Abstract
Abstract. The application of UAV-based aerial imagery has advanced exponentially in the past two decades. This can be attributed to UAV operational flexibility, ultra-high spatial resolution, inexpensiveness, and UAV-based sensors enhancement. Nonetheless, the application of multitemporal series of multispectral UAV imagery still suffers significant misregistration errors, and therefore becoming a concern for applications such as precision agriculture. Direct image georeferencing and co-registration is commonly done using ground control points; this is usually costly and time consuming. This research proposes a novel approach for automatic co-registration of multitemporal UAV imagery using intensity-based keypoints. The Speeded Up Robust Features (SURF), Binary Robust Invariant Scalable Keypoints (BRISK), Maximally Stable Extremal Regions (MSER) and KAZE algorithms, were tested and parameters optimized. Image matching performance of these algorithms informed the decision to pursue further experiments with only SURF and KAZE. Optimally parametrized SURF and KAZE algorithms obtained co-registration accuracies of 0.1 and 0.3 pixels for intra-epoch and inter-epoch images respectively. To obtain better intra-epoch co-registration accuracy, collective band processing is advised whereas one-to-one matching strategy is recommended for inter-epoch co-registration. The results were tested using a maize crop monitoring case and the; comparison of spectral response of vegetation between the UAV sensors, Parrot Sequoia and Micro MCA was performed. Due to the missing incidence sensor, spectral and radiometric calibration of Micro MCA imagery is observed to be key in achieving optimal response. Also, the cameras have different specifications and thus differ in the quality of their respective photogrammetric outputs.
Highlights
The application of drone technology in crop monitoring has become rife. Nex & Remondino (2014) review the use of unmanned aerial vehicles for 3D mapping applications, and highlights agriculture as a domain that consumes digital surface models (DSM) and orthoimages to extract useful information on crop status
The experiments aim to compare the performance of the algorithms since they are architecturally different; Speeded Up Robust Features (SURF) and KAZE use float descriptors, while Maximally Stable Extremal Regions (MSER) and Binary Robust Invariant Scalable Keypoints (BRISK) use binary descriptors
5.1.1 Feature Detection using default parameters The results indicated that KAZE outperformed SURF, BRISK and MSER by detecting three times the number of points detected
Summary
The application of drone technology in crop monitoring has become rife. Nex & Remondino (2014) review the use of unmanned aerial vehicles for 3D mapping applications, and highlights agriculture as a domain that consumes digital surface models (DSM) and orthoimages to extract useful information on crop status. UAVs are embraced across domains because they are flexible lowaltitude Remote Sensing (RS) platforms. They are not affected by cloud occlusion, and can achieve ground sampling distances (GSD) of up to 3cm or less depending on the flight parameters and the aim of the acquisition (Nex & Remondino, 2014). This is still ten times higher the spatial resolution of the best VHR satellite imagery. UAVs provide an inexpensive alternative to satellites and other platforms for aerial image acquisition; they increasingly offer tools and inspire innovations that seal the gap between terrestrial and aerial (high-altitude) platforms (Nex et al 2015)
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