Отрывок: The training algorithm varies these parameters trying to min- imize the cost function [27]       1ω ω ω 1 ,2LR T Tl l l ll x UJ ln exp y x x c     where yl (x) equals 1 if  (x) = l and (-1) otherwise. We used Broyden–Fletcher–Goldfarb–Shanno algorithm to solve this nonlinear optimization problem [28]. The final multinomial decision rule was based on the softmax function:     ...
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dc.contributor.authorGaidel, A.V.-
dc.contributor.authorPodlipnov, V.V.-
dc.contributor.authorIvliev, N.A.-
dc.contributor.authorParinger, R.A.-
dc.contributor.authorIshkin, P.A.-
dc.contributor.authorMashkov, S.V.-
dc.contributor.authorSkidanov, R.V.-
dc.date.accessioned2023-04-26 14:44:55-
dc.date.available2023-04-26 14:44:55-
dc.date.issued2023-06-
dc.identifierDspace\SGAU\20230424\103218ru
dc.identifier.citationGaidel, A.V. Agricultural plant hyperspectral imaging dataset / A.V. Gaidel, V.V. Podlipnov, N.A. Ivliev, R.A. Paringer, P.A. Ishkin, S.V. Mashkov, R.V. Skidanov // Computer Optics. - 2023. - Vol. 47(3). - P. 442-450. - DOI: 10.18287/2412-6179-CO-1226.ru
dc.identifier.urihttps://dx.doi.org/10.18287/2412-6179-CO-1226-
dc.identifier.urihttp://repo.ssau.ru/handle/Zhurnal-Komputernaya-optika/Agricultural-plant-hyperspectral-imaging-dataset-103218-
dc.description.abstractDetailed automated analysis of crop images is critical to the development of smart agriculture and can significantly improve the quantity and quality of agricultural products. A hyperspectral camera potentially allows to extract more information about the observed object than a conventional one, so its use can help in solving problems that are difficult to solve with conventional methods. Often, predictive models that solve such problems require a large dataset for training. However, sufficiently large datasets of hyperspectral images of agricultural plants are not currently publicly available. Therefore, we present a new dataset of hyperspectral images of plants in this paper. This dataset can be accessed via URL https://pypi.org/project/HSI-Dataset-API/. It contains 385 hyperspectral images with a spatial resolution of 512 by 512 pixels and spectral resolution of 237 spectral bands. The images were captured in the summer of 2021 in Samara and Novocherkassk (Russia) using Offner based Imaging Hyperspectrometer of our own production. The article demonstrates the work of some basic approaches to the analysis of hyperspectral images using the dataset and states problems for further solving.ru
dc.description.sponsorshipThis work was supported by the Ministry of Science and Higher Education of the Russian Federation under Grant 00600/2020/51896 agreement number 075-15-2022-319.ru
dc.language.isoenru
dc.publisherСамарский национальный исследовательский университетru
dc.relation.ispartofseries47;3-
dc.subjecthyperspectral imagingru
dc.subjectimage datasetru
dc.subjectimage processingru
dc.subjectimage segmentationru
dc.subjectsmart agricultureru
dc.titleAgricultural plant hyperspectral imaging datasetru
dc.typeArticleru
dc.textpartThe training algorithm varies these parameters trying to min- imize the cost function [27]       1ω ω ω 1 ,2LR T Tl l l ll x UJ ln exp y x x c     where yl (x) equals 1 if  (x) = l and (-1) otherwise. We used Broyden–Fletcher–Goldfarb–Shanno algorithm to solve this nonlinear optimization problem [28]. The final multinomial decision rule was based on the softmax function:     ...-
dc.classindex.scsti28.23.15-
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