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Registro Completo |
Biblioteca(s): |
Embrapa Florestas; Embrapa Instrumentação. |
Data corrente: |
15/12/2023 |
Data da última atualização: |
19/02/2024 |
Tipo da produção científica: |
Artigo em Periódico Indexado |
Autoria: |
COSTA, B. R. S.; OLDONI, H.; SILVA, T. M. M. da; FARINASSI. L. G.; BOGNOLA, I. A.; BASSOI, L. H. |
Afiliação: |
Universidade Estadual Paulista (Unesp); Universidade Estadual Paulista (Unesp); Universidade Estadual Paulista (Unesp); Universidade Estadual Paulista (Unesp); ITAMAR ANTONIO BOGNOLA, CNPF; LUIS HENRIQUE BASSOI, CNPDIA. |
Título: |
How similar is the zoning of different vegetation indices: Defining the optimal framework for monitoring grapevines’ growth within vigorous vineyards. |
Ano de publicação: |
2023 |
Fonte/Imprenta: |
Scientia Horticulturae, v. 322, 112404, p. 1-17, 2023. |
DOI: |
https://doi.org/10.1016/j.scienta.2023.112404 |
Idioma: |
Inglês |
Conteúdo: |
ABSTRACT The spatial patterns of grapevines’ vigor across vigorous vineyards were assessed through distinct vegetation indices (VI) for comparison purposes. This survey also aids the selection of the most sensitive VI to monitor the vineyards during a given optimal stage of the last period of the growing season. The canopy reflectance (ρ) of grapevines cv. Cabernet Franc and Cabernet Sauvignon (Vitis vinifera L.) was measured throughout their berry development and ripening stages. Georeferenced data of ρ at the red (680 nm), red edge (730 nm), and nearinfrared (780 nm) wavebands were taken using a hand-held active sensor to compute the normalized difference red edge index (NDRE), and the normalized difference vegetation index (NDVI). Spatial predictions of both VI were estimated by geostatistical interpolation technique (kriging) and then categorized into homogeneous zones (HZ) through the Jenks natural breaks optimization method to delimit low and high vigor regions. Statistics of the inter-rater reliability between each VI zoning were calculated afterward. The relative dispersion of data around their mean was assumed as a criterion to assess the sensibility of each VI in detecting vigor variability under a given condition. The most appropriate stage to monitor the vineyards was determined based on the peak of vegetative growth inferred from the values of the VI we presumed as most sensitive. Differences between the HZ defined from the best combination of VI and stage in terms of yield, cane weight, and crop load were also examined. We demonstrated that NDRE was more sensitive than NDVI in detecting the vigor variability of high-density vegetation due to the relative dispersion of its datasets and the saturation effect of NDVI at the late stages of the grapevine growing season. The lowest and higher agreement between the VI zoning was usually detected at the berry touch and berry softening growth stages, respectively. Although there were distinct levels of concordance between NDRE and NDVI maps, their overall agreement was higher than 70% in most surveys. The disagreement in quantity or spatial allocation of vigor categories provided by each VI relied on the vineyard, growth stage, and growing season. Nevertheless, the early definition of HZ from NDRE monitoring carried out at veraison could be suitable to identify differences in cane weight at pruning, with a moderate effect size. MenosABSTRACT The spatial patterns of grapevines’ vigor across vigorous vineyards were assessed through distinct vegetation indices (VI) for comparison purposes. This survey also aids the selection of the most sensitive VI to monitor the vineyards during a given optimal stage of the last period of the growing season. The canopy reflectance (ρ) of grapevines cv. Cabernet Franc and Cabernet Sauvignon (Vitis vinifera L.) was measured throughout their berry development and ripening stages. Georeferenced data of ρ at the red (680 nm), red edge (730 nm), and nearinfrared (780 nm) wavebands were taken using a hand-held active sensor to compute the normalized difference red edge index (NDRE), and the normalized difference vegetation index (NDVI). Spatial predictions of both VI were estimated by geostatistical interpolation technique (kriging) and then categorized into homogeneous zones (HZ) through the Jenks natural breaks optimization method to delimit low and high vigor regions. Statistics of the inter-rater reliability between each VI zoning were calculated afterward. The relative dispersion of data around their mean was assumed as a criterion to assess the sensibility of each VI in detecting vigor variability under a given condition. The most appropriate stage to monitor the vineyards was determined based on the peak of vegetative growth inferred from the values of the VI we presumed as most sensitive. Differences between the HZ defined from the best combination of VI and stage in te... Mostrar Tudo |
Palavras-Chave: |
Grapevine vigor; Map comparison; Mapas; Precision viticulture; Videira; Viticultura de precisão; Vitis vinifera L. |
Categoria do assunto: |
-- K Ciência Florestal e Produtos de Origem Vegetal |
Marc: |
LEADER 03328naa a2200277 a 4500 001 2159824 005 2024-02-19 008 2023 bl uuuu u00u1 u #d 024 7 $ahttps://doi.org/10.1016/j.scienta.2023.112404$2DOI 100 1 $aCOSTA, B. R. S. 245 $aHow similar is the zoning of different vegetation indices$bDefining the optimal framework for monitoring grapevines’ growth within vigorous vineyards.$h[electronic resource] 260 $c2023 520 $aABSTRACT The spatial patterns of grapevines’ vigor across vigorous vineyards were assessed through distinct vegetation indices (VI) for comparison purposes. This survey also aids the selection of the most sensitive VI to monitor the vineyards during a given optimal stage of the last period of the growing season. The canopy reflectance (ρ) of grapevines cv. Cabernet Franc and Cabernet Sauvignon (Vitis vinifera L.) was measured throughout their berry development and ripening stages. Georeferenced data of ρ at the red (680 nm), red edge (730 nm), and nearinfrared (780 nm) wavebands were taken using a hand-held active sensor to compute the normalized difference red edge index (NDRE), and the normalized difference vegetation index (NDVI). Spatial predictions of both VI were estimated by geostatistical interpolation technique (kriging) and then categorized into homogeneous zones (HZ) through the Jenks natural breaks optimization method to delimit low and high vigor regions. Statistics of the inter-rater reliability between each VI zoning were calculated afterward. The relative dispersion of data around their mean was assumed as a criterion to assess the sensibility of each VI in detecting vigor variability under a given condition. The most appropriate stage to monitor the vineyards was determined based on the peak of vegetative growth inferred from the values of the VI we presumed as most sensitive. Differences between the HZ defined from the best combination of VI and stage in terms of yield, cane weight, and crop load were also examined. We demonstrated that NDRE was more sensitive than NDVI in detecting the vigor variability of high-density vegetation due to the relative dispersion of its datasets and the saturation effect of NDVI at the late stages of the grapevine growing season. The lowest and higher agreement between the VI zoning was usually detected at the berry touch and berry softening growth stages, respectively. Although there were distinct levels of concordance between NDRE and NDVI maps, their overall agreement was higher than 70% in most surveys. The disagreement in quantity or spatial allocation of vigor categories provided by each VI relied on the vineyard, growth stage, and growing season. Nevertheless, the early definition of HZ from NDRE monitoring carried out at veraison could be suitable to identify differences in cane weight at pruning, with a moderate effect size. 653 $aGrapevine vigor 653 $aMap comparison 653 $aMapas 653 $aPrecision viticulture 653 $aVideira 653 $aViticultura de precisão 653 $aVitis vinifera L 700 1 $aOLDONI, H. 700 1 $aSILVA, T. M. M. da 700 1 $aFARINASSI. L. G. 700 1 $aBOGNOLA, I. A. 700 1 $aBASSOI, L. H. 773 $tScientia Horticulturae$gv. 322, 112404, p. 1-17, 2023.
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Registro original: |
Embrapa Florestas (CNPF) |
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Registros recuperados : 19 | |
5. | | SILVA, T. W. R. da; SANTOS, A. F. dos; AUER, C. G.; TESSMANN, D. J. Métodos de detecção, transmissão e patogenicidade de Fusarium spp. em sementes de Pinus taeda. Ciência Florestal, Santa Maria, v. 27, n. 1, p. 73-84, jan./mar. 2017.Tipo: Artigo em Periódico Indexado | Circulação/Nível: A - 2 |
Biblioteca(s): Embrapa Florestas. |
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6. | | ÁVILA, S.; SILVA, T. M. F. S. S.; BEUX, M. R.; LAZZAROTTO, M.; RIBANI, R. H. Impacto da pasteurização e desumificação na qualidade de meis de Tetragonisca angustula. In: CONGRESSO BRASILEIRO DE APICULTURA, 22.; CONGRESSO BRASILEIRO DE MELIPONICULTURA, 7., 2018, Joinville. Polinização, tecnologia oportunidades e desafio para o criador de abelha no Brasil: anais. Joinville: CBA, 2018. p. 184.Tipo: Resumo em Anais de Congresso |
Biblioteca(s): Embrapa Florestas. |
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10. | | FERNANDES, E.; SCHUSTER, I.; VIEIRA, E. S. N.; SILVA, T. A. da; SILVA, H. A. da; BALERONI, A. G.; SCAPIM, C. A. Diversidade genética estimada por marcadores microssatélites entre linhagens elite de milho e associação com heterose. In: CONGRESSO BRASILEIRO DE MELHORAMENTO DE PLANTAS, 7., 2013, Uberlândia. Variedade melhorada: a força da nossa agricultura: anais. Viçosa, MG: SBMP, 2013. p. 300-303.Tipo: Artigo em Anais de Congresso |
Biblioteca(s): Embrapa Florestas. |
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11. | | COSTA, A. M.; MOTOIKE, S. Y.; CORRÊA, T. R.; SILVA, T. C.; COSER, S. M.; RESENDE, M. D. V. de; TEÓFILO, R. F. Genetic parameters and selection of macaw palm (Acrocomia aculeata) accessions: an alternative crop for biofuels. Crop Breeding and Applied Biotechnology, v. 18, N. 3, p. 259-266, July/Sept. 2018.Tipo: Artigo em Periódico Indexado | Circulação/Nível: A - 2 |
Biblioteca(s): Embrapa Florestas. |
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13. | | CARMO, J. F. A. do; SÁ, I. I. S.; MOURA, M. S. B. de; HIGA, R. C. V.; WREGE, M. S.; SILVA, T. G. F. da. Potencial climático do Estado de Pernambuco para o plantio de Eucalyptus brassiana S. T. Blake. In: JORNADA DE INICIAÇÃO CIENTÍFICA DA EMBRAPA SEMIÁRIDO, 5., 2010, Petrolina. Anais... Petrolina: Embrapa Semiárido, 2010. p. 33-39. (Embrapa Semiárido. Documentos, 228.).Tipo: Artigo em Anais de Congresso |
Biblioteca(s): Embrapa Florestas. |
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14. | | CUNHA, L.; BARTZ, M.; DEMETRIO, W.; SILVA, T.; JAMES, S.; SILVA, E. da; STANTON, D.; CONRADO, A. C.; DECAENS, T.; LAVELLE, P.; SANTOS, A.; NADOLNY, H.; VELÁSQUEZ, E.; ZANGERLÉ, A.; TAPIA-CORAL, S.; FERREIRA, T.; MAIA, L.; SEGALLA, R.; CLEMENT, C.; MUNIZ, A. W.; KILLE, P.; BROWN, G. G.; TPI NETWORK. Earthworms and Amazonian Dark Earths: improving understanding of the relationships between soil management, biodiversity and function. In: INTERNATIONAL OLIGOCHAETE TAXONOMY MEETING, 7., 2016, Paimpont. Taxonomy, phygeny and ecology of earthworm's communities. [Rennes]: Université de Rennes, [2016]. Não paginado.Tipo: Resumo em Anais de Congresso |
Biblioteca(s): Embrapa Florestas. |
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15. | | CONRADO, A. C.; DEMETRIO, W. C.; STANTON, D. W. G.; BARTZ, M. L. C.; JAMES, S. W.; SANTOS, A.; SILVA, E. da; FERREIRA, T.; ACIOLI, A. N. S.; FERREIRA, A. C.; MAIA, L. S.; SILVA, T. A. C.; LAVELLE, P.; VELASQUEZ, E.; TAPIA-CORAL, S. C.; MUNIZ, A. W.; SEGALLA, R. F.; DECAËNS, T.; NADOLNY, H. S.; PEÑA-VENEGAS, C.; PASINI, A.; OLIVEIRA JUNIOR, R. C. de; TPI NETWORK; KILLE, P.; BROWN, G. G.; CUNHA, L. Amazonian earthworm biodiversity is heavily impacted by ancient and recent human disturbance. Science of the Total Environment, v. 895, art. 165087, 2023.Tipo: Artigo em Periódico Indexado | Circulação/Nível: A - 1 |
Biblioteca(s): Embrapa Amazônia Ocidental; Embrapa Florestas. |
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16. | | SILVA, T. A. C.; CORREA, R. B.; SANTOS, A.; FERREIRA, A.; NALDONY, H.; CUNHA, L. F.; SILVA, E. da; CORAL, S. C. T.; VENEGAS, C. P.; LIMA, A. M. A.; SCHOCK, M.; DECAENS, T.; ACIOLLI, A. N. S.; JAMES, S.; BARTZ, M. L. C.; VELÁSQUEZ. E.; LAVELLE, P. M.; KILLE, P.; CLEMENT, C.; MARTINS, G. C.; MUNIZ, A. W.; PUCCI, P.; BROWN, G. G.; TERRA PRETO DE ÍNDIO NETWORK. População e biomassa de minhocas em Terra Preta de Índio no Amazonas utilizando diferentes metodologias de coleta. In: ENCONTRO LATINO-AMERICANO DE ECOLOGIA E TAXONOMIA DE OLIGOQUETAS, 5; SIMPÓSIO ENGENHEIROS EDÁFICOS, FERTILIDADE DO SOLO E TERRA PRETA DE ÍNDIO (TPI), 2015, Curitiba. Anais. [S.l.]: Federação Brasileira de plantio direto de irrigação, 2015. p. 96. Disponível online. Resumo. 5° ELAETAO.Tipo: Resumo em Anais de Congresso |
Biblioteca(s): Embrapa Florestas. |
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17. | | ABRAHÃO, A. A.; MACHADO, A. M. R.; FRASSONI, A.; SHEILA, B.; CARVALHO, C. H.; MIRANDA, C. A.; OLIVEIRA, D. A. de; ROMERO, F. C.; WERNECK, G.; SOUZA, G. dos S.; COUTO, H. A. R. do; ERVILHA, I. C.; VILLARDI, J. W.; DOBRE, L. G.; AMORIM, M.; NAKASHIMA, M. M.; MATTOS, P. P. de; CONNERTON, P. J.; MELO, P.; CLEMENTE, R. F.; COELHO, S. M. S. da C.; BRAZ, S. N.; CAVENDISH, T.; SILVA, T. H. da; FERREIRA, V. de P.; BARROCAS, P. R. G. Ambiente urbano. In: IBAMA. Relatório de qualidade do meio ambiente: RQMA: Brasil 2020. Brasília, DF, 2022. Cap. 7, p. 424-492. Selo ODS: ODS-1; ODS-3; ODS-4; ODS-6; ODS-8; ODS-9; ODS-11; ODS-12.Tipo: Capítulo em Livro Técnico-Científico |
Biblioteca(s): Embrapa Amazônia Oriental; Embrapa Florestas. |
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18. | | BROWN, G. G.; BARTZ, M.; JAMES, S.; CUNHA, L.; SILVA, E. da; FEIJOO, A.; ROSA, M.; SILVA, T.; STANTON, D.; KILLE, P.; BARETTA, D.; DECAENS, T.; LAVELLE, P.; SANTOS, A.; NADOLNY, H.; FERREIRA, T.; DEMETRIO, W.; CARDOSO, G.; TAHERI, S.; DUPONT, L.; GORTE, T.; BRAGA, L.; TSAI, S.; ZAGATTO, M.; FERREIRA, S.; PASINI, A.; STEFFEN, G.; STEFFEN, R.; ANTONIOLLI, Z.; DRUMOND, M. A.; SILVA, R. da; CARVALHO, M. R.; ESTEVES, E.; CHUBATSU, L.; HERNANDEZ, L.; ROUSSEAU, G.; SANTOS, B.; MARTINS, M.; SCHUHLI, G. S. e. Earthworm taxonomy, biology and ecology. An overview of recent advances (2013-2016) in Brazil. In: INTERNATIONAL OLIGOCHAETE TAXONOMY MEETING, 7., 2016, Paimpont. Taxonomy, phygeny and ecology of earthworm's communities. [Rennes]: Université de Rennes, [2016]. Não paginado.Tipo: Resumo em Anais de Congresso |
Biblioteca(s): Embrapa Florestas. |
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19. | | DEMETRIO, W. C.; CONRADO, A. C.; ACIOLI, A. N. S.; FERREIRA, A. C.; BARTZ, M. L. C.; JAMES, S. W.; SILVA, E. da; MAIA, L. S.; MARTINS, G. C.; MACEDO, R. S.; STANTON, D. W. G.; LAVELLE, P.; VELASQUEZ, E.; ZANGERLÉ, A.; BARBOSA, R.; TAPIA-CORAL, S. C.; MUNIZ, A. W.; SANTOS, A.; FERREIRA, T.; SEGALLA, R. F.; DECAËNS, T.; NADOLNY, H. S.; PEÑA-VENEGAS, C. P.; MAIA, C. M. B. F.; PASINI, A.; MOTA, A. F.; TAUBE JÚNIOR, P. S.; SILVA, T. A. C.; REBELLATO, L.; OLIVEIRA JUNIOR, R. C. de; NEVES, E. G.; LIMA, H. P.; FEITOSA, R. M.; TORRADO, P. V.; McKEY, D.; CLEMENT, C. R.; SHOCK, M. P.; TEIXEIRA, W. G.; MOTTA, A. C. V.; MELO, V. F.; DIECKOW, J.; GARRASTAZU, M. C.; CHUBATSU, L. S.; KILLE, P.; BROWN, G. G.; CUNHA, L. A "dirty" footprint: macroinvertebrate diversity in Amazonian Anthropic soils. Global Change Biology, v. 27, n. 19, p. 4575-4591, Oct. 2021.Tipo: Artigo em Periódico Indexado | Circulação/Nível: A - 1 |
Biblioteca(s): Embrapa Amazônia Ocidental; Embrapa Amazônia Oriental; Embrapa Florestas; Embrapa Solos. |
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Registros recuperados : 19 | |
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Nenhum registro encontrado para a expressão de busca informada. |
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