论文信息 - Integration of intensity information and echo distribution in the filtering process of LIDAR data in vegetated areas

Integration of intensity information and echo distribution in the filtering process of LIDAR data in vegetated areas

Accurate digital terrain models (DTM) are crucial for many applications in coastal management, such as simulation of flood risk scenarios. Airborne LIDAR sensors generate dense height information of large areas for the derivation of suitable DTM in an efficient manner. However, the accuracy and reliability of the LIDAR DTM points suffer if the laser beam interacts with vegetation. Several filter algorithms were developed, which usually apply geometric criteria to eliminate the vegetation points. However, in areas of very dense vegetation and rough terrain, where only few laser pulses are able to penetrate the canopy, such processing often fails resulting in an upward height shift of the derived DTM. In this paper additional features are proposed, which correspond to the reflectance characteristics of the backscattering objects, to support the filtering proccess. The introduced new algorithm uses intensity information and the distribution of multiple echoes for adaptive weight update in an iterative surface fitting procedure. The benefit of the integration of these new features in the filtering method is shown for several areas covered by different types of coastal shrubberies.

Uwe Soergel | Jens Goepfert | Alexander Brzank

[1] K. Mengersen,et al. Airborne laser scanning: Exploratory data analysis indicates potential variables for classification of individual trees or forest stands according to species , 2005 .

[2] A. Jelalian. Laser radar systems , 1980 .

[3] ESTIMATION OF THE LIDAR HEIGHT OFFSET IN COASTAL VEGETATED AREAS , 2007 .

[4] W. Wagner,et al. Gaussian decomposition and calibration of a novel small-footprint full-waveform digitising airborne laser scanner , 2006 .

[5] ASSESSMENT OF LIDAR DTM ACCURACY IN COASTAL VEGETATED AREAS , 2006 .

[6] George Vosselman,et al. Experimental comparison of filter algorithms for bare-Earth extraction from airborne laser scanning point clouds , 2004 .

[7] G. Sithole,et al. Segmentation and classification of airborne laser scanner data , 2005 .

[8] K. Kraus,et al. Determination of terrain models in wooded areas with airborne laser scanner data , 1998 .

[9] R. Wack,et al. DIGITAL TERRAIN MODELS FROM AIRBORNE LASER SCANNER DATA - A GRID BASED APPROACH , 2002 .

[10] D. Tóvári,et al. 3D object classification in laserscanning data , 2004 .

[11] G. Vosselman. SLOPE BASED FILTERING OF LASER ALTIMETRY DATA , 2000 .

[12] M. Brovelli,et al. Managing and processing LIDAR data within GRASS , 2002 .