Development Of Digital Elevation Model Research Articles

Development of digital elevation model for assessment of flood vulnerable areas using Cartosat‐1 and GIS at Thamirabarani river, Tamilnadu, India

AbstractIn recent years, a considerable occurrence of floods at global level impacts the occupation and various segments of the economy. Flood vulnerability is the key paradigm in flood menace management. Assessment of flood vulnerability is essential to investigate the hypothetical onsets of vulnerability. Recent flood inundation in Thamirabarani river basin in Tirunelveli district, Tamil Nadu has caused devastating impacts to the lives around the river basin area. The proposed study integrated remote sensing and GIS techniques to produce flood map of flood inundation area in the nearby Thamirabarani river basin using Cartosat‐1 Satellite based Digital Elevation Model (DEM) derived by means of Leica Photogrammetry Suite to identify flood prone areas. A flow model was designed with the aid of DEM. The DEM classified the flood prone zones into high risk, medium risk and low risk zones using equal interval of classification based on elevation (buffer distance) from the river basin. Based on the nature and extent of flood, the remedial measures were classified as short‐ term, medium‐term and long‐ term measures. The proposed study has recommended some flood mitigation remedial measures to the district administration of Tirunelveli for managing the flood disaster caused during the monsoon rainfall.

Development of digital elevation models for shallow-water zones and coastal areas of Lake Baikal, the Irkutsk reservoir and the downstream pool of Irkutsk HPP

Development of digital elevation models for shallow-water zones and coastal areas of Lake Baikal, the Irkutsk reservoir and the downstream pool of Irkutsk HPP

Согласование цифровых моделей рельефа и гидрографической сети для определения границ бассейнов

The development of digital elevation models (DEM) and methods of its analysis expanded its application in various geographical researches, and for hydrological modeling in particular. In this paper we present a procedure of harmonizing DEM and hydrographic network for automated basin delineation at a small scale. It is shown that the harmonization procedure is a necessary step of hydrological modeling, the requirements to the harmonization procedure are defined, as well as minimum data set needed for reliable harmonization. This data set includes

Development of digital elevation model for Okomu National Park, Nigeria

Development of digital elevation model for Okomu National Park, Nigeria

Deformaciones neotectónicas en el relieve fluvial de la Llanura Sur de Pinar del Río, Cuba

Research findings in neotectonics (the most recent movements of the earth's crust) are fundamental to the analysis of modern landforms. In the 1970s, a significant number of structural and geological investigations were carried out in Cuba, all complemented by geophysical data and perforations, Allowing the first division in morphostructural blocks of different hierarchical orders: megabloque, macroblock, mesobloque and smaller blocks. The southern plain of Pinar del Río is located in the mesobloque Batabanó, bordered by the mesobloques Pinar and Habana-Matanzas, and controlled by the Southern Cuban fault system. In the southern plain of Pinar del Río, recent vertical velocities of the order of +2.0 to +4.0 mm / year are reported, according to the geodetic investigations of successive leveling made by others authors in 1989, which influence the conformation of the current relief. The existence of different local morphostructures, anomalies in the drainage network and a coast with submersion characteristics, which condition its marshy nature, are elements that point to the existence of these movements. In general, the main methods used to recognize neotectonic deformations have been instrumental (seismological and geodetic), historical-archeological and geological-geomorphological investigations. In Cuba, sedimentary-structural criteria have been applied to differentiate the tectonic styles of the pliocene-quaternary deposits with respect to the folded substrate. Simultaneously, these hypotheses were corroborated by geophysical criteria and deep drilling data. The development of digital elevation models allows the quantitative characterization of the relief and to recognize the tectonic effect in its evolution, especially in very active tectonic zones. As an essential support for the neotectonic investigations of the Cuban archipelago, quantitative geomorphological investigations and teledección techniques were also included. In these works, morphothectonic methods were applied in a very limited way, since there were no numerical models of the terrain that facilitated their use. In the case of Cuba, the criteria for placing the neotectonics stage in geologic time vary greatly. While some authors identify its inception at the end of the Paleogene, others place it between the late Eocene and the Miocene. From the geomorphological perspective, the neotectonics stage is divided into two sub-stages: early neotectonics (Oligocene-Miocene) and late neotectonics (late Miocene to Pleistocene). In relatively flat regions, such as the southern plains of the Pinar del Río Province, in western Cuba, evidence of neotectonic deformation is not always easily identifiable, especially when attributed to recent geological history. A compounded approach is therefore necessary. During the last prospecting works for sand and gravel deposits, certain regularities were established in the distribution of alluvial sediments, the former riverbeds and the diversion of major rivers. All these elements led to the development of new lines of research, of which this work partakes, and which aim at defining active tectonic processes, especially during the Pliocene-Quaternary. These processes are evident in present landforms and the existing drainage system, as well as in their influence on the morphological evolution of the Pinar del Rio southern plains. From a methodological point of view, the efficiency of combining geological, geomorphological and pedological methods in the study of the neotectonics of relatively flat areas was demonstrated. These methods included the morphometric evaluation of landforms, the analysis of drainage anomalies, the study of the spatial distribution of stratigraphic complexes and alluvial deposits, and the spectrometry of the potassium channel there in. Within the perimeter of the southern plains, a total of 15 river basins were identified and delimited. Those basins directly connected to the southern coast were singled out for morphometric evaluation, and in some cases, divided for closer study. In order to identify recent neotectonic activity, morphometric indices were used. Longitudinal blocks of the horst-and-graben type were highlighted in confirmation of the results obtained by geophysical and drilling tests, and three overlapped blocks from west to east were also identified with different amplitudes of vertical displacement of the order of 6 to 10 m. Located at the center and towards the east, blocks II and III are subjected to a sustained tectonic tilting, which has resulted in a progressive migration of the river network in a southwesterly direction, as evidenced by the asymmetry of watersheds. Finally, among the rivers in the axial part of the plain a clockwise deflection pattern was established, probably associated with shearing neotectonic movements along the dislocation at the southern end of the Los Palacios depression.

Application of Structure‐from‐Motion photogrammetry to river restoration

AbstractStructure‐from‐Motion (SfM) photogrammetry is now used widely to study a range of earth surface processes and landforms, and is fast becoming a core tool in fluvial geomorphology. SfM photogrammetry allows extraction of topographic information and orthophotos from aerial imagery. However, one field where it is not yet widely used is that of river restoration. The characterisation of physical habitat conditions pre‐ and post‐restoration is critical for assessing project success, and SfM can be used easily and effectively for this purpose. In this paper we outline a workflow model for the application of SfM photogrammetry to collect topographic data, develop surface models and assess geomorphic change resulting from river restoration actions. We illustrate the application of the model to a river restoration project in the NW of England, to show how SfM techniques have been used to assess whether the project is achieving its geomorphic objectives. We outline the details of each stage of the workflow, which extend from preliminary decision‐making related to the establishment of a ground control network, through fish‐eye lens camera testing and calibration, to final image analysis for the creation of facies maps, the extraction of point clouds, and the development of digital elevation models (DEMs) and channel roughness maps. The workflow enabled us to confidently identify geomorphic changes occurring in the river channel over time, as well as assess spatial variation in erosion and aggradation. Critical to the assessment of change was the high number of ground control points and the application of a minimum level of detection threshold used to assess uncertainties in the topographic models. We suggest that these two things are especially important for river restoration applications. Copyright © 2016 John Wiley & Sons, Ltd.

Laser Scanning in Engineering Surveying: Methods of Measurement and Modeling of Structures

Abstract The study is devoted to the uses of laser scanning in the field of engineering surveying. It is currently one of the main trends of research which is developed at the Department of Engineering Surveying and Civil Engineering at the Faculty of Mining Surveying and Environmental Engineering of AGH University of Science and Technology in Krakow. They mainly relate to the issues associated with tower and shell structures, infrastructure of rail routes, or development of digital elevation models for a wide range of applications. These issues often require the use of a variety of scanning techniques (stationary, mobile), but the differences also regard the planning of measurement stations and methods of merging point clouds. Significant differences appear during the analysis of point clouds, especially when modeling objects. Analysis of the selected parameters is already possible basing on ad hoc measurements carried out on a point cloud. However, only the construction of three-dimensional models provides complete information about the shape of structures, allows to perform the analysis in any place and reduces the amount of the stored data. Some structures can be modeled in the form of simple axes, sections, or solids, for others it becomes necessary to create sophisticated models of surfaces, depicting local deformations. The examples selected for the study allow to assess the scope of measurement and office work for a variety of uses related to the issue set forth in the title of this study. Additionally, the latest, forward-looking technology was presented - laser scanning performed from Unmanned Aerial Vehicles (drones). Currently, it is basically in the prototype phase, but it might be expected to make a significant progress in numerous applications in the field of engineering surveying.

Orthorectification and Digital Elevation Model (DEM) Generation Using Cartosat-1 Satellite Stereo Pair in Himalayan Terrain

High resolution data have high relief displacement in hilly terrains. Development of Digital Elevation model helps to assess bio resources more accurately in such terrains. While estimating bio resources in the Himalayan hilly terrain using multispectral LISS-III data of 23 m spatial resolution, the need for orthorectifcation of satellite data was necessary to correct for spatial distances due to high undulating slopes. Therefore, Cartosat stereo pair based Digital Elevation Model (DEM) was generated using the Rational Polynomial Coefficients (RPC) supplied along with the data products. By using the DEM orthorectification of LISS-III was created. In order to evaluate the positional accuracy of ortho rectified LISS-III Ground control points were selected using the Global Positioning System in differential GPS mode. As there is variation in the spatial distances and height over few points, the GCP corrected DEM was used for ortho rectifcation of Cartosat PAN and LISS-III data. This paper presents the procedure followed for ortho rectification and digital elevation model generation using Cartosat stereo pair data. The result of the study indicated high spatial resolution stereo images helped generation of three dimensional mountainous regions more accurately which helps in estimating the bio resources using multispectral LISS III data.

Assessment of forest structure with airborne LiDAR and the effects of platform altitude

Airborne scanning LiDAR is a spatial technology increasingly used for forestry and environmental applications. However, the accuracy and coverage of LiDAR observations is highly dependent on both the extrinsic specifications of the LiDAR survey as well as the intrinsic effects such as the underlying forest structure. Extrinsic parameters which are set as part of the LiDAR survey include platform altitude, scan angle (half max. angle off nadir), and beam cross sectional diameter at the reflecting surface (referred to as footprint size). In this paper we investigate the effect of a number of these extrinsic parameters, including three different platform altitudes (1000, 2000, and 3000 m), two scan angles at 1000 m (10° and 15° half max. angle off nadir), and three footprint sizes (0.2, 0.4, and 0.6 m). The comparison was undertaken in eucalypt forests at three sites, varying in vegetation structure and topography within the Wedding Bells State Forest, Coffs Harbour, Australia. Results at the plot scale (40 × 90 m areas) indicate that tree heights computed from the 1000 m LiDAR data set (10° half max. angle off nadir) are well correlated with maximum plot heights (difference < 3 m) and field measured canopy volume ( r 2 > 0.75, p < 0.001). Using normalised canopy height profiles (CHP) derived for sites, from data recorded at each altitude, we observed no significant difference between the relative distribution of LiDAR returns, indicating that platform altitude and footprint size have not had a major influence on CHP estimation. Interestingly, comparisons of first and last returns for individual pulses at increasing altitudes identified progressively fewer discrete first/last pulse combinations with more than 70% of pulses recorded as a single return at the highest altitude (3000 m). A possible hypothesis is that greater platform altitude and footprint size reduces the intensity of laser beam incident on a given surface area thus decreasing the probability of recording a last return above the noise threshold. Furthermore, tree scale analysis found a positive relationship between platform altitude and the underestimation of crown area and crown volume. The implications of this work for forest management are: (i) platform altitudes as high as 3000 m can be used to quantify the vertical distribution of phyto-elements, (ii) higher platform altitudes record a lower proportion of first/last return combinations that will further reduce the number of points available for forest structural assessment and development of digital elevation models, and (iii) for discrete LiDAR data, increasing platform altitude will record a lower frequency of returns per crown, resulting in larger underestimates of individual tree crown area and volume if standard algorithms are applied.

A desktop image processing and photogrammetric method for rapid volcanic hazard mapping: application to air-photo interpretation of Mount Pelée, Martinique

A desktop image processing and photogrammetric method was developed for digitizing black-and-white aerial photographs. The technique was applied to airborne optical images of Mt. Pelee, Martinique, a historically active volcano in the tropical Lesser Antilles island arc, to evaluate its utility for rapid geologic mapping and hazard assessment in vegetated areas. The digital approach provides several advantages over traditional air-photo interpretation by allowing for change detection in time-series images, morphologic characterization, development of digital elevation models from stereopairs, and geo-referencing with other digital data sets. A digital mosaic of Mt. Pelee was created from air photos acquired in 1951, which covered the region affected by the 1902 eruption. Severe mismatches occurred along edges of adjacent photographs prior to correction, which precluded quantitative morphologic analysis of the volcanic edifice. Geometric corrections and histogram equalization of digitized air photos allowed creation of a continuous mosaic. Comparison of the mosaic and a map based on differences in gray scale and texture to a volcanostratigraphic map revealed that not only the various deposits produced during the 1902 event were easily differentiated, but that older eruptive products were identified, suggesting that this approach may be used for rapid hazard evaluation of historically active tropical volcanoes.