Tree Approximation of the Long Wave Radiation Parameterization in the NCAR CAM Global Climate Model
Abstract
The computation of Global Climate Models (GCMs) presents significant numerical challenges. This paper presents new algorithms based on sparse occupancy trees for learning and emulating the long-wave radiation parameterization in the National Center of Atmospheric Research (NCAR) Community Atmospheric Model (CAM). This emulation occupies by far the most significant portion of the computational time in the implementation of the climate model. From the mathematical point of view this parameterization can be considered as a mapping R(sup 220) to R(sup 33) which is to be learned from scattered data samples (x(sup i), y(sup i)), i = 1, . . . , N. Hence, the problem represents a typical application of high-dimensional statistical learning. The goal is to develop learning schemes that are not only accurate and reliable, but also computationally efficient and capable of adapting to time-varying environmental states. The algorithms developed in this paper are compared with other approaches such as neural networks, nearest neighbor methods, and regression trees to show how these various goals are met.
Document Details
- Document Type
- Technical Report
- Publication Date
- Jan 01, 2011
- Accession Number
- ADA594269
Entities
People
- Alexei Belochitski
- Michael Fox-rabinovitz
- Peter Binev
- Philipp Lamby
- Ronald DeVore
- Vladimir Krasnopolsky
Organizations
- University of South Carolina