Experimental Investigation of Friction Stir Processing Scallop Removal Utilizing Complex Toolpaths

Authors

Tyler Grimm, Clemson University
Laine Mears, Clemson University

Document Type

Poster

Publication Date

4-1-2019

Abstract

The computational complexity of solving nonlinear support vector machine (SVM) is prohibitive on large-scale data. In particular, this issue becomes very sensitive when the data represents additional difficulties such as highly imbalanced class sizes. Typically, nonlinear kernels produce significantly higher classification quality to linear kernels but introduce extra kernel and model parameters which requires computationally expensive fitting. This increases the quality but also reduces the performance dramatically. We introduce a generalized fast multilevel framework for regular and weighted SVM and discuss several versions of its algorithmic components that lead to a good trade-off between quality and time. Our framework is implemented using PETSc which allows an easy integration with scientific computing tasks. The experimental results demonstrate significant speed up compared to the state-of-the-art nonlinear SVM libraries. Our source code, documentation and parameters are available at https://github.com/esadr/mlsvm.

Recommended Citation

Grimm, Tyler and Mears, Laine, "Experimental Investigation of Friction Stir Processing Scallop Removal Utilizing Complex Toolpaths" (2019). Graduate Research and Discovery Symposium (GRADS). 227.
https://open.clemson.edu/grads_symposium/227