Abstract
In order to optimize agricultural processes, near real-time spatial information about in-field variations, such as crop height development (i.e., changes over time), is indispensable. This development can be captured with a LiDAR system. However, its applicability in precision agriculture is often hindered due to high costs and unstandardized processing methods. This study investigates the potential of an autonomously operating low-cost static terrestrial laser scanner (TLS) for multitemporal height monitoring of maize crops. A low-cost system is simulated by artificially reducing the point density of data captured during eight different campaigns. The data were used to derive and assess crop height models (CHM). Results show that heights calculated with CHM based on the unreduced point cloud are accurate when compared to manually measured heights (mean deviation = 0.02 m, standard deviation = 0.15 m, root mean square error (RMSE) = 0.16 m). When reducing the point cloud to 2% of its original size to simulate a low-cost system, this difference increases (mean deviation = 0.12 m, standard deviation = 0.19 m, RMSE = 0.22 m). We found that applying the simulated low-cost TLS system in precision agriculture is possible with acceptable accuracy up to an angular scan resolution of 8 mrad (i.e., point spacing of 80 mm at 10 m distance). General guidelines for the measurement set-up and an automatically executable method for CHM generation and assessment are provided and deserve consideration in further studies.
Highlights
Light detection and ranging (LiDAR) has emerged as a powerful active remote sensing method for direct measurement of 3D plant structure in precision agriculture [1,2]
We found that applying the simulated low-cost terrestrial laser scanner (TLS) system in precision agriculture is possible with acceptable accuracy up to an angular scan resolution of 8 mrad
This study shows that LiDAR technology in general and multitemporal 3D geodata in particular are feasible for application in precision agriculture
Summary
Light detection and ranging (LiDAR) has emerged as a powerful active remote sensing method for direct measurement of 3D plant structure in precision agriculture [1,2]. Complexities caused by the outdoor agricultural environment, such as variable natural lighting, occlusion and obscuration of plant features by foliage from neighboring plants [6] make an automatic observation of in-field variations challenging. This has led to the use of different remote sensing technologies to capture in-field variations including ultrasonic sensors [7,8,9,10,11], photography [12,13,14], Remote Sens. This has led to the use of different remote sensing technologies to capture in-field variations including ultrasonic sensors [7,8,9,10,11], photography [12,13,14], Remote Sens. 2016, 8, 205; doi:10.3390/rs8030205 www.mdpi.com/journal/remotesensing
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