A Combined Method for Vegetation Classification Based on Visible Bands from UAV Images: A Case Study for Invasive Wild Parsnip Plants
Wild parsnip is an invasive plant that has serious health risks to humans due to the toxin in its sap. Monitoring its presence and spread has been challenging for conservation authorities due to its small size and irregular shape. On traditional remotely-sensed images acquired by satellites or airplanes, wild parsnip cannot be distinguished from other vegetation due to low spatial resolution of the imagery. Unmanned Aerial Vehicles (UAV) can obtain ultra-high resolution (UHR) imagery and have been used for vegetation-related monitoring in both environmental and agricultural applications in recent years. In this study, UAV images captured at Lemoine Point Conservation Area in Kingston, Ontario, are used to test a methodology for distinguishing wild parsnip. The objective of this study is to develop an efficient invasive wild parsnip classification workflow based on UHR digital UAV imagery. The challenge is that all processing options are based only on visible bands information (RGB) of the digital cameras on UAV, which means there is no infrared spectral information to use. The UAV image processing flow included image orientation, digital elevation model (DEM) and digital surface model (DSM) extractions, individual orthophoto production, and orthomosaic generation processing using Simactive’s software. Three vegetation indices and three texture features are calculated and the first two significant features are added to the mosaicked images. The Random Forest algorithm with relevant variables is used as the classifier to distinguish wild parsnip plants from other vegetation types. The optimal image resolution in parsnip analyses are undertaken by comparing accuracy assessments. The results provide an executable workflow to distinguish wild parsnip and show that UAV images, with a simple digital-light camera, are an appropriate and economic resource for small and irregular vegetation detection. The combined method yields reliable and valid outcomes in detecting wild parsnip plants and shows good performance in mapping vegetation.
URI for this recordhttp://hdl.handle.net/1974/23937
Request an alternative formatIf you require this document in an alternate, accessible format, please contact the Queen's Adaptive Technology Centre
The following license files are associated with this item: