Nonlinear kernel-free quadratic hyper-surface support vector machine with 0-1 loss function

For the binary classification problem, a novel nonlinear kernel-free quadratic hyper-surface support vector machine with 0-1 loss function (QSSVM$_{0/1}$) is proposed. Specifically, the task of QSSVM$_{0/1}$ is to seek a quadratic separating hyper-surface to divide the samples into two categories. And it has better interpretability than the methods using kernel functions, since each feature of the sample acts both independently and synergistically. By introducing the 0-1 loss function to construct the optimization model makes the model obtain strong sample sparsity. The proximal stationary point of the optimization problem is defined by the proximal operator of the 0-1 loss function, which figures out the problem of non-convex discontinuity of the optimization problem due to the 0-1 loss function. A new iterative algorithm based on the alternating direction method of multipliers (ADMM) framework is designed to solve the optimization problem, which relates to the working set defined by support vectors. The computational complexity and convergence of the algorithm are discussed. Numerical experiments on 4 artificial datasets and 14 benchmark datasets demonstrate that our QSSVM$_{0/1}$ achieves higher classification accuracy, fewer support vectors and less CPU time cost than other state-of-the-art methods.