Abstract
The U.S. Forest Inventory and Analysis Program (FIA) collects inventory data on and computes estimates for many forest attributes to monitor the status and trends of the nation's forests. Increasingly, FIA needs to produce estimates in small geographic and temporal regions. In this application, we implement area level hierarchical Bayesian (HB) small area estimators of several forest attributes for ecosubsections in the Interior West of the US. We use a remotely-sensed auxiliary variable, percent tree canopy cover, to predict response variables derived from ground-collected data such as basal area, biomass, tree count, and volume. We implement four area level HB estimators that borrow strength across ecological provinces and sections and consider prior information on the between-area variation of the response variables. We compare the performance of these HB estimators to the area level empirical best linear unbiased prediction (EBLUP) estimator and to the industry-standard post-stratified (PS) direct estimator. Results suggest that when borrowing strength to areas which are believed to be homogeneous (such as the ecosection level) and a weakly informative prior distribution is placed on the between-area variation parameter, we can reduce variance substantially compared the analogous EBLUP estimator and the PS estimator. Explorations of bias introduced with the HB estimators through comparison with the PS estimator indicates little to no addition of bias. These results illustrate the applicability and benefit of performing small area estimation of forest attributes in a HB framework, as they allow for more precise inference at the ecosubsection level.
Highlights
The USDA Forest Service Forest Inventory and Analysis Program (FIA) collects a sample of inventory data nationwide to monitor status and trends in forested ecosystems at scales relevant for strategic-level planning
We explore the performance of the PS, the area level empirical best linear unbiased prediction (EBLUP), and the area level hierarchical Bayesian (HB) estimators at estimating the mean value of four response variables: basal area (m2 per hectare), count of trees per hectare, above-ground biomass, and net volume of trees (m3 per hectare), excluding rotten or form defects, across the Interior West (IW) of the US
We investigate how borrowing strategies affect the performance of the indirect estimators by comparing estimates and standard errors of the area level estimators applied to ecosubsections when borrowing occurs at the ecoprovincial vs. ecosectional levels
Summary
The USDA Forest Service Forest Inventory and Analysis Program (FIA) collects a sample of inventory data nationwide to monitor status and trends in forested ecosystems at scales relevant for strategic-level planning. When the indirect estimator explicitly relies on a model to link the data in the desired small area with data in other related small areas it is called a small area estimator These linking models can be built either at the area level or unit (i.e., plot) level, depending on data availability and the strength of the relationships between the inventory data and remote sensing data at these two resolutions. We study area level models here because the inventory and remotely-sensed data we consider have strong linear trends at the area level and violate normality assumptions at the unit level. These estimators are constructed under either a frequentist framework where the quantities of interest are fixed, unknown values or a Bayesian framework where they are considered random variables. Key advantages of the Bayesian approach are that it allows the modeler to directly consider uncertainty between the small areas and to obtain distributions, not just point estimates and standard error estimates, for the parameters of interest
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