Abstract
Publicly available land cover maps do not accurately represent shrubs and saplings, an uncommon but ecologically relevant cover type represented by woody vegetation <4 m tall. This omission likely occurs because (1) the resolution is too coarse, (2) poor training data are available, and/or (3) shrub/saplings are difficult to discriminate from spectrally similar classes. We present a framework for classifying land cover, including shrub/saplings, by combining open-source fine-resolution (1 m) spectral and structural data across a large (>6000 km2) mountainous region. We hypothesized that the combination of spectral (imagery) and structural (LIDAR) data would allow for discrimination of shrub/sapling cover from other cover types. Specifically, we created training data using segmented four-band imagery from the National Agricultural Imagery Program (NAIP). In addition to spectral information from imagery, we used topographic information (elevation, slope, and aspect) and a LIDAR-derived canopy height model to classify land cover within a pixel-based random forests framework. To assess model accuracy, we used image interpretation and an independent sample of validation points. Due to the fine resolution of predictor rasters across such a large geographic region, we classified five subregions (counties) separately. We also compared the landscape metrics calculated for our custom classification at fine (1 m) and coarse resolution (resampled to 30 m) to metrics calculated with National Land Cover Data (NLCD). We achieved an overall accuracy of 89% and >80% accuracy for each land cover class. The LIDAR-derived canopy height model was consistently ranked as the most important predictor of vegetative land cover classes. Compared with our custom classification, NLCD underrepresented pasture/grassland by up to 10% and overrepresented forest up to 30%. There was no correlation between percent shrub/sapling cover in our custom classification and NLCD, suggesting that NLCD is not reliable for applications concerned with this ecologically relevant cover type.
Highlights
IntroductionLand cover classification maps are essential in a wide range of applications, including land use planning, resource inventory, tracking landscape changes, and ecological research [1]
The agencies creating land cover classifications are limited by time and resources in the scope of what they can produce and must prioritize certain scales and land cover classes that will be valuable to the greatest number of users
Because our custom classification relies on Light Detection and Ranging (LIDAR)-derived canopy height models in addition to spectral properties of cover types from satellite imagery, we were able to identify shrubs that would otherwise appear spectrally similar to forests and be classified as such
Summary
Land cover classification maps are essential in a wide range of applications, including land use planning, resource inventory, tracking landscape changes, and ecological research [1]. Publicly available land cover datasets, including the National Land. Cover Database ([2]; hereafter NLCD), are intended for broad use and necessarily have shortcomings when used for specific applications. The agencies creating land cover classifications are limited by time and resources in the scope of what they can produce and must prioritize certain scales and land cover classes that will be valuable to the greatest number of users. The NLCD covers the entire continental United States at a 4.0/).
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