Vertical accuracy assessment of freely available global DEMs (FABDEM, Copernicus DEM, NASADEM, AW3D30 and SRTM) in flood-prone environments | Natural Hazards Research Australia

Vertical accuracy assessment of freely available global DEMs (FABDEM, Copernicus DEM, NASADEM, AW3D30 and SRTM) in flood-prone environments

The purpose of this study is to provide a comprehensive accuracy assessment of contemporary and freely-available Digital Elevation Models (DEMs).

Publication type

Journal Article

Published date

01/2024

Author Michael Meadows , Prof Simon Jones , A/Prof Karin Reinke
Abstract

This article is open access.

Flood models rely on accurate topographic data representing the bare earth ground surface. In many parts of the world, the only topographic data available are the free, satellite-derived global Digital Elevation Models (DEMs). However, these have well-known inaccuracies due to limitations of the sensors used to generate them (such as a failure to fully penetrate vegetation canopies and buildings). We assess five contemporary, 1 arc- second (≈30 m) DEMs -- FABDEM, Copernicus DEM, NASADEM, AW3D30 and SRTM -- using a diverse reference dataset comprised of 65 airborne- LiDAR surveys, selected to represent biophysical variations in flood-prone areas globally. While vertical accuracy is nuanced, contingent on the specific metrics used and the biophysical character of the site being assessed, we found that the recently-released FABDEM consistently ranked first, improving on the second-place Copernicus DEM by reducing large positive errors associated with forests and buildings. Our results suggest that land cover is the main factor explaining vertical errors (especially forests), steep slopes are associated with wider error spreads (although DEMs resampled from higher-resolution products are less sensitive), and variable error dependency on terrain aspect is likely a function of horizontal geolocation errors (especially problematic for AW3D30 and Copernicus DEM).

Year of Publication
2024
Journal
Internation Journal of Digital Earth
Volume
17
Issue
1
Date Published
01/2024
DOI
https://doi.org/10.1080/17538947.2024.2308734
Locators DOI | Google Scholar

Related projects

Project
Correcting vertical errors in a global Digital Elevation Model to derive a bare earth terrain surface for improved flood modelling in data-scarce regions