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dc.contributor.authorShajahan, Sunoj
dc.description.abstractDigital image processing is one of the potential technologies used in precision agriculture to gather information, such as seed emergence, plant health, and phenology from the digital images. Despite its potential, the rate of adoption is slow due to limited accessibility, unsuitability to specific issues, unaffordability, and high technical knowledge requirement from the clientele. Therefore, the development of open source image processing applications that are task-specific, easy-to-use, requiring fewer inputs, and rich with features will be beneficial to the users/farmers for adoption. The Fiji software, an open source free image processing ImageJ platform, was used in this application development study. A collection of four different agricultural field applications were selected to address the existing issues and develop image processing tools by applying novel approaches and simple mathematical principles. First, an automated application, using a digital image and “pixel-march” method, performed multiple radial measurements of sunflower floral components. At least 32 measurements for ray florets and eight for the disc were required statistically for accurate dimensions. Second, the color calibration of digital images addressed the light intensity variations of images using standard calibration chart and derived color calibration matrix from selected color patches. Calibration using just three-color patches: red, green, and blue was sufficient to obtain images of uniform intensity. Third, plant stand count and their spatial distribution from UAS images were determined with an accuracy of ≈96 %, through pixel-profile identification method and plant cluster segmentation. Fourth, the soybean phenological stages from the PhenoCam time-lapse imagery were analyzed and they matched with the manual visual observation. The green leaf index produced the minimum variations from its smoothed curve. The time of image capture and PhenoCam distances had significant effects on the vegetation indices analyzed. A simplified approach using kymograph was developed, which was quick and efficient for phenological observations. Based on the study, these tools can be equally applied to other scenarios, or new user-coded, user-friendly, image processing tools can be developed to address specific requirements. In conclusion, these successful results demonstrated the suitability and possibility of task-specific, open source, digital image processing tools development for agricultural field applications.en_US
dc.publisherNorth Dakota State Universityen_US
dc.rightsNDSU policy 190.6.2
dc.titleAgricultural Field Applications of Digital Image Processing Using an Open Source ImageJ Platformen_US
dc.typeDissertationen_US
dc.typeVideoen_US
dc.date.accessioned2019-05-01T16:00:51Z
dc.date.available2019-05-01T16:00:51Z
dc.date.issued2019en_US
dc.identifier.urihttps://hdl.handle.net/10365/29711
dc.subjectalgorithmen_US
dc.subjectImageJen_US
dc.subjectimage processingen_US
dc.subjectPhenoCamen_US
dc.subjectprecision agricultureen_US
dc.subjectunmanned aerial systemen_US
dc.description.sponsorshipUnited States. Agricultural Research Serviceen_US
dc.description.sponsorshipNational Institute of Food and Agriculture (U.S.)en_US
dc.rights.urihttps://www.ndsu.edu/fileadmin/policy/190.pdf
ndsu.degreeDoctor of Philosophy (PhD)en_US
ndsu.collegeGraduate and Interdisciplinary Studies
ndsu.departmentAgricultural and Biosystems Engineeringen_US
ndsu.programAgricultural and Biosystems Engineeringen_US
ndsu.advisorCannayen, Igathinathane


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