image inspection]
Next, distortion correction of the product image using the jetting timing pulse number integrated value and high resolution will be described. The image inspection is an inspection of a printed image that determines the presence or absence of defects in the printed image based on the difference between the captured data of the printed image and the reference image.

〔problem〕
<< 1 >>
When performing image inspection and defective nozzle detection for a single medium, it is caused by the influence of image structure distortion in the medium transport direction when specifying the position of the imaging data 61B of the nozzle inspection pattern shown in FIG. As a result, the position of the imaging data 61B of the nozzle inspection pattern becomes unstable. When image inspection is not performed, it is possible to match the imaging timing of the nozzle inspection pattern 14A with the position of the nozzle inspection pattern 14A by using the encoder measurement signal. However, when performing image inspection, this method is used. Is difficult to adopt.

<< 2 >>
In the medium transport direction, the resolution of the captured data may be insufficient with respect to the resolution of the printed image.

When image pickup is performed using an image pickup device equipped with an image pickup element such as a CCD image sensor and a CMOS image sensor, it is difficult to obtain good image pickup data if the image pickup element cannot store a certain amount of light. As a solution to this, it is conceivable to increase the amount of illumination light at the time of imaging, increase the aperture of the imaging optical system to decrease the numerical aperture, and increase the imaging sensitivity of the image sensor. The numerical aperture may be referred to as F value or NA. NA is an abbreviation for Numerical Aperture.

However, all of the above solutions may be difficult to apply due to hardware restrictions, optical requirements, and the like. Examples of restrictions on optical requirements include an imaging region, contrast, and resolving power. If it is difficult to apply the above solution, a solution of lengthening the exposure period of the image sensor may be applied.

On the other hand, if the exposure period is lengthened when the line sensor type image sensor is applied, drawback may occur in which the resolution in the medium transport direction is lowered. Then, it is fully possible that the resolution of the captured data is insufficient with respect to the resolution of the printed image.

In a situation where the resolution of the captured data is insufficient with respect to the resolution of the printed image, the analysis accuracy deteriorates when image processing is performed to analyze the image structure of the printed image in the medium transport direction in detail using the captured data of the inline scanner. Can be done. For example, in the inspection of a printed image using input image data such as PDF format image data as a reference image, the analysis accuracy may deteriorate when the resolution of the imaging data is lower than the resolution of the reference image data. A technical solution to this problem is desired. Hereinafter, the image structure distortion may be described as distortion.

[Aspects in which image inspection and defective nozzle detection are used together]
FIG. 16 is an explanatory diagram when image inspection and defective nozzle detection are used in combination. The image inspection can be applied to both the case where the input image data such as the image data in the PDF format is used as the reference image data, the case where the reference print image is used as the reference image data, which is a printed image which can be regarded as the reference image. is there.

As described above, the jetting timing pulse number integrated value 54 for each imaging timing is added to the imaging data for each imaging timing.

In the example shown in FIG. 16, the imaging resolution in the medium transport direction is less than the print resolution in the medium transport direction. For example, the imaging resolution in the medium transport direction is 200 dots per inch, and the print resolution in the medium transport direction is 1200 dots per inch.

In this case, one pixel of the imaging data includes a plurality of printing pixels in the medium transport direction. On the other hand, in the jetting timing pulse 52, the resolution conversion value obtained by converting the period into the value of the unit representing the print resolution matches the print resolution. The resolution conversion value of the cycle of the jetting timing pulse 52 may be equal to or higher than the print resolution.

In the above specific example, when there is no uneven feeding of the medium 12, the integrated value of the number of jetting timing pulses for one pixel of the imaging data is 6. On the other hand, when the feed unevenness of the medium 12 occurs, the integrated value of the number of jetting timing pulses for one pixel of the imaging data is 6 or more or 6 or less.

On the other hand, the relationship between the integrated value of the number of jetting timing pulses and the amount of movement of the medium 12 in the medium transport direction is not affected by the uneven feeding of the medium 12, so the integrated value of the number of jetting timing pulses in one imaging period. Represents the amount of movement of the medium 12 in the medium transport direction in one imaging period.

Therefore, the number of pixels corresponding to the integrated value of the jetting timing pulses for each imaging timing is interpolated with respect to the imaging data for each imaging timing. Then, the distortion of the captured data of the product image 14 is corrected in the medium transport direction. Interpolation interpolation is applied to at least the captured data of the product image 14. Interpolation interpolation may be applied to the imaging data of the nozzle inspection pattern 14A.

In addition, one or more pixels are interpolated into one pixel of the imaged data. As a result, the captured data of the product image 14 is increased in resolution. Reference numeral 60G in FIG. 16 indicates the corrected imaging data in which the distortion of the imaging data of the product image 14 is corrected and the imaging data of the product image 14 is increased in resolution.

[Specific examples of distortion correction and high resolution]
Let Pixel_k be any pixel in the imaging data 60A. k is an integer representing the pixel number in the sub-scanning direction. Let the pixel value of pixel Pixel_k be Scan_k. Let PulseSum_k be the integrated value of the number of jetting timing pulses of pixel Pixel_k. Pixel_k is expressed as Pixel_k (Scan_k, PulseSum_k) by using a pair of a pixel value of Scan_k and a jetting timing pulse number integrated value of PulseSum_k.

Consider consecutive pixels Pixel_k (Scan_k, PulseSum_k) and Pixel_k + 1 (Scan_k + 1, PulseSum_k + 1). Assuming that the difference between the pixel PulseSum_k + 1 and the pixel PulseSum_k is 5, 4 pixels are inserted between the pixel Pixel_k and the pixel Pixel_k + 1. The pixel values of the four pixels to be inserted are interpolated from the value of the pixel value Scan_k + 1 and the value of the pixel value Scan_k.

That is, for one pixel of the imaging data 60A, the number of pixels corresponding to the integrated value of the jetting timing pulses added to the imaging data 60A is interpolated. When the feed unevenness of the medium does not occur, the integrated value of the number of jetting timing pulses added to each imaging data 60A is a fixed value. When the print resolution is 1200 dots per inch and the imaging resolution is 200 dots per inch, the increase in the jetting timing pulse number integrated value added to each imaging data 60A is 6.

On the other hand, when the feed of the medium is delayed, the increase in the integrated value of the number of jetting timing pulses added to each imaging data 60A is 6 or more. When the medium is fed, the increase in the jetting timing pulse number integrated value added to each imaging data 60A is 6 or less.

The integrated value of the number of jetting timing pulses may be the number of increases in the number of jetting timing pulses in each imaging period. The integrated value may include a relative integrated value.

Examples of interpolation include linear interpolation, spline interpolation, polynomial approximation, and a combination of smoothing and interpolation using a moving average. As the interpolation interpolation applied to the imaging data 60A, the interpolation interpolation when the jetting timing pulse 52 is generated from the encoder measurement signal 50 may be applied.

That is, the information of the interpolation interpolation when the jetting timing pulse 52 is generated from the encoder measurement signal 50 is retained as the signal interpolation information 84, and can be applied to the interpolation of the imaging data. The analysis processing unit 130 shown in FIG. 4 may include an option input for acquiring signal interpolation information 84.

The region of the captured data 61A of the product image 14 in the captured data 60A shown in FIG. 16 is an example of the analysis target region.

[Action and effect of application example]
<< 1 >>
For one pixel of the imaging data for each imaging timing, the number of pixels corresponding to the integrated value of the jetting timing pulses is interpolated. As a result, distortion correction of imaging data and high resolution can be performed efficiently and with high accuracy.

<< 2 >>
The captured data is highly resolved. In the image inspection using the input image data as the reference image, it is possible to omit the resolution compression of the input image data or relax the compression ratio. This makes it possible to improve the accuracy of image inspection. In addition, the processing load of image processing of input image data is reduced.

[Other application examples]
[Application examples of distortion correction and high resolution]
The above-mentioned distortion correction and high resolution can be applied to the cutout region 60E. With respect to the cutout region 60E, the influence of uneven feeding of the medium is suppressed. Further, the influence of insufficient imaging resolution is suppressed for the cutout region 60E.

[Type of medium]
A continuous medium may be used instead of the single-wafer medium. As the continuous medium, continuous paper may be applied. It is possible to apply one image area corresponding to one sheet of the single-wafer medium to the continuous medium and perform the same processing as the single-leaf medium for each image area.

[Application example of analysis processing result]
Other application examples of defective nozzle detection and image inspection include head module alignment amount measurement function, head-to-head registration deviation measurement function, printed image distortion amount measurement function, printed matter front and back registration deviation measurement function, and sujimura measurement function. .. It can also be applied to improve the efficiency of area search when analyzing the imaging data of an in-line scanner when inserting various test charts into an arbitrary area.

[Example of application to other media transfer methods]
In the present embodiment, a printing device for rotating and transporting a medium using a transport drum is illustrated, but the imaging data correction according to the present embodiment is also applied to a printing device that linearly transports a medium using a transport mechanism such as a transport belt. Applicable.

In a linear transfer type printing device, a measurement signal may be acquired from an encoder attached to a rotary shaft of a motor that is a drive source of a transfer mechanism. Further, the measurement signal may be acquired from the linear encoder that detects the position of the movable portion of the transport mechanism.

[Example of application to other printing devices]
In the present embodiment, an inkjet printing device has been illustrated, but the printing method is not limited to the inkjet printing method. For example, the imaging data correction according to the present embodiment can be applied to an electrophotographic printing apparatus. Further, the imaging data correction according to the present embodiment can also be applied to a plate printing device that controls printing timing by using a signal derived from a measurement signal of an encoder attached to a transport device that conveys a medium.

The signal derived from the encoder measurement signal is a signal obtained by subjecting the encoder measurement signal to processing such as interpolation. The signal derived from the encoder measurement signal may include the encoder measurement signal.

It is possible to configure an image analysis apparatus by using some of the components of the printing apparatus shown in the present embodiment. For example, an image analysis device that analyzes imaging data can be configured by using a system controller 100, an analysis processing unit 130, and the like. An image analysis method including a step corresponding to each part of the image analysis apparatus can be configured.

[Example of application to programs]
The defective nozzle detection and the image analysis in the defective nozzle detection shown in the present embodiment can be realized by using an image analysis program that causes a computer to execute the functions of each part or each process. For example, using an image analysis program that causes a computer to execute an imaging data acquisition function, an analysis processing function, a transport function, a printing function, an imaging function, a measurement function, an integrated value acquisition function, a medium information acquisition function, and an image information acquisition function. It is possible to realize image analysis in detecting defective nozzles and detecting defective nozzles. Further, it is possible to construct a non-temporary and computer-readable recording medium such as a hard disk, a CD (Compact Disk), a DVD (Digital Versatile Disk), and various semiconductor memories in which an image analysis program is stored.

[Combination of Embodiments and Modifications]
The components described in the above-described embodiment and the components described in the modified examples can be used in combination as appropriate, or some components can be replaced.

[Explanation of terms]
The medium includes what is called recording paper, recording paper, and the like. Further, the medium includes a sheet-like member made of a material other than paper capable of recording an image using ink, such as a resin sheet and a metal sheet. The medium may include either a single-wafer medium or a continuous medium.

The ink includes a liquid for graphic use containing a coloring material. The ink may include a transparent or translucent liquid that does not contain a coloring material, and an industrial liquid that contains resin particles, metal particles, and the like.

The medium transport direction may be referred to as a paper transport direction, a sub-scanning direction, or the like. The medium width direction may be referred to as a paper width direction, a main scanning direction, or the like.

Printing may include concepts such as image recording, drawing, and image formation. The image may include characters, figures, patterns, patterns and the like. The printed image may include an image to be a printed matter, an attached image such as a test pattern, and the like.

Orthogonality includes a substantial right angle that can obtain the same effect as when intersecting at 90 degrees when intersecting at an angle less than 90 degrees or at an angle exceeding 90 degrees due to an error or the like. Is done.

Along the line includes a case where a plurality of components are arranged in a straight line, a case where a plurality of components are arranged in a zigzag pattern with respect to a straight line, and the like. The direction along the line includes parallelism. Parallel includes substantially parallel, which can obtain the same effect as parallel when it is non-parallel due to an error or the like.

In the embodiment of the present invention described above, the constituent requirements can be appropriately changed, added, or deleted without departing from the spirit of the present invention. The present invention is not limited to the embodiments described above, and many modifications can be made by a person having ordinary knowledge in the art within the technical idea of the present invention.

10 Inkjet printing device 12 Medium 12A Rear end 12B Rear end 12C Tip 12D Tip 12E Imaging start position on medium 12F Imaging start position of nozzle inspection pattern 14 Product image 14A Nozzle inspection pattern 14C Pattern element 20 Transport unit 22 Transport drum 22A Outer surface 24 Encoder 30 Printing unit 32K, 32C, 32M, 32Y Inkjet head 40 Imaging unit 42 In-line scanner 50 Encoder measurement signal 52 Jetting timing pulse 54 Jetting timing Pulse number integrated value 54A Jetting corresponding to the cutting start position Calculated value of integrated timing pulse number 56 Imaging timing control signal 60, 60A Imaging data 60B Imaging start position 60C Clipping start position 60D Sub-scanning pixel line 60E Clipping area 60F Rough reading area 60G Corrected imaging data 61A Imaging data of product image 61B Nozzle inspection pattern imaging data 62 pixels 64 imaging line 84 signal interpolation information 100 system controller 102 communication unit 103 host computer 104 image memory 110 transport control unit 112 print control unit 114 operation unit 116 display unit 118 parameter storage unit 120 program storage Unit 122 Imaging control unit 126 Jetting timing pulse generation unit 128 Jetting timing pulse number integrated value calculation unit 130 Analysis processing unit 132 Media size information storage unit 134 Image information storage unit 206 Z-phase signal 208 A-phase signal 220 Imaging start timing signal S10 to S34, S100 to S126 Each step of the image inspection method

Claims (16)

Acquires the imaging data of the printed image that is imaged using the imaging device arranged in the transport path of the transport unit and that is captured at the imaging timing of each region in which the printed image is divided into a plurality of regions in the transport direction of the medium. Image data acquisition unit and
An analysis processing unit that analyzes the imaging data acquired by using the imaging data acquisition unit, and an analysis processing unit.
With
The imaging data acquisition unit acquires imaging data in which an integrated value of the number of pulses of a timing signal, which is a pulse signal representing the position or phase of the transport unit, is added to the imaging data for each imaging timing.
The analysis processing unit is an image analysis device that uses the integrated value to specify an analysis target region of the imaging data. A transport unit that transports media along the media transport direction,
A printing unit that prints on a medium transported using the transport unit,
The imaging data of the printed image captured by the imaging device arranged in the transport path of the transport unit and captured at the imaging timing of each region in which the printed image is divided into a plurality of regions in the transport direction of the medium. The image data acquisition unit to be acquired and
An analysis processing unit that analyzes the imaging data acquired by using the imaging data acquisition unit, and an analysis processing unit.
A measuring unit that acquires a timing signal that is a pulse signal representing the position or phase of the transport unit, and
An integrated value acquisition unit that acquires an integrated value of the number of pulses of the timing signal, and
With
The imaging data acquisition unit acquires imaging data to which the integrated value is added to the imaging data for each imaging timing.
The analysis processing unit is a printing device that identifies an analysis target area of the imaging data using the integrated value. The printing apparatus according to claim 2, further comprising a print control unit that controls the printing unit using the timing signal. The measuring unit includes an encoder that measures the position or phase of the transport unit and outputs a measurement signal, and the first print resolution conversion value obtained by converting the resolution of the encoder into the print resolution of the printing unit is obtained. When the print resolution is lower than the print resolution, the second print resolution conversion value representing the period converted into the value of the unit representing the print resolution by performing interpolation interpolation on the measurement signal is equal to or higher than the print resolution. The printing apparatus according to claim 3, which acquires a timing signal. The media information acquisition unit that acquires information on the size of the medium,
An image information acquisition unit that acquires information on the position of a printed image on a medium,
With
The analysis processing unit acquires the information of the print area on which the image to be analyzed specified by using the size information of the medium and the position information of the print image is printed, and uses the information of the print area as the information. The printing apparatus according to any one of claims 2 to 4, wherein a print-compatible area in the imaging data corresponding to the print area is extracted, and the analysis target area is specified from the print-compatible area. The printing unit prints a test pattern used for detecting an abnormal printing element, and prints the test pattern.
The printing apparatus according to any one of claims 2 to 5, wherein the analysis processing unit specifies an area on which the test pattern is printed as the analysis target area. The printing apparatus according to claim 6, wherein the printing unit prints the test pattern in a non-product image area other than the product image area on which the product image is printed. The printing apparatus according to claim 7, wherein the printing unit prints the test pattern on the non-commodity image area at the rear end of the medium in the medium transport direction. The printing apparatus according to claim 7 or 8, wherein the analysis processing unit uses the integrated value of the timing signal to specify the product image area. The imaging data acquisition unit acquires imaging data captured by applying an imaging resolution lower than the printing resolution of the printed image.
The printing apparatus according to claim 9, wherein the analysis processing unit corrects distortion caused by uneven feeding of the medium and increases the resolution of the imaged data in the product image area. The analysis processing unit interpolates the number of pixels corresponding to the integrated value of the number of pulses of the timing signal added to the imaged data with respect to one pixel of the imaged data of the product image area. The printing apparatus described in. The analysis processing unit determines the distortion of the product image due to uneven feeding of the medium, and based on the difference between the captured data of the product image region subjected to the high resolution and the reference image of the product image. The printing apparatus according to claim 10 or 11, wherein an image inspection for determining the presence or absence of an image defect is performed. The imaging data acquisition unit acquires imaging data captured by applying an imaging resolution lower than the printing resolution of the printed image.
The printing apparatus according to any one of claims 2 to 12, wherein the analysis processing unit corrects distortion caused by uneven feeding of the medium and increases the resolution of the analysis target region. Acquires the imaging data of the printed image that was imaged using the imaging device arranged in the transport path of the transport unit and that was captured at the imaging timing of each region in which the printed image was divided into a plurality of regions in the transport direction of the medium. Imaging data acquisition process and
An analysis processing step for analyzing the imaging data acquired in the imaging data acquisition process, and
Including
In the imaging data acquisition step, imaging data obtained by adding an integrated value of the number of pulses of a timing signal, which is a pulse signal representing the position or phase of the transport unit, to the imaging data for each imaging timing is acquired.
The analysis processing step is an image analysis method for specifying an analysis target region of the imaging data by using the integrated value. On the computer
Acquires the imaging data of the printed image that was imaged using the imaging device arranged in the transport path of the transport unit and that was captured at the imaging timing of each region in which the printed image was divided into a plurality of regions in the transport direction of the medium. It is a program that realizes an image pickup data acquisition function and an analysis processing function that analyzes the image pickup data acquired by using the image pickup data acquisition function.
The imaging data acquisition function acquires imaging data in which an integrated value of the number of pulses of a timing signal, which is a pulse signal representing the position or phase of the transport unit, is added to the imaging data for each imaging timing.
The analysis processing function is a program that identifies an analysis target area of the imaging data using the integrated value. A non-temporary, computer-readable recording medium when the instructions stored in the recording medium are read by a computer.
Acquires the imaging data of the printed image that is imaged using the imaging device arranged in the transport path of the transport unit and that is captured at the imaging timing of each region in which the printed image is divided into a plurality of regions in the transport direction of the medium. Imaging data acquisition function and
An image analysis function including an analysis processing function for analyzing the imaging data acquired by using the imaging data acquisition function.
The imaging data acquisition function acquires imaging data in which an integrated value of the number of pulses of a timing signal, which is a pulse signal representing the position or phase of the transport unit, is added to the imaging data for each imaging timing.
The analysis processing function is a recording medium that allows a computer to realize an image analysis function that identifies an analysis target area of the imaging data by using the integrated value.