Abstract
Abstract. The multi-lens multispectral cameras (MSCs), such as Micasense Rededge and Parrot Sequoia, can record multispectral information by each separated lenses. With their lightweight and small size, which making they are more suitable for mounting on an Unmanned Aerial System (UAS) to collect high spatial images for vegetation investigation. However, due to the multi-sensor geometry of multi-lens structure induces significant band misregistration effects in original image, performing band co-registration is necessary in order to obtain accurate spectral information. A robust and adaptive band-to-band image transform (RABBIT) is proposed to perform band co-registration of multi-lens MSCs. First is to obtain the camera rig information from camera system calibration, and utilizes the calibrated results for performing image transformation and lens distortion correction. Since the calibration uncertainty leads to different amount of systematic errors, the last step is to optimize the results in order to acquire a better co-registration accuracy. Due to the potential issues of parallax that will cause significant band misregistration effects when images are closer to the targets, four datasets thus acquired from Rededge and Sequoia were applied to evaluate the performance of RABBIT, including aerial and close-range imagery. From the results of aerial images, it shows that RABBIT can achieve sub-pixel accuracy level that is suitable for the band co-registration purpose of any multi-lens MSC. In addition, the results of close-range images also has same performance, if we focus on the band co-registration on specific target for 3D modelling, or when the target has equal distance to the camera.
Highlights
Multispectral (MS) information, including visible (i.e. Red (RED), Green (GRE), and Blue (BLU)) and invisible (i.e. Rededge (REG) and Near Infrared (NIR)) spectral response, are indispensable in the application of precision agriculture
Utilizing multispectral cameras (MSCs) mounted on an UAS (Unmanned Aerial System) for vegetation investigation has the benefits of efficiency and convenience (Sankaran et al, 2015)
In order to evaluate the performance of robust and adaptive band-to-band image transform (RABBIT), both aerial and close-range images acquired from Rededge and Sequoia are utilized for examinations
Summary
Multispectral (MS) information, including visible (i.e. Red (RED), Green (GRE), and Blue (BLU)) and invisible (i.e. Rededge (REG) and Near Infrared (NIR)) spectral response, are indispensable in the application of precision agriculture. Such a combination means that the Sequoia has the benefits of generating a high spatial resolution DSM through the RGB camera and generating orthoimages by triangulating the RGB and MS images together (Jhan et al, 2016)
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