Your search keyword '"Amy L. Neuenschwander"' showing total 2 results

1. Automated bare earth extraction technique for complex topography in light detection and ranging surveys

Author

Terry H. Stevenson, Lori A. Magruder, Amy L. Neuenschwander, and Brian Bradford

Subjects

Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Image processing, Ranging, Terrain, Image segmentation, Curvature, GeneralLiterature_MISCELLANEOUS, Data modeling, Data set, Lidar, General Earth and Planetary Sciences, ComputingMethodologies_COMPUTERGRAPHICS, Remote sensing

Abstract

Bare earth extraction is an important component to light detection and ranging (LiDAR) data analysis in terms of terrain classification. The challenge in providing accurate digital surface models is augmented when there is diverse topography within the data set or complex combinations of vegetation and built structures. Few existing algorithms can handle substantial terrain diversity without significant editing or user interaction. This effort presents a newly developed methodology that provides a flexible, adaptable tool capable of integrating multiple LiDAR data attributes for an accurate terrain assessment. The terrain extraction and segmentation (TEXAS) approach uses a third-order spatial derivative for each point in the digital surface model to determine the curvature of the terrain rather than rely solely on the slope. The utilization of the curvature has shown to successfully preserve ground points in areas of steep terrain as they typically exhibit low curvature. Within the framework of TEXAS, the contiguous sets of points with low curvatures are grouped into regions using an edge-based segmentation method. The process does not require any user inputs and is completely data driven. This technique was tested on a variety of existing LiDAR surveys, each with varying levels of topographic complexity.

Published

2013

2. Lidar waveform stacking techniques for faint ground return extraction

Author

Amy L. Neuenschwander, Lori A. Magruder, and Scott P. Marmillion

Subjects

Signal processing, Data processing, Data acquisition, Lidar, Computer science, Attenuation, Feature extraction, General Earth and Planetary Sciences, Waveform, Energy (signal processing), Remote sensing

Abstract

Innovative algorithm development for small-footprint full-waveform lidar data processing extends this technology's capabilities to more complicated acquisition scenarios then previously determined, namely success of surveys over obscured areas. Waveform decomposition and the extraction of waveform metrics provide a straightforward approach to identifying vertical structure within each laser measurement. However, there are some limitations in this approach as faint returns within the waveform go undetected within the classical processing chain. These faint returns are the result of reduced energy levels due to obscurant scattering, attenuation and absorption. Lidar surveys over non-homogeneous wooded regions indicate that there are meaningful ground returns within dense tree coverage if extracted correctly from the data. By using a waveform stacking technique with appropriate waveforms in near geospatial proximity to the original, these faint returns can be augmented and detected during data processing. In comparison to the traditional approach, the waveform stacking technique provides up to a 60% increase in perceived ground returns with the faint signal extraction for the particular datasets analyzed over a broadleaf forest in Mississippi. The enhanced capability in the presence of foliage provides a decrease in operational effort associated with data density, dwell or targeting techniques, in addition to required survey expense.

Published

2010