Your search keyword '"Thomas, Valerie"' showing total 2 results

1. Estimating tree canopy cover using harmonic regression coefficients derived from multitemporal Landsat data.

Author

Derwin, Jill M., Thomas, Valerie A., Wynne, Randolph H., Coulston, John W., Liknes, Greg C., Bender, Stacie, Blinn, Christine E., Brooks, Evan B., Ruefenacht, Bonnie, Benton, Robert, Finco, Mark V., and Megown, Kevin

Subjects

*FOREST canopies, *ARITHMETIC mean, *EIGENANALYSIS, *GROWING season, *STANDARD deviations, *LAND cover

Abstract

• Harmonic regression coefficients are better predictors of tree canopy cover than median composite components. • Per-pixel prediction variance was obtained from the mean variance of 500 independent model runs. • Harmonic regression variables are less influenced by noise than median composite variables. • Use of all available image data obviates the need for cloud-free scenes near peak growing season. The goal of this study was to evaluate whether harmonic regression coefficients derived using all available cloud-free observations in a given Landsat pixel for a three-year period can be used to estimate tree canopy cover (TCC), and whether models developed using harmonic regression coefficients as predictor variables are better than models developed using median composite predictor variables, the previous operational standard for the National Land Cover Database (NLCD). The two study areas in the conterminous USA were as follows: West (Oregon), bounded by Landsat Worldwide Reference System 2 (WRS-2) paths/rows 43/30, 44/30, and 45/30; and South (Georgia/South Carolina), bounded by WRS-2 paths/rows 16/37, 17/37, and 18/37. Plot-specific tree canopy cover (the response variable) was collected by experienced interpreters using a dot grid overlaid on 1 m spatial resolution National Agricultural Imagery Program (NAIP) images at two different times per region, circa 2010 and circa 2014. Random forest model comparisons (using 500 independent model runs for each comparison) revealed the following (1) harmonic regression coefficients (one harmonic) are better predictors for every time/region of TCC than median composite focal means and standard deviations (across times/regions, mean increase in pseudo R2 of 6.7% and mean decrease in RMSE of 1.7% TCC) and (2) harmonic regression coefficients (one harmonic, from NDVI, SWIR1, and SWIR2), when added to the full suite of median composite and terrain variables used for the NLCD 2011 product, improve the quality of TCC models for every time/region (mean increase in pseudo R2 of 3.6% and mean decrease in RMSE of 1.0% TCC). The harmonic regression NDVI constant was always one of the top four most important predictors across times/regions, and is more correlated with TCC than the NDVI median composite focal mean. Eigen analysis revealed that there is little to no additional information in the full suite of predictor variables (47 bands) when compared to the harmonic regression coefficients alone (using NDVI, SWIR1, and SWIR2; 9 bands), a finding echoed by both model fit statistics and the resulting maps. We conclude that harmonic regression coefficients derived from Landsat (or, by extension, other comparable earth resource satellite data) can be used to map TCC, either alone or in combination with other TCC-related variables. [ABSTRACT FROM AUTHOR]

Published

2020

2. New approach for optimal electricity planning and dispatching with hourly time-scale air quality and health considerations.

Author

Kerl PY, Zhang W, Moreno-Cruz JB, Nenes A, Realff MJ, Russell AG, Sokol J, and Thomas VM

Subjects

Air Pollutants, Occupational toxicity, Georgia, Humans, Air Pollutants, Occupational analysis, Electricity, Occupational Health, Planning Techniques, Power Plants

Abstract

Integrating accurate air quality modeling with decision making is hampered by complex atmospheric physics and chemistry and its coupling with atmospheric transport. Existing approaches to model the physics and chemistry accurately lead to significant computational burdens in computing the response of atmospheric concentrations to changes in emissions profiles. By integrating a reduced form of a fully coupled atmospheric model within a unit commitment optimization model, we allow, for the first time to our knowledge, a fully dynamical approach toward electricity planning that accurately and rapidly minimizes both cost and health impacts. The reduced-form model captures the response of spatially resolved air pollutant concentrations to changes in electricity-generating plant emissions on an hourly basis with accuracy comparable to a comprehensive air quality model. The integrated model allows for the inclusion of human health impacts into cost-based decisions for power plant operation. We use the new capability in a case study of the state of Georgia over the years of 2004-2011, and show that a shift in utilization among existing power plants during selected hourly periods could have provided a health cost savings of $175.9 million dollars for an additional electricity generation cost of $83.6 million in 2007 US dollars (USD2007). The case study illustrates how air pollutant health impacts can be cost-effectively minimized by intelligently modulating power plant operations over multihour periods, without implementing additional emissions control technologies.

Published

2015