Abstract: An image inspection device analyzes data of a first read image obtained by reading a defective nozzle detection pattern which is recorded in a first region of a recording medium by a single pass ink jet printing apparatus to detect a defective nozzle of a line-type ink jet head used to record the defective nozzle detection pattern and stores a history of the detection result of the defective nozzle in a history information storage unit. The image inspection device analyzes data of a second read image of a printed image recorded in a second region of the recording medium to detect an image defect of the printed image and collates information about the detected image defect with history information stored in the history information storage unit to specify a defective nozzle causing the image defect.

Abstract: An image inspection device analyzes data of a first read image obtained by reading a defective nozzle detection pattern which is recorded in a first region of a recording medium by a single pass ink jet printing apparatus to detect a defective nozzle of a line-type ink jet head used to record the defective nozzle detection pattern and stores a history of the detection result of the defective nozzle in a history information storage unit. The image inspection device analyzes data of a second read image of a printed image recorded in a second region of the recording medium to detect an image defect of the printed image and collates information about the detected image defect with history information stored in the history information storage unit to specify a defective nozzle causing the image defect.

Abstract: The positional displacement shift amount between the head modules is calculated in a first dynamic range and with a first arithmetic accuracy, and calculated in a second dynamic range wider than the first dynamic range and with a second arithmetic accuracy rougher than the first arithmetic accuracy and finer than the first dynamic range, and as a positional displacement shift amount between the head modules in the first direction, the positional displacement shift amount with the second arithmetic accuracy is selected if the positional displacement shift amount with the second arithmetic accuracy exceeds the first dynamic range, and the positional displacement shift amount with the first arithmetic accuracy is selected if within the first dynamic range.

Abstract: The positional displacement shift amount between the head modules is calculated in a first dynamic range and with a first arithmetic accuracy, and calculated in a second dynamic range wider than the first dynamic range and with a second arithmetic accuracy rougher than the first arithmetic accuracy and finer than the first dynamic range, and as a positional displacement shift amount between the head modules in the first direction, the positional displacement shift amount with the second arithmetic accuracy is selected if the positional displacement shift amount with the second arithmetic accuracy exceeds the first dynamic range, and the positional displacement shift amount with the first arithmetic accuracy is selected if within the first dynamic range.

Abstract: An image processing method includes: forming an image for density unevenness measurement on a recording medium in a single-pass method, using an inkjet head in which nozzles are disposed in a main scanning direction; acquiring a density measurement value of each set gradation value from an image for density unevenness measurement before drying; converting the acquired density measurement value into a conversion density measurement value corresponding to a post-dry density measurement value, using a density measurement value conversion value set for each region in the main scanning direction; and deriving a new unevenness correction value using this conversion density measurement value.

Abstract: A liquid is ejected which has a volume exceeding a volume for forming a dot of a maximum size used in regular liquid ejection to output a high load pattern, an ejection abnormality detection pattern is output for detecting an ejection element abnormality within a specific period of time from outputting the high load pattern, read data of the output ejection abnormality detection pattern is acquired, and the acquired read data is analyzed to detect an abnormal ejection element.

Abstract: A liquid is ejected which has a volume exceeding a volume for forming a dot of a maximum size used in regular liquid ejection to output a high load pattern, an ejection abnormality detection pattern is output for detecting an ejection element abnormality within a specific period of time from outputting the high load pattern, read data of the output ejection abnormality detection pattern is acquired, and the acquired read data is analyzed to detect an abnormal ejection element.

Abstract: An image processing method includes: forming an image for density unevenness measurement on a recording medium in a single-pass method, using an inkjet head in which nozzles are disposed in a main scanning direction; acquiring a density measurement value of each set gradation value from an image for density unevenness measurement before drying; converting the acquired density measurement value into a conversion density measurement value corresponding to a post-dry density measurement value, using a density measurement value conversion value set for each region in the main scanning direction; and deriving a new unevenness correction value using this conversion density measurement value.

Abstract: In the optimization of a non-discharge correction parameter for correcting a non-discharge using a non-discharge correction nozzle, a first test chart including a non-recording region that is the recording position of the non-discharge correction nozzle, a measurement chart region where a measurement chart is formed, and a uniform concentration region is formed for a designated nozzle that is previously designated. Then, the first test chart is read, the reading data is analyzed, the concentration at the measurement chart and the concentration at the uniform concentration region are compared for each non-discharge correction parameter, and a non-discharge correction parameter corresponding to the concentration at the measurement chart that minimizes the concentration difference from the uniform concentration region is derived as the optimum value of the non-discharge correction parameter for the designated nozzle.

Abstract: The present invention provides an image recording method and apparatus and a recording medium therefor. In an aspect of the present invention, when recording the image in a condition where an image recording range in a first direction by the image recorder is a specific range, image processing is applied to the image data using a latest image processing parameter among image processing parameters which are according to positions in the first direction and have been generated on the basis of measurement results of test charts output using the specific range or a wider range than the specific range on the image recorder, and the image recorder is caused to record the image on the recording medium according to the image data after the image processing.

Abstract: Unevenness correcting information is generated based on property information indicating a recording property of each of a plurality of recording elements which are included in a recording head, the recording elements being subjected to output correction in a first output correction unit based on unevenness correcting information obtained after a flattening processing and output correction in a second output correction unit, and the unevenness correcting information close to an appropriate value with which an image in an appropriately-corrected state can be obtained can be generated.

Abstract: A method for controlling an image recording apparatus includes: detecting a defective recording element out of a plurality of recording elements on a recording head for recording an image on a recording medium; performing a correction processing including suspension of an output of the defective recording element and increase of an output of a recording element at least adjacent to the defective recording element according to a detection result; determining whether or not an image defect is caused in the image by the suspension of output of the defective recording element, before performing the correction processing, according to the detection result; selecting a forced recording element that is forced to output ink out of defective recording elements when it is determined that the image defect is caused; and suspending the output of the defective recording element other than the forced recording element when the forced recording element is selected.

Abstract: The present invention relates to an ink jet recording apparatus and method. In an aspect of the present invention, uneven concentration correction and non-ejection correction are performed at the time of drawing an image. In the non-ejection correction, a non-ejecting nozzle and a deflected ejection nozzle are detected as a defective nozzle, the detected defective nozzle is not allowed to eject ink to perform the non-ejection correction. When a deflected ejection nozzle is detected, an allowable value range of a deflected ejection amount of each of nozzles with respect to a deflected ejection amount of each of nozzles at the time of creating an uneven concentration correction parameter is determined. A nozzle in which a deflected ejection amount exceeds the allowable value range so that the deflected ejection occurs is detected as a deflected ejection nozzle.

Abstract: In the optimization of a non-discharge correction parameter for correcting a non-discharge using a non-discharge correction nozzle, a first test chart including a non-recording region that is the recording position of the non-discharge correction nozzle, a measurement chart region where a measurement chart is formed, and a uniform concentration region is formed for a designated nozzle that is previously designated. Then, the first test chart is read, the reading data is analyzed, the concentration at the measurement chart and the concentration at the uniform concentration region are compared for each non-discharge correction parameter, and a non-discharge correction parameter corresponding to the concentration at the measurement chart that minimizes the concentration difference from the uniform concentration region is derived as the optimum value of the non-discharge correction parameter for the designated nozzle.

Abstract: The present invention relates to an ink jet recording apparatus and method. In an aspect of the present invention, uneven concentration correction and non-ejection correction are performed at the time of drawing an image. In the non-ejection correction, a non-ejecting nozzle and a deflected ejection nozzle are detected as a defective nozzle, the detected defective nozzle is not allowed to eject ink to perform the non-ejection correction. When a deflected ejection nozzle is detected, an allowable value range of a deflected ejection amount of each of nozzles with respect to a deflected ejection amount of each of nozzles at the time of creating an uneven concentration correction parameter is determined. A nozzle in which a deflected ejection amount exceeds the allowable value range so that the deflected ejection occurs is detected as a deflected ejection nozzle.

Abstract: According to the inkjet recording apparatus and the image recording method of the present invention, since the droplet volume of droplets ejected from ejection abnormality nozzles is limited to not greater than a prescribed upper limit value, and the droplet volume of droplets ejected from other normally functioning nozzles is corrected on the basis of correction values used for correction of non-uniformities in the image caused by ejection abnormality nozzles, then in even in cases where the interval between droplets ejected from adjacent nozzles which are adjacent to an ejection abnormality nozzle becomes larger due to landing interference, in particular, it is possible to perform image recording by using droplets ejected from deflecting nozzles. As a result of this, the occurrence of non-uniformities (stripe non-uniformities) in the image can be suppressed.

Abstract: An aspect of a recording defect inspection method for an image recording apparatus includes: a recording step of sequentially recording test patterns of respective recording heads onto a recording medium, an image capturing step of capturing an image of a test pattern recorded on the recording medium by means of a scanner, an analysis step of analyzing the captured test pattern and detecting a recording defect of the recording head which has recorded the test pattern, an evaluation frequency setting step of setting an evaluation frequency for each of the recording heads on the basis of a recording defect occurrence frequency for each recording head, and a control step of setting a frequency of each of the recording heads in the test patterns to the set evaluation frequency.

Abstract: The present invention provides an image recording method and apparatus and a recording medium therefor. In an aspect of the present invention, when recording the image in a condition where an image recording range in a first direction by the image recorder is a specific range, image processing is applied to the image data using a latest image processing parameter among image processing parameters which are according to positions in the first direction and have been generated on the basis of measurement results of test charts output using the specific range or a wider range than the specific range on the image recorder, and the image recorder is caused to record the image on the recording medium according to the image data after the image processing.

Abstract: Unevenness correcting information is generated based on property information indicating a recording property of each of a plurality of recording elements which are included in a recording head, the recording elements being subjected to output correction in a first output correction unit based on unevenness correcting information obtained after a flattening processing and output correction in a second output correction unit, and the unevenness correcting information close to an appropriate value with which an image in an appropriately-corrected state can be obtained can be generated.

Abstract: A method for controlling an image recording apparatus includes: detecting a defective recording element out of a plurality of recording elements on a recording head for recording an image on a recording medium; performing a correction processing including suspension of an output of the defective recording element and increase of an output of a recording element at least adjacent to the defective recording element according to a detection result; determining whether or not an image defect is caused in the image by the suspension of output of the defective recording element, before performing the correction processing, according to the detection result; selecting a forced recording element that is forced to output ink out of defective recording elements when it is determined that the image defect is caused; and suspending the output of the defective recording element other than the forced recording element when the forced recording element is selected.