Fusion model of unmanned aerial vehicle-based digital elevation model for accuracy improvement mapping
Most construction projects require accurate Digital Elevation Model (DEM) data adhere to a certain standard of accuracy both in the horizontal and vertical components. However, due to the DEM inherent errors, it has been a major research concern to generate accurate DEM over large and inaccessibl...
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Main Author: | |
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Format: | Thesis |
Language: | English |
Published: |
2020
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Subjects: | |
Online Access: | http://psasir.upm.edu.my/id/eprint/85496/1/FK%202020%2049%20ir.pdf http://psasir.upm.edu.my/id/eprint/85496/ |
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Institution: | Universiti Putra Malaysia |
Language: | English |
Summary: | Most construction projects require accurate Digital Elevation Model (DEM) data
adhere to a certain standard of accuracy both in the horizontal and vertical
components. However, due to the DEM inherent errors, it has been a major research
concern to generate accurate DEM over large and inaccessible areas in a cost and time effective
manner. Hence, the fusion of UAV-based DEMs. This study aimed: (i) to
develop models for investigating the effect of Atmospheric Pressure (AP) on DEMs
generated from fixed-wing UAV platform, (ii) to develop a methodological approach
for determining an optimum flying altitude for UAV cadastral mapping and (iii) to
develop fusion and filtering algorithms for improving the vertical accuracy of DEM
generated by UAV systems. Before aerial photography, forty-five ground control
points (GCPs) were established evenly in the study area using a real-time kinematic
differential global positioning system for georeferencing and quality assessment of
UAV products (DEM and orthoimage). Regarding the first objective, a canon digital
camera onboard fixed-wing UAV was flown over UniPutra golf club in the Universiti
Putra Malaysia campus at an altitude of 100 m, 150 m, 200 m, 250 m, 350 m, 400 m,
and 500 m. The onboard camera took a series of overlapping photographs of the study
area at a predefined three seconds regular time interval. The photos were processed
using Agisoft algorithm. In the end, seven DEMs were exported in tiff file format. The
DEMs were evaluated for atmospheric pressure effect using a proposed mathematical
model. The results of the AP effect on the DEM at 100 m, 150 m, 200 m, 250 m, 350
m, 400 m, and 500 m altitudes produced 0.072 m, 0.05 m, 0.014 m, 0.01m, 0.004 m,
0.003 m, and 0.002 m, respectively. The results were verified using the height of
established GCPs and corresponding points on the DEMs. The verification process
provides RMSE of 0.03 m, 0.05 m, 0.07 m, 0.1 m, 0.13 m, 0.14 m, and 0.16 m,
respectively. The results show that the DEM produced at an altitude of 100 m
generated a higher accuracy of 0.03 m despite a huge AP effect of 0.072 m.
Conversely, at 500 m altitude, a lesser AP effect of 0.02 produced a low-quality DEM
of 0.16 m. Analysis of variance (ANOVA) test conducted to uncover the interacting effects of AP on the DEMs produced 0.931 (R-value), 0.867 (R Square), and 0.017
(significance F) correlation coefficients. The results of the test indicated goodness of
fit because both Multiple R and R Square values are very close to 1 and Significance
F value < 0.05. The overall results of the experiment show that the effect of AP is
insignificant and, thus, can be ignored. To achieve the second objective, Tarot 680-
hexacopter UAV was flown over the stadium UPM near the UniPutra golf club at the
Universiti to take photographs at an altitude range of 70 m, 100 m, and 250 m. The
photographs were processed and georeferenced using an Agisoft PhotoScan algorithm
and ten of established ground control points, respectively. The resulting orthoimages
exported to an ArcGIS software for cadastral map digitization. Analyses, such as
visual, tabular, and graphical, were carried out to examine an optimum flight altitude
for cadastral mapping. The results of the study show that the cadastral map at 70 m
altitude produced an optimum result. The last objective proposes a fusion model that
integrates a weighted averaging and median additive filtering to improve the quality
of DEM derived from fixed-wing UAVs. The fixed-wing DEM was fused with highquality
DEM generated from a multi-rotor UAV platform. Assessment of the DEM
produced root mean square error of 1.14 cm and standard vertical accuracy of 2.24 cm
at a 95% confidence level (CL). This value represents a decrease in the vertical
standard error of 18.31 cm to 2.24 cm, which is an improvement of 87.77%. The result
of the study indicated that the method is suitable for improving a low-quality DEM
produced by the UAV system. Transferability assessment of the proposed model was
conducted by fusing a high-accuracy DEM generated from a LiDAR dataset (1.87 cm)
with a low-accuracy fixed-wing DEM. The resulting DEM was filtered for noise
reduction. Accuracy assessment of fused and filtered DEM at 95% CL produced 2.13
cm, which is a gap of 16.18 cm (88.37%) when compared with a low-accuracy input
DEM. The results show that the method is not only efficient for improving UAV DEM
quality but also can be used to improve the quality of DEM derived from other sensors. |
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