Abstract
One may consider the application of remote sensing as a trade-off between the imaging platforms, sensors, and data gathering and processing techniques. This study addresses the potential of hyperspectral imaging using ultra-light aircraft for vegetation species mapping in an urban environment, exploring both the engineering and scientific aspects related to imaging platform design and image classification methods. An imaging system based on simultaneous use of Rikola frame format hyperspectral and Nikon D800E adopted colour infrared cameras installed onboard a Bekas X32 manned ultra-light aircraft is introduced. Two test imaging flight missions were conducted in July of 2015 and September of 2016 over a 4000 ha area in Kaunas City, Lithuania. Sixteen and 64 spectral bands in 2015 and 2016, respectively, in a spectral range of 500–900 nm were recorded with colour infrared images. Three research questions were explored assessing the identification of six deciduous tree species: (1) Pre-treatment of spectral features for classification, (2) testing five conventional machine learning classifiers, and (3) fusion of hyperspectral and colour infrared images. Classification performance was assessed by applying leave-one-out cross-validation at the individual crown level and using as a reference at least 100 field inventoried trees for each species. The best-performing classification algorithm—multilayer perceptron, using all spectral properties extracted from the hyperspectral images—resulted in a moderate classification accuracy. The overall classification accuracy was 63%, Cohen’s Kappa was 0.54, and the species-specific classification accuracies were in the range of 51–72%. Hyperspectral images resulted in significantly better tree species classification ability than the colour infrared images and simultaneous use of spectral properties extracted from hyperspectral and colour infrared images improved slightly the accuracy over the 2015 image. Even though classifications using hyperspectral data cubes of 64 bands resulted in relatively larger accuracies than with 16 bands, classification error matrices were not statistically different. Alternative imaging platforms (like an unmanned aerial vehicle and a Cessna 172 aircraft) and settings of the flights were discussed using simulated imaging projects assuming the same study area and field of application. Ultra-light aircraft-based hyperspectral and colour-infrared imaging was considered to be a technically and economically sound solution for urban green space inventories to facilitate tree mapping, characterization, and monitoring.
Highlights
Remote sensing is the science and art of gathering information about an object of interest through analysing data acquired by a sensor that is not in contact with the object [1]
The performance of classification algorithms to separate six deciduous tree species differed (Table 3); in practically all cases, multilayer perceptron resulted in the highest classification accuracies and achieved performance (i.e., Cohen’s Kappa overall classification accuracy values), if using all, or selected, bands
This study demonstrated the successful installation and simultaneous use of a frame-type hyperspectral Rikola camera and Nikon D800E camera, which was converted and reconfigured to capture in the NIR (770–950 nm), red + NIR (550–850 nm), and green + NIR (530–630 nm) bands, on-board manned ultra-light aircraft
Summary
Remote sensing is the science and art of gathering information about an object of interest through analysing data acquired by a sensor that is not in contact with the object [1]. The operational application of remote sensing can be understood as a process of trade-offs among the spectral, temporal, and spatial properties of captured images [2] bearing in mind the quality, speed, and price of the final product. Numerous fields of remote sensing applications are supported by an increasing volume of scientific research, aimed at improving the quality of the acquired information. The current study investigated the use of cost-efficient remote sensing solutions in a very specific activity, which could, in principle, be implemented by human-survey based techniques. We discuss the ease and cost-effectiveness potential of using remotely sensed data to facilitate urban green space inventories and monitoring. Trees are important as they regulate urban climates, air and acoustic pollution, accumulate CO2, provide cultural services through recreation and education, and deliver supporting services for human well-being and habitats for biodiversity, etc. [4,5,6,7,8]
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