Airborne Lidar: Advances in Discrete Return Technology for 3D Vegetation Mapping

Ussyshkin, Valerie; Theriault, Livia

doi:10.3390/rs3030416

Cited by 51 publications

(27 citation statements)

References 19 publications

(33 reference statements)

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“…In certain applications such as forestry [40,41] and bathymetry [42] FWD systems have distinct advantages over discrete return systems, although in forestry the discrete data still provides abundant information [43,44]. Other uses such as the mapping of large scale topographic features (faults, landslides) have been successful for decades with discrete return systems even when the terrain features of interest are occluded by dense vegetation [45].…”

Section: Discrete Return Versus Full Waveform Digitizing Systemsmentioning

confidence: 99%

Now You See It… Now You Don’t: Understanding Airborne Mapping LiDAR Collection and Data Product Generation for Archaeological Research in Mesoamerica

et al. 2014

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Abstract:In this paper we provide a description of airborne mapping LiDAR, also known as airborne laser scanning (ALS), technology and its workflow from mission planning to final data product generation, with a specific emphasis on archaeological research. ALS observations are highly customizable, and can be tailored to meet specific research needs. Thus it is important for an archaeologist to fully understand the options available during planning, collection and data product generation before commissioning an ALS survey, to ensure the intended research questions can be answered with the resultant data products. Also this knowledge is of great use for the researcher trying to understand the quality and limitations of existing datasets collected for other purposes. Throughout the paper we use examples from archeological ALS projects to illustrate the key concepts of importance for the archaeology researcher.

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Section: Discrete Return Versus Full Waveform Digitizing Systemsmentioning

confidence: 99%

Now You See It… Now You Don’t: Understanding Airborne Mapping LiDAR Collection and Data Product Generation for Archaeological Research in Mesoamerica

et al. 2014

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“…Otherwise, go to step (6). (6) Give the points in the list a new label, clear the list, and go to step (3).…”

Section: Svm-based Classificationmentioning

confidence: 99%

SVM-Based Classification of Segmented Airborne LiDAR Point Clouds in Urban Areas

2013

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Abstract:Object-based point cloud analysis (OBPA) is useful for information extraction from airborne LiDAR point clouds. An object-based classification method is proposed for classifying the airborne LiDAR point clouds in urban areas herein. In the process of classification, the surface growing algorithm is employed to make clustering of the point clouds without outliers, thirteen features of the geometry, radiometry, topology and echo characteristics are calculated, a support vector machine (SVM) is utilized to classify the segments, and connected component analysis for 3D point clouds is proposed to optimize the original classification results. Three datasets with different point densities and complexities are employed to test our method. Experiments suggest that the proposed method is capable of making a classification of the urban point clouds with the overall classification accuracy larger than 92.34% and the Kappa coefficient larger than 0.8638, and the classification accuracy is promoted with the increasing of the point density, which is meaningful for various types of applications.

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“…In this paper we deal with measurements of an aerial discrete return (DR) Lidar sensor [13], which is able to capture up to four range measurements for a single laser pulse, including 1st, 2nd, 3rd and last returns. We may also obtain four intensity returns of each pulse, which are related to the strength of the backscattered echoes.…”

Section: A Sensing Technologiesmentioning

confidence: 99%

Extraction of Vehicle Groups in Airborne Lidar Point Clouds With Two-Level Point Processes

Börcs

Benedek

2015

IEEE Trans. Geosci. Remote Sensing

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Airborne Lidar: Advances in Discrete Return Technology for 3D Vegetation Mapping

Cited by 51 publications

References 19 publications

Now You See It… Now You Don’t: Understanding Airborne Mapping LiDAR Collection and Data Product Generation for Archaeological Research in Mesoamerica

Now You See It… Now You Don’t: Understanding Airborne Mapping LiDAR Collection and Data Product Generation for Archaeological Research in Mesoamerica

SVM-Based Classification of Segmented Airborne LiDAR Point Clouds in Urban Areas

Extraction of Vehicle Groups in Airborne Lidar Point Clouds With Two-Level Point Processes

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