Abstract
Above-Ground Biomass (AGB) assessment using remote sensing has been an active area
of research since the 1970s. However, improvements in the reported accuracy of wide
scale studies remain relatively small. Therefore, there is a need to improve error analysis
to answer the question: Why is AGB assessment accuracy still under doubt? This project
aimed to develop and implement a systematic quantitative methodology to analyse the
uncertainty of remotely sensed AGB, including all perceptible error types and reducing
the associated costs and computational effort required in comparison to conventional
methods.
An accuracy prediction tool was designed based on previous study inputs and their
outcome accuracy. The methodology used included training a neural network tool to
emulate human decision making for the optimal trade-off between cost and accuracy for
forest biomass surveys. The training samples were based on outputs from a number of
previous biomass surveys, including 64 optical data based studies, 62 Lidar data based
studies, 100 Radar data based studies, and 50 combined data studies. The tool showed
promising convergent results of medium production ability. However, it might take many
years until enough studies will be published to provide sufficient samples for accurate
predictions.
To provide field data for the next steps, 38 plots within six sites were scanned with a
Leica ScanStation P20 terrestrial laser scanner. The Terrestrial Laser Scanning (TLS) data
analysis used existing techniques such as 3D voxels and applied allometric equations,
alongside exploring new features such as non-plane voxel layers, parent-child
relationships between layers and skeletonising tree branches to speed up the overall
processing time. The results were two maps for each plot, a tree trunk map and branch
map.
An error analysis tool was designed to work on three stages. Stage 1 uses a Taylor method
to propagate errors from remote sensing data for the products that were used as direct
inputs to the biomass assessment process. Stage 2 applies a Monte Carlo method to
propagate errors from the direct remote sensing and field inputs to the mathematical
model. Stage 3 includes generating an error estimation model that is trained based on the
error behaviour of the training samples.
The tool was applied to four biomass assessment scenarios, and the results show that the
relative error of AGB represented by the RMSE of the model fitting was high (20-35%
of the AGB) in spite of the relatively high correlation coefficients. About 65% of the
RMSE is due to the remote sensing and field data errors, with the remaining 35% due to
the ill-defined relationship between the remote sensing data and AGB. The error
component that has the largest influence was the remote sensing error (50-60% of the
propagated error), with both the spatial and spectral error components having a clear
influence on the total error. The influence of field data errors was close to the remote
sensing data errors (40-50% of the propagated error) and its spatial and non-spatial
Overall, the study successfully traced the errors and applied certainty-scenarios using the
software tool designed for this purpose. The applied novel approach allowed for a
relatively fast solution when mapping errors outside the fieldwork areas.
Date of Award | 2018 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Martin John (Other Supervisor) |
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- Laser scanning
- TLS
- Error analysis
- Error propagation
- Biomass
- Aboveground Biomass
- Remote sensing
Error Propagation Analysis for Remotely Sensed Aboveground Biomass
Alboabidallah, A. H. H. (Author). 2018
Student thesis: PhD