Robust kernel-based distribution regression

Regularization schemes for regression have been widely studied in learning theory and inverse problems. In this paper, we study regularized distribution regression (DR) which involves two stages of sampling, and aims at regressing from probability measures to real-valued responses by regularization over a reproducing kernel Hilbert space. Many important tasks in statistical learning and inverse problems can be treated in this framework. Examples include multi-instance learning and point estimation for problems without analytical solutions. Recently, theoretical analysis on DR has been carried out via kernel ridge regression and several interesting learning behaviors have been observed. However, the topic has not been explored and understood beyond the least squares based DR. By introducing a robust loss function l_σ for two-stage sampling problems, we present a novel robust distribution regression (RDR) scheme. With a windowing function V and a scaling parameter σ which can be appropriately chosen, l_σ can include a wide range of commonly used loss functions that enrich the theme of DR. Moreover, the loss l_σ is not necessarily convex, which enlarges the regression class (least squares) in the literature of DR. Learning rates in different regularity ranges of the regression function are comprehensively studied and derived via integral operator techniques. The scaling parameter σ is shown to be crucial in providing robustness and satisfactory learning rates of RDR.