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Registro Completo |
Biblioteca(s): |
Embrapa Agricultura Digital. |
Data corrente: |
06/03/2007 |
Data da última atualização: |
17/01/2020 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Autoria: |
CAMARGO NETO, J.; MEYER, G. E.; JONES, D. D. |
Afiliação: |
JOAO CAMARGO NETO, CNPTIA; GEORGE E. MEYER, Biological Systems Engineering/University of Nebraska; DAVID D. JONES, Biological Systems Engineering/University of Nebraska. |
Título: |
Individual leaf extractions from young canopy image using Gustafson-Kessel clustering and a genetic algorithm. |
Ano de publicação: |
2006 |
Fonte/Imprenta: |
Computers and Electronics in Agriculture, v. 51, p. 66-85, 2006. |
DOI: |
10.1016/j.compag.2005.11.002 |
Idioma: |
Inglês |
Conteúdo: |
The extraction of individual concealed leaves from images of complex plant canopies is a necessary step for taxonomic feature acquisition, species identification, and mapping using a modern personal computer. A new system for individual leaflet extraction was developed and tested, based on connected components, fuzzy clustering and a genetic optimization algorithm. Color images were taken of young, but sparse green canopies, grown in both greenhouse and field conditions. Some images contained individual leaves as connected components, which were readily apparent after separation of the vegetation from its background. Fragments of all other leaves imbedded in the canopy were obtained using the Gustafson?Kessel (GK) clustering algorithm. Each leaf fragment was labeled and placed in a variable length data structure called a chromosome, which represented selected leaf fragments and its neighbors. A genetic algorithm was then used to systematically reassemble the fragments of non-occluded, individual leaves. System performance was evaluated by comparing the number of individual leaves extracted by the computer per plant or plant canopy connected component for various soil/residue backgrounds and time after emergence. 83.5% of the plants in the second week produced at least one computer-extracted leaf for identification. Ninty-two percent of the plants had at least one computer extracted leaf by the third week. 84.7% had more than three computer extracted leaves for identification in the third week. Images of young field plants in multiple species clusters resulted in a 46% leaf extraction rate, but with at least one leaf per connected canopy component. Soybean and velvetleaf leaflets were the easiest to extract. Once individual leaves are extracted, they can be classified using traditional shape and textural feature methods. Computerized individual leaf extraction could assist plant identification and mapping, needed for weed control and crop management. MenosThe extraction of individual concealed leaves from images of complex plant canopies is a necessary step for taxonomic feature acquisition, species identification, and mapping using a modern personal computer. A new system for individual leaflet extraction was developed and tested, based on connected components, fuzzy clustering and a genetic optimization algorithm. Color images were taken of young, but sparse green canopies, grown in both greenhouse and field conditions. Some images contained individual leaves as connected components, which were readily apparent after separation of the vegetation from its background. Fragments of all other leaves imbedded in the canopy were obtained using the Gustafson?Kessel (GK) clustering algorithm. Each leaf fragment was labeled and placed in a variable length data structure called a chromosome, which represented selected leaf fragments and its neighbors. A genetic algorithm was then used to systematically reassemble the fragments of non-occluded, individual leaves. System performance was evaluated by comparing the number of individual leaves extracted by the computer per plant or plant canopy connected component for various soil/residue backgrounds and time after emergence. 83.5% of the plants in the second week produced at least one computer-extracted leaf for identification. Ninty-two percent of the plants had at least one computer extracted leaf by the third week. 84.7% had more than three computer extracted leaves for identification... Mostrar Tudo |
Palavras-Chave: |
Algoritmo genético; Fuzzy clustering; Genetic algorithm; Leaf extraction; Machine vision; Visão computacional. |
Thesaurus Nal: |
Computer vision. |
Categoria do assunto: |
X Pesquisa, Tecnologia e Engenharia |
Marc: |
LEADER 02750naa a2200241 a 4500 001 1001350 005 2020-01-17 008 2006 bl uuuu u00u1 u #d 024 7 $a10.1016/j.compag.2005.11.002$2DOI 100 1 $aCAMARGO NETO, J. 245 $aIndividual leaf extractions from young canopy image using Gustafson-Kessel clustering and a genetic algorithm.$h[electronic resource] 260 $c2006 520 $aThe extraction of individual concealed leaves from images of complex plant canopies is a necessary step for taxonomic feature acquisition, species identification, and mapping using a modern personal computer. A new system for individual leaflet extraction was developed and tested, based on connected components, fuzzy clustering and a genetic optimization algorithm. Color images were taken of young, but sparse green canopies, grown in both greenhouse and field conditions. Some images contained individual leaves as connected components, which were readily apparent after separation of the vegetation from its background. Fragments of all other leaves imbedded in the canopy were obtained using the Gustafson?Kessel (GK) clustering algorithm. Each leaf fragment was labeled and placed in a variable length data structure called a chromosome, which represented selected leaf fragments and its neighbors. A genetic algorithm was then used to systematically reassemble the fragments of non-occluded, individual leaves. System performance was evaluated by comparing the number of individual leaves extracted by the computer per plant or plant canopy connected component for various soil/residue backgrounds and time after emergence. 83.5% of the plants in the second week produced at least one computer-extracted leaf for identification. Ninty-two percent of the plants had at least one computer extracted leaf by the third week. 84.7% had more than three computer extracted leaves for identification in the third week. Images of young field plants in multiple species clusters resulted in a 46% leaf extraction rate, but with at least one leaf per connected canopy component. Soybean and velvetleaf leaflets were the easiest to extract. Once individual leaves are extracted, they can be classified using traditional shape and textural feature methods. Computerized individual leaf extraction could assist plant identification and mapping, needed for weed control and crop management. 650 $aComputer vision 653 $aAlgoritmo genético 653 $aFuzzy clustering 653 $aGenetic algorithm 653 $aLeaf extraction 653 $aMachine vision 653 $aVisão computacional 700 1 $aMEYER, G. E. 700 1 $aJONES, D. D. 773 $tComputers and Electronics in Agriculture$gv. 51, p. 66-85, 2006.
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Embrapa Agricultura Digital (CNPTIA) |
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1. | | MINE, R. de O.; RAMOS FILHO, L. O.; MESQUITA, S.; SILVA, I. D. S.; QUEIROGA, J. L. de. Agroecologia na economia urbana: a experiência de feiras livres dos agricultores do Assentamento Sepé Tiaraju, Serra Azul - SP. In: SIMPÓSIO SOBRE REFORMA AGRÁRIA E QUESTÕES RURAIS. Terra, trabalho e lutas no século XXI: projetos em disputa, 2018, Araraquara: anais... Araraquara: UNIARA, 2018. 10 p.Tipo: Artigo em Anais de Congresso |
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