Multiple Geotechnological Tools Applied to Digital Mapping of Tropical Soils

Alves, Marcelo Rodrigo; Demattê, José Alexandre Melo; Barros, Pedro Paulo

doi:10.1590/01000683rbcs20140410

Cited by 7 publications

(6 citation statements)

References 41 publications

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“…Both soil types consist of mineral material, highly weathered by high temperatures and precipitation, and are typical for tropical regions [30]. The main difference is that the oxisols generally have higher clay content and are uniform in clay content, approximately 380 g/kg in the top one-meter layer, whereas for ultisols, a gradual increase in clay content in deeper soil layers is observed (158 g/kg from 0-0.2 m, 201 g/kg from 0.4-0.6 m and 334 g/kg from 0.8-1 m) [32].…”

Section: Soil Typementioning

confidence: 93%

“…Specifically regarding the dry state of these specific soils types, the oxisols are characterized by the presence of deep, well-drained soils [32]. This leads to the additional assumption that the moisture content in soils that are assumed dry under the criteria reported in Section 2.2.2 is lesser for oxisols (i.e., resulting in lower backscatter) than for ultisols.…”

Section: Soil Typementioning

confidence: 99%

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Vegetation Characterization through the Use of Precipitation-Affected SAR Signals

et al. 2018

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Current space-based SAR offers unique opportunities to classify vegetation types and to monitor vegetation growth due to its frequent acquisitions and its sensitivity to vegetation geometry. However, SAR signals also experience frequent temporal fluctuations caused by precipitation events, complicating the mapping and monitoring of vegetation. In this paper, we show that the influence of a priori known precipitation events on the signals can be used advantageously for the classification of vegetation conditions. For this, we exploit the change in Sentinel-1 backscatter response between consecutive acquisitions under varying wetness conditions, which we show is dependent on the state of vegetation. The performance further improves when a priori information on the soil type is taken into account.

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Section: Soil Typementioning

confidence: 93%

Section: Soil Typementioning

confidence: 99%

Vegetation Characterization through the Use of Precipitation-Affected SAR Signals

et al. 2018

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“…It is as these in recent years, there have witnessed a significant increase in the use of geotechnological tools (remote sensing [RS] and GIS) to study soil erosive processes. The principle objectives of many of these contributions are: (a) the multi-temporal and spatial modeling of erosive processes (Zeng et al, 2013); (b) the analysis of the effects of the changes in vegetal cover and land use (Lech-hab et al, 2015); (c) the quantification of soil loss (Parveen and Kumar, 2012;Farhan et al, 2013;Amsalu and Mengaw, 2014;Lahlaoi et al, 2015;Ganasri and Ramesh, 2016;Tahiri et al, 2016); (d) the zoning of the hazard and risk control (Prasannakumar et al, 2012;Gaatib and Larabi, 2014;Uddin et al, 2014;Chirala et al, 2015); and (e) soil mapping and classification (Alves et al, 2015;Rizzo et al, 2015;Moura-Bueno et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Soil erosion risk zoning in the Ecuadorian coastal region using geo-technological tools

2019

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The activation of erosive processes on the slopes of the drainage catchments in the Ecuadorian coastal region represents a serious environmental problem that results in a loss of soil resources with the consequent reduction in agricultural productivity, an increasing lack of areas with vegetation, and decreased water quality. These issues increase, among other things, the probability of flooding. The purpose of this research is to zone soil erosion risk in the Manabí province, which is located on the Ecuadorian coast. The methodology is supported by the employment of Geographic Information Technologies (GIT) in order to access and process information of interest, such as: precipitation data with which to calculate the R Factor of the Universal Soil Loss Equation (USLE); topography, which was employed to create a slope map from the Digital Elevation Model (DEM) ASTER; vegetation cover, by applying the Standard Difference Vegetation Index (NDVI); land use, through the interpretation of orthophotos and a field survey; and infiltration capacity, obtained by considering the texture of the soil. The factors were combined by means a weighted relationship (map algebra) and exploiting the potential of software for the design of Geographic Information Systems (GIS). The results indicate the presence of soils with little or without vegetal protection, in areas with steep slopes, moderate rainfall and extensive farming activities. These characteristics determine conditions of high soil erodability, and propitiate the triggering of erosive processes. This scenario shows the need for autonomous governments to implement policies, strategies and actions so as to promote the strengthening of institutional and community capacities that will promote environmental sustainability.

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“…No entanto, essa abordagem exige a existência de mapas legados para calibração dos modelos de predição, sendo inviável para regiões onde não há disponibilidade dessas informações. Uma alternativa para a ausência de mapas legados é a predição da ocorrência dos solos a partir de informações coletadas em perfis de solos georreferenciados (Hengl et al, 2007;Alves et al, 2015;Arruda et al, 2016). Dessa forma, pode-se realizar o mapeamento de áreas que já foram amostradas, além da confecção de bancos de dados estruturados e a extrapolação para áreas fisiograficamente semelhantes.…”

Section: Introductionunclassified

Índice de área foliar residual como estratégia para manejo de pasto: estrutura do capim Tanzânia

Lemos

Ruggieri

Silva

et al. 2019

Agraria

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AGRONOMIA (AGRONOMY) RESUMO: Os estudos de mapeamento digital de classes de solos (MDS) têm utilizado mapas legados como principal fonte de informação para calibração dos modelos preditores. Entretanto, são necessárias novas abordagem com técnicas que permitam o uso de informações contidas em perfis de solos georreferenciados, permitindo a aplicação do MDS em áreas amostradas que não disponibilizem de mapas convencionais de solos. O objetivo deste estudo foi avaliar o desempenho na predição de ocorrência de solos de amostras coletadas em pixels de perfis de solos georreferenciados e em pixels coletados em buffers com raio de 50, 100, 150, 200 e 250 m dos perfis de solos nas bacias dos rios Lajeado Grande e Santo Cristo. As duas áreas possuem dados de levantamento de solos publicados em escala 1:50.000. Para predição da ocorrência das classes de solos foram utilizadas dez variáveis preditoras geradas a partir de um modelo digital de elevação com resolução espacial de 30 m. Para a predição foi utilizado o algoritmo Random Forest. Os mapas preditos foram avaliados quanto à exatidão em relação aos perfis de solos e quanto a reprodutibilidade dos mapas convencionais. A utilização dos pixels amostrais coletados nos buffers não alterou de forma expressiva a acurácia geral dos mapas preditos na bacia do rio Lajeado Grande, mas permitiu um ganho de 15,6% de exatidão na bacia do rio Santo Cristo. O uso apenas dos perfis georreferenciados resultou em mapas preditos com exatidão superior a 75% e concordância de reprodutibilidade igual ou superior a 67% em relação ao mapa convencional.

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Multiple Geotechnological Tools Applied to Digital Mapping of Tropical Soils

Cited by 7 publications

References 41 publications

Vegetation Characterization through the Use of Precipitation-Affected SAR Signals

Vegetation Characterization through the Use of Precipitation-Affected SAR Signals

Soil erosion risk zoning in the Ecuadorian coastal region using geo-technological tools

Índice de área foliar residual como estratégia para manejo de pasto: estrutura do capim Tanzânia

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