Understory biomass measurement based on SfM data by a manual low-flying drone under the canopy
- 1Center for Research in Isotopes and Environmental Dynamics, University of Tsukuba, Ibaraki, Japan (s1930233@s.tsukuba.ac.jp)
- 2Institute of Surface-Earth System Science, Tianjin University, Tianjin , PR China (xinchao.sun@tju.edu.cn)
- 3Department of International Environmental and Agricultural Science, Tokyo University of Agriculture and Technology, Tokyo , Japan (gomit@cc.tuat.ac.jp)
Understory vegetation has the important effect that cannot be ignored on Evapotranspiration. In previous studies, laser scanner was used to measure small-scale biomass and airborne LiDAR was used to assess light availability to understory vegetation, which in turn was converted to understory biomass production. However, it is difficult to measure watershed-scale understory biomass with high resolution. In this study, Structure from Motion (SfM) was used to reconstruct understory vegetation structure by a manual low-flying drone under the canopy with radial paths in a line thinning plantation and a spot thinning plantation made by Japanese cedar and cypress. By generating Orthomosaic image and dense point cloud data, we then extracted Excess Green Index (ExG) and Canopy Height Model (CHM), combining with understory biomass data from field harvesting to establish a quantitative relationship between the CHM and biomass, which was then used to map biomass and vegetation coverage in the study area. The results indicated that (1) a flight height of 7-10 meters is more conducive to understory vegetation reconstruction, with a photo quality greater than 0.8 and a point cloud density of more than 20 points/cm2. (2) a regression cubic model based on the CHM has acceptable accuracy and biomass estimate capability (P<0.01), with a coefficient of determination of 0.75. (3) compared with the spot thinning, the understory biomass under the line thinning scenario was higher(average biomass 3.03kg/m2). (4) vegetation coverage based on the ExG index of visible light analysis was affected by ambient light(strong sunlight on a sunny day), and it cannot reflect the seasonal changes of understory vegetation biomass. These results disclosed the potential of the dense point cloud from drone SfM for estimating understory biomass. With this method, we will measure more than 5000m2 of headwater catchment and output a understory biomass map.
How to cite: Zhang, Y., Onda, Y., Kato, H., Sun, X., and Gomi, T.: Understory biomass measurement based on SfM data by a manual low-flying drone under the canopy, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-14009, https://doi.org/10.5194/egusphere-egu2020-14009, 2020
Comments on the presentation
AC: Author Comment | CC: Community Comment | Report abuse
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CC1:
Comment on EGU2020-14009, Hamideh Nouri, 06 May 2020
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AC1:
Reply to CC1, Yupan Zhang, 06 May 2020
Thanks for your comment, about ET we have values calculated by the Total Soil Moisture measurement in two small plot(4m*10m) , and we hope to analyze the relationship between biomass and ET in the same factors.
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CC3:
Reply to AC1, Hamideh Nouri, 07 May 2020
Thanks Yupan. All the best.
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CC3:
Reply to AC1, Hamideh Nouri, 07 May 2020
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AC1:
Reply to CC1, Yupan Zhang, 06 May 2020
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CC2:
Comment on EGU2020-14009, Stenka Vulova, 07 May 2020
Interesting study! Did you capture any other data with your UAV (spectral, thermal)? Do you know if biomass can be integrated into any models modelling evapotranspiration?
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AC2:
Reply to CC2, Yupan Zhang, 07 May 2020
Thanks for your comment. The small drone used in the study only collected visible light. As you said, I am reading some paper that combines biomass simulation with ET, but more paper focus on some specific species, such as crops and grass, rather than the complex undergrowth vegetation.And please let me know if you have any good Suggestions.
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AC2:
Reply to CC2, Yupan Zhang, 07 May 2020
Very interesting research. Can you please explain how including understory vegetation improve ET estimation? To what extent?