Abstract
A crop height model (CHM) can be an important element of the decision making process in agriculture, because it relates well with many agronomic parameters, e.g., crop height, plant biomass or crop yield. Today, CHMs can be inexpensively obtained from overlapping imagery captured from unmanned aerial vehicle (UAV) platforms or from proximal sensors attached to ground-based vehicles used for regular management. Both approaches have their limitations and combining them with a data fusion may overcome some of these limitations. Therefore, the objective of this study was to investigate if regression kriging, as a geostatistical data fusion approach, can be used to improve the interpolation of ground-based ultrasonic measurements with UAV imagery as covariate. Regression kriging might be suitable because we have a sparse data set (ultrasound) and an exhaustive data set (UAV) and both data sets have favorable properties for geostatistical analysis. To confirm this, we conducted four missions in two different fields in total, where we collected UAV imagery and ultrasonic data alongside. From the overlapping UAV images, surface models and ortho-images were generated with photogrammetric processing. The maps generated by regression kriging were of much higher detail than the smooth maps generated by ordinary kriging, because regression kriging ensures that for each prediction point information from the UAV, imagery is given. The relationship with crop height, fresh biomass and, to a lesser extent, with crop yield, was stronger using CHMs generated by regression kriging than by ordinary kriging. The use of UAV data from the prior mission was also of benefit and could improve map accuracy and quality. Thus, regression kriging is a flexible approach for the integration of UAV imagery with ground-based sensor data, with benefits for precision agriculture-oriented farmers and agricultural service providers.
Highlights
In modern agriculture, fertilization and plant protection can be highly optimized if spatial data about the crop canopy can be made available in a timely manner, and integrated into agronomic measures [1,2]
crop height models (CHM) for precision agricultural needs is through the use of consumer- grade cameras on unmanned aerial vehicles (UAV) [5,6] and by using distance sensors attached to vehicles that pass the fields for making agricultural measurements [7]
The integration of UAV imagery with regression kriging for the spatial estimation of crop height models with ultra-sonic sensing successfully improved relationships with crop height, fresh biomass and, to a lesser extent, with crop yield, compared to univariate interpolation ordinary kriging
Summary
Fertilization and plant protection can be highly optimized if spatial data about the crop canopy can be made available in a timely manner, and integrated into agronomic measures [1,2]. Today’s photogrammetry software uses fast algorithms based on structure from motion techniques to obtain (UAV-CHM), the difference method can be used. This leads to better results than with estimating the crop height from one 3D point cloud with dense cloud classification directly, because there is a high uncertainty in classifying pure ground pixels [12]. The difference method needs two surface models to be generated These are subtracted from each other, one from the crop surface and a corresponding one from the bare ground, for example before sowing or after harvesting. Subsequent studies showed the good relationship of CHMs in combination with the color information of the orthoimage with biomass [5,6,13,14]
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