Abstract
Measuring and monitoring the height of vegetation provides important insights into forest age and habitat quality. These are essential for the accuracy of applications that are highly reliant on up-to-date and accurate vegetation data. Current vegetation sensing practices involve ground survey, photogrammetry, synthetic aperture radar (SAR), and airborne light detection and ranging sensors (LiDAR). While these methods provide high resolution and accuracy, their hardware and collection effort prohibits highly recurrent and widespread collection. In response to the limitations of current methods, we designed Y-NET, a novel deep learning model to generate high resolution models of vegetation from highly recurrent multispectral aerial imagery and elevation data. Y-NET’s architecture uses convolutional layers to learn correlations between different input features and vegetation height, generating an accurate vegetation surface model (VSM) at 1×1 m resolution. We evaluated Y-NET on 235 km2 of the East San Francisco Bay Area and find that Y-NET achieves low error from LiDAR when tested on new locations. Y-NET also achieves an R2 of 0.83 and can effectively model complex vegetation through side-by-side visual comparisons. Furthermore, we show that Y-NET is able to identify instances of vegetation growth and mitigation by comparing aerial imagery and LiDAR collected at different times.
Highlights
Frequent and accurate assessments of vegetation are critical for managing forest biomass, designing effective mitigation strategies in anticipation of wildland fires, and managing vegetation in the wildland urban interface (WUI) [1,2,3,4]
We propose Y-NET, a novel deep learning model to generate a high resolution vegetation surface model (VSM) from readily available visual data and terrain data
The motivation behind our work stems from cost, complexity, and periodicity limitations of light detection and ranging (LiDAR) for widespread remote sensing, and the need for current and future modeling software to transition towards higher resolution
Summary
Frequent and accurate assessments of vegetation are critical for managing forest biomass, designing effective mitigation strategies in anticipation of wildland fires, and managing vegetation in the wildland urban interface (WUI) [1,2,3,4]. Current methods of remote sensing for detailed vegetation information include manual ground surveys, aerial photogrammetry, synthetic aperture radar (SAR), and light detection and ranging (LiDAR) [6,7,8,9]. While these methods are widely used, they are all subject to multiple limitations. The accuracy and resolution of SAR is heavily dependent on the relationship between stem biomass and characteristics of the vegetation This relationship is unique to specific vegetation species, preventing techniques from being truly general [8,11,12,13,14]. A fraction of the continental United States has been scanned by LiDAR due to the immense cost and collection burden, and most areas are scanned only once with no projected re-scan rate [17]
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