Abstract
Despite the need for quality land cover information, large-area, high spatial resolution land cover mapping has proven to be a difficult task for a variety of reasons including large data volumes, complexity of developing training and validation datasets, data availability, and heterogeneity in data and landscape conditions. We investigate the use of geographic object-based image analysis (GEOBIA), random forest (RF) machine learning, and National Agriculture Imagery Program (NAIP) orthophotography for mapping general land cover across the entire state of West Virginia, USA, an area of roughly 62,000 km2. We obtained an overall accuracy of 96.7% and a Kappa statistic of 0.886 using a combination of NAIP orthophotography and ancillary data. Despite the high overall classification accuracy, some classes were difficult to differentiate, as highlight by the low user’s and producer’s accuracies for the barren, impervious, and mixed developed classes. In contrast, forest, low vegetation, and water were generally mapped with accuracy. The inclusion of ancillary data and first- and second-order textural measures generally improved classification accuracy whereas band indices and object geometric measures were less valuable. Including super-object attributes improved the classification slightly; however, this increased the computational time and complexity. From the findings of this research and previous studies, recommendations are provided for mapping large spatial extents.
Highlights
Supervised classification of land cover at a high spatial resolution (1–5 m) over large areas can be challenging due to large data volumes, computational load, processing time, complexity of developing training and validation datasets, data availability, and heterogeneity in data and landscape conditions [1,2,3,4,5,6]
Basu et al [1] mapped the extent of tree canopy cover across the entire state of California using 1 m aerial imagery and suggested that the proposed method could be applied to the entirety of the contiguous United States (CONUS)
One goal of this study is to explore the value of common measures for general land cover mapping over large areas
Summary
Supervised classification of land cover at a high spatial resolution (1–5 m) over large areas can be challenging due to large data volumes, computational load, processing time, complexity of developing training and validation datasets, data availability, and heterogeneity in data and landscape conditions [1,2,3,4,5,6]. O’Neil-Dunne et al [4] used geographic object-based image analysis (GEOBIA) methods and a variety of high spatial resolution datasets to map urban and suburban tree canopy cover in more than 70 cities and counties in the United States. The Chesapeake Conservancy and partners produced a 1 m land cover dataset for all counties that intersect the Chesapeake Bay drainage basin, an area of approximately 250,000 km2 [13]. These data are currently being used to train a deep neural network model implemented by Microsoft Azure AI [14]
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