SRTM DEM Correction in Vegetated Mountain Areas through the Integration of Spaceborne LiDAR, Airborne LiDAR, and Optical Imagery
Abstract
:1. Introduction
2. Study Area and Datasets
Name | Type | Time | Coverage | Resolution | Source |
---|---|---|---|---|---|
Forest inventory | Field measurements | 2004–2009 | -- | -- | U.S. Forest Service |
SRTM DEM | Imagery | 2000 | 5022 km2 | 30 m | U.S. Geological Survey |
GLAS/ICESat | Full-waveform LiDAR | 2003–2009 | -- | ~65 m in diameter | NASA |
Airborne LiDAR | Discrete LiDAR | 2009 | 257 km2 | 15–20 cm in diameter | U.S. Forest Service |
Aerial imagery | Imagery | 2009 | 5022 km2 | 1 m | U.S. Department of Agriculture |
Landsat TM | Imagery | 2009 | 5022 km2 | 30 m | U.S. Geological Survey |
Climate surfaces | Imagery | 1950–2000 | 5022 km2 | 30 m | Alvarez et al., (2014) [37] |
2.1. Study Area
2.2. In-Situ Data
2.3. SRTM Data
2.4. Spaceborne LiDAR Data
2.5. Airborne LiDAR Data
2.6. Aerial Imagery
2.7. Landsat TM Imagery
2.8. Climate Surfaces
3. Methodology
3.1. Canopy Cover Estimation Procedure
3.2. Tree Height Estimation Method
3.3. SRTM DEM Correction Method
3.4. Accuracy Assessment
4. Results
4.1. Canopy Cover Estimation
4.2. Tree Height Estimation
4.3. SRTM DEM Correction
Tree Height (m) | Canopy Cover (%) | Slope (°) | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Group | Mean a | STD b | N c | Group | Mean a | STD b | N c | Group | Mean a | STD b | N c |
0–5 | 3.04 | 7.39 | 34,387 | 0–10 | 2.11 | 7.68 | 15,482 | 0–5 | 9.52 | 8.07 | 43,494 |
5–10 | 6.01 | 8.17 | 13,952 | 10–25 | 4.57 | 9.06 | 15,438 | 5–10 | 12.12 | 8.43 | 69,034 |
10–20 | 7.91 | 8.71 | 40,121 | 25–50 | 7.21 | 8.89 | 44,492 | 10–20 | 12.72 | 10.66 | 111,021 |
20–30 | 13.33 | 9.95 | 139,790 | 50–75 | 11.76 | 9.58 | 87,439 | 20–30 | 13.12 | 14.35 | 41,927 |
30–40 | 20.67 | 10.30 | 42,986 | 75–90 | 15.15 | 10.19 | 65,838 | 30–40 | 12.80 | 18.20 | 7783 |
≥40 | 24.35 | 10.12 | 2751 | 90–100 | 19.29 | 10.86 | 45,298 | ≥40 | 13.30 | 23.13 | 724 |
5. Discussions
5.1. Accuracy of Estimated Vegetation Parameters
5.2. Comparisons among SRTM DEM, GLAS Elevations, LiDAR DEM and Corrected SRTM DEM
Tree Height (m) | Canopy Cover (%) | Slope (°) | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Group | Mean a | STD b | N c | Group | Mean a | STD b | N c | Group | Mean a | STD b | N c |
0–5 | −3.49 | 3.92 | 74 | 0–10 | −3.58 | 4.85 | 36 | 0–5 | −5.45 | 5.25 | 120 |
5–10 | −3.68 | 3.93 | 35 | 10–25 | −1.10 | 2.75 | 50 | 5–10 | −5.57 | 4.77 | 284 |
10–20 | −3.62 | 4.24 | 172 | 25–50 | −3.54 | 4.25 | 201 | 10–20 | −6.23 | 5.02 | 420 |
20–30 | −6.38 | 4.89 | 469 | 50–75 | −6.47 | 4.58 | 423 | 20–30 | −5.57 | 4.98 | 56 |
≥30 | −9.04 | 4.79 | 133 | ≥75 | −9.08 | 4.71 | 173 | ≥30 | −9.02 | 6.62 | 3 |
6. Conclusions
Acknowledgments
Author Contributions
Conflicts of Interest
References
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Su, Y.; Guo, Q.; Ma, Q.; Li, W. SRTM DEM Correction in Vegetated Mountain Areas through the Integration of Spaceborne LiDAR, Airborne LiDAR, and Optical Imagery. Remote Sens. 2015, 7, 11202-11225. https://doi.org/10.3390/rs70911202
Su Y, Guo Q, Ma Q, Li W. SRTM DEM Correction in Vegetated Mountain Areas through the Integration of Spaceborne LiDAR, Airborne LiDAR, and Optical Imagery. Remote Sensing. 2015; 7(9):11202-11225. https://doi.org/10.3390/rs70911202
Chicago/Turabian StyleSu, Yanjun, Qinghua Guo, Qin Ma, and Wenkai Li. 2015. "SRTM DEM Correction in Vegetated Mountain Areas through the Integration of Spaceborne LiDAR, Airborne LiDAR, and Optical Imagery" Remote Sensing 7, no. 9: 11202-11225. https://doi.org/10.3390/rs70911202
APA StyleSu, Y., Guo, Q., Ma, Q., & Li, W. (2015). SRTM DEM Correction in Vegetated Mountain Areas through the Integration of Spaceborne LiDAR, Airborne LiDAR, and Optical Imagery. Remote Sensing, 7(9), 11202-11225. https://doi.org/10.3390/rs70911202