【 摘 要 】

Accuracy of digital elevation models (DEMs) often depends on how features of different spatial scales are represented. Scale dependence is particularly important in low gradient coastal environments where small vertical errors can affect large areas and where representation of fine scale topographic features can influence how DEMs are used for modeling inundation. It is commonly observed that different types of DEMs represent larger, coarse-scale topographic features similarly but differ in how they represent smaller, finer-scale features. The spatial-scale dependence of DEM accuracy can be quantified in terms of the correlation scale (lambda(C)); the spatial wavelength above which models agree with spectral coherency >05 and below which they differ. We compare cross spectral analyses of the GDEM2 and SRTM global DEMs with 14,572 LiDAR-derived elevations along transects in diverse coastal environments of New York City. Both global DEMs have positive bias relative to LiDAR ground elevations, but bias (mu) and uncertainty (sigma) of GDEM2 (mu: 8.1 m; sigma: 7.6 m) are significantly greater than those of SRTM (mu: 1.9 m; sigma. 3.6 m). Cross-spectral coherency between GDEM2 and the LiDAR DEM begins to roll-off at scales of lambda < similar to 3 km, while coherency between SRTM and the LiDAR DEM begins to roll-off at scales of lambda < similar to 1 km. The correlation scale below which coherency with LiDAR attains a signal to noise ratio of I is similar to 1 km for GDEM2 and similar to 0.5 km for SRTM; closely matching the divergence scales where the surface roughness of the land cover exceeds the roughness of the underlying terrain. (C) 2014 Published by Elsevier Inc.

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10_1016_j_rse_2014_11_031.pdf	1750KB	PDF	download