A Minimax Framework for Classification with Applications to Images and High Dimensional Data
This paper introduces a minimax framework for multiclass classification, which is applicable to general data including, in particular, imagery and other types of high-dimensional data. The framework consists of estimating a representation model that minimizes the fitting errors under a class of distortions of interest to an application, and deriving subsequently categorical information based on the estimated model. A variety of commonly used regression models, including lasso, elastic net and ridge regression, can be regarded as special cases that correspond to specific classes of distortions. Optimal decision rules are derived for this classification framework. By using kernel techniques the framework can account for nonlinearity in the input space. To demonstrate the power of the framework we consider a class of signal-dependent distortions and build a new family of classifiers as new special cases. This family of new methods-minimax classification with generalized multiplicative distortions-often outperforms the state-of-the-art classification methods such as the support vector machine in accuracy. Extensive experimental results on images, gene expressions and other types of data verify the effectiveness of the proposed framework.
MSU Digital Commons Citation
Cheng, Qiang; Zhou, Hongbo; Cheng, Jie; and Li, Huiqing, "A Minimax Framework for Classification with Applications to Images and High Dimensional Data" (2014). Department of Computer Science Faculty Scholarship and Creative Works. 40.