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Geospatial description of river channels in three dimensionsMerwade, Venkatesh 28 August 2008 (has links)
Not available / text
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The bathymetry, sedimentology and seismic stratigraphy of Lake Sibaya- Northern KwaZulu-Natal.Miller, Warwick Richard. January 1998 (has links)
The morphology of Lake Sibaya is a product of an ancient fluvial system that drained a coastal
landscape dominated by aeolian processes. The sedimentary processes within the lake are driven
by wind generated currents. The dominant sedimentary process is one of lake segmentation,
whereby prograding bedforms isolate the lake into smaller water bodies. The prograding
bedforms include cuspate forelands and sand spits. The size and mobility of these bedforms is a
function of sediment availability and current regime.
The bathymetry of Lake Sibaya is discussed, with emphasis on geomorphic features derived from
the ancient aeolian landscape as well as features related to modern sedimentary processes. The
presence of underwater knickpoints and terraces indicate that lake level fluctuations have been
common in Lake Sibaya. It is during lake highstands that large volumes of sand are eroded from
aeolian dunes which surround the lake and made available for shoreline progradation. Ancient
dune topography is preserved to depths of 20 m below water-level within the lake.
Surface sediment distribution maps were compiled from 515 grab samples and thirteen core
samples. Fine grained, well sorted, coarse skewed quartz sand comprises the majority of the
surface area of the lake floor. Gyttja is the other dominant sediment type and accumulates in
palaeovalleys and depressions on the lake floor. Sediment distribution in Lake Sibaya is discussed
in terms of modern lacustrine processes as well as inherited sedimentary characteristics.
The stratigraphy of the sediments underlying Lake Sibaya was investigated using a Uni-Boom
seismic profiling system. Seismic profiles were compiled by identifying acoustically reflective
surfaces that show regional development. Thirteen seismic overlays were prepared, and are
illustrated as west - east and north - south seismic profiles. Five sequences ranging in age from
late Cretaceous to Holocene were identified from the seismic profiles, and are described in terms
of sequence stratigraphic principles. The seismic sequences were interpreted within a
lithostratigraphic framework and are presented as a series of idealised geological sections.
Thirteen sediment cores were collected from the Lake Sibaya area in order to ascertain the
accuracy of the stratigraphic interpretation of the seismic records, to investigate reflective
horizons identified from seismic records and to collect dateable material. Interpretation of the
sediment cores reveals that a proto Lake Sibaya existed on drowned dune topography, during the
period ± 43500 BP to ± 25500 BP prior to the Last Glacial Maximum. During the early to mid
Holocene the Lake Sibaya site was occupied by a saline lagoon which underwent isolation from
the sea ± 5030 BP. Since the mid-Holocene the lake has evolved to totally freshwater conditions
and has undergone little sedimentation.
The geological evolution of the Lake Sibaya area is discussed in terms of the geometry of the
identified seismic sequences, the sedimentary characteristics of these sequences and the
radiocarbon dates provided from the sediment cores. Palaeo-environmental conditions during the
accumulation of the sedimentary sequences is discussed where fossil remains permit. / Thesis (M.Sc.)-University of Natal, Durban, 1998.
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Avaliação dos interpoladores krigagem e Topo to Raster na geração de Modelos Digitais de Elevação a partir de dados batimétricos / Avaliação dos interpoladores krigagem e Topo to Raster na geração de Modelos Digitais de Elevação a partir de dados batimétricos / Avaliação dos interpoladores krigagem e Topo to Raster na geração de Modelos Digitais de Elevação a partir de dados batimétricos / Avaliação dos interpoladores krigagem e Topo to Raster na geração de Modelos Digitais de Elevação a partir de dados batimétricos / Avaliação dos interpoladores krigagem e Topo to Raster na geração de Modelos Digitais de Elevação a partir de dados batimétricos / Avaliação dos interpoladores krigagem e Topo to Raster na geração de Modelos Digitais de Elevação a partir de dados batimétricosCarmo, Edilson José do 25 November 2014 (has links)
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Previous issue date: 2014-11-25 / With developments in recent years, methods for bathymetric surveys using acoustic sensors (echo sounders) and signals transmitted by satellite navigation receivers, it becomes possible to describe the submerged same level of detail which is embossed with the surface relief describes terrestrial. A graphical representation of the underwater relief occurs from Digital Elevation Models (DEMs) generated by interpolating seeking, from measurements, predict the depth at unsampled locations. The geometrical information taken from bathymetric surveys, the volume of liquid water or mud present, for example in a reservoir, is the most relevant. This study sought to determine the products generated by single beam bathymetric survey, as well as the methods of kriging interpolation and Topo to Raster. The study areas were a box of decanting of the water treatment plant and a dam lake of Furnas, where surveys were conducted, with total station and bathymetric surveys, with a single beam echo sounder which operates at frequencies 33 kHz and 210 kHz . In the settling box, first bathymetric survey was conducted (Lbat 1). Then be emptied and cleaned the box and before filling it again, surveying, (Ltop) was performed with total station. Immediately after filling, without water and mud decanted, another bathymetric survey (Lbat 2) was performed. To survey the dam lake of Furnas, held automated bathymetric survey, ie, using the GNSS technology for positioning. First, the data from the survey, we evaluated the methods of kriging interpolation and Topo to Raster in the DEM generation of the settling box. The conclusion was that the interpolator Top to Raster conditioning showed remarkable deformations at the edges and in the center of the study area and should be discarded. The next stage of this work was to evaluate the accuracy of DEMs generated by applying kriging on data from single beam bathymetric survey, Lbat 2, using the frequencies of 33 kHz and 210 kHz. Possession of DEMs were calculated discrepancies between information from them and points of surveying. The results showed an accuracy of about 5 cm in mean depths of 3.21 m, and that as the surveys were conducted after cleaning the box, with clean water, there was no significant difference in the accuracy of DEMs generated with depths raised to the frequencies 33 kHz and 210 kHz. Then the DEMs were generated by kriging for the first bathymetric survey, Lbat 1, when solid waste resulting from the settling process still existed. Volumes were calculated and compared to evaluate the frequency of 33 kHz echo sounder to determine the volume of mud in the box. After analyzing the results, it was found that using only the first bathymetric survey, with the frequencies 33 kHz and 210 kHz, there was detected 186 m3 of sludge, in a total volume of 799 m3 of water and mud which, with the clean water the volume is determined by accurate bathymetry, showing discrepancy of 0.63% for the frequency of 210 kHz and 0.12% for the frequency of 33 kHz. To survey the lake of Furnas DEMs were generated by kriging interpolation method and the Top to Raster, varying the spacing between the regular survey lines using horizontal scan lines to the regular survey lines. Through statistical analysis of the discrepancies between estimated by interpolating depths and depths observed in the scan lines of the bathymetric survey, the kriging showed better results for spacings of 40 and 80 meters. Considering the isobatimétricas between different DEMs created, it is observed that for larger spacings the interpolator to Top Raster presented smoother features when compared to the DEMs generated by kriging. / Com a evolução, nos últimos anos, dos métodos de levantamentos batimétricos utilizando sensores acústicos (ecobatímetros) e receptores de sinais transmitidos por satélites de navegação, torna-se possível descrever o relevo submerso com mesmo nível de detalhe com que se descreve o relevo da superfície terrestre. A representação gráfica do relevo submerso se dá a partir de Modelos Digitais de Elevação (MDEs) gerados por interpoladores que buscam, a partir das medidas realizadas, predizer a profundidade em locais não amostrados. Das informações geométricas extraídas de levantamentos batimétricos, o volume de água ou lama líquida presente, por exemplo em um reservatório, é a mais relevante. Este trabalho busca avaliar produtos gerados pelo levantamento batimétrico monofeixe, assim como os métodos de interpolação krigagem e Topo to Raster. As áreas de estudo foram uma caixa de decantação de estação de tratamento de água e um lago da represa de furnas, onde foram realizados levantamentos topográficos, com estação total e levantamentos batimétricos, com ecobatímetro monofeixe que opera nas frequências 33 kHz e 210 kHz. Na caixa de decantação, primeiramente foi realizado levantamento batimétrico (Lbat 1). Em seguida, esvaziou-se e limpou-se a caixa e, antes de enchê-la novamente, foi realizado um levantamento topográfico, (Ltop), com estação total. Logo após o enchimento, com água e sem lama decantada, foi realizado outro levantamento batimétrico (Lbat 2). Para o levantamento no lago da represa de furnas, realizou-se levantamento batimétrico automatizado, ou seja, empregando a tecnologia GNSS para o posicionamento. Primeiramente, com os dados do levantamento topográfico, se avaliou os métodos de interpolação krigagem e Topo to Raster na geração do MDE da caixa de decantação. A conclusão foi que o interpolador Topo to Raster condicionado apresentou notáveis deformações nas bordas e no centro da área de estudo, devendo ser descartado. A próxima etapa do trabalho foi avaliar a acurácia dos MDEs gerados aplicando krigagem nos dados do levantamento batimétrico monofeixe, Lbat 2, utilizando as frequências de 33 kHz e 210 kHz. De posse dos MDEs foram calculadas as discrepâncias entre informações extraídas deles e os pontos do levantamento topográfico. Os resultados apresentaram uma acurácia em torno de 5 cm, em profundidades médias de 3,21 m, e que, como os levantamentos foram realizados após a limpeza da caixa, com água limpa, não se verificou diferença significativa na acurácia dos MDEs gerados com as profundidades levantadas com as frequências 33 kHz e 210 kHz. Em seguida foram gerados os MDEs pela krigagem para o primeiro levantamento batimétrico, Lbat 1, quando ainda existiam resíduos sólidos resultantes do processo de decantação. Os volumes foram calculados e comparados a fim de avaliar a frequência de 33 kHz do ecobatímetro para determinar o volume de lama na caixa. Após analisar os resultados verificou-se que usando somente o primeiro levantamento batimétrico, com as frequências 33 kHz e 210 kHz, não se detectou 186 m3 de lama, num volume total de 799 m3 de água e lama, e que, com a água limpa, o volume determinado pela batimetria é acurado, apresentando discrepância de 0,63% para a frequência de 210 khz e 0,12% para a frequência de 33 khz. Para o levantamento do lago de furnas foram gerados MDEs pelo método de krigagem e pelo Topo to Raster, variando o espaçamento entre as linhas regulares de sondagem, utilizando linhas de verificação transversais às linhas regulares de sondagem. Através da análise estatística das discrepâncias entre as profundidades estimadas pelos interpoladores e as profundidades observadas nas linhas de verificação do levantamento batimétrico, a krigagem apresentou melhores resultados para espaçamentos de 20 a 80 metros. A diferença entre os volumes determinados para os espaçamentos de 20 a 40 metros foi menor que 2%,. Considerando as isobatimétricas entre os diversos MDEs criados, observa-se que para espaçamentos maiores o interpolador Topo to Raster apresentou feições mais suavizadas quando comparado com os MDEs gerados pela krigagem.
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