A Comparative Study of Pairwise Learning Methods based on Kernel Ridge Regression
Abstract
Many machine learning problems can be formulated as predicting labels for a pair of objects. Problems of that kind are often referred to as pairwise learning, dyadic prediction or network inference problems. During the last decade kernel methods have played a dominant role in pairwise learning. They still obtain a state-of-the-art predictive performance, but a theoretical analysis of their behavior has been underexplored in the machine learning literature. In this work we review and unify existing kernel-based algorithms that are commonly used in different pairwise learning settings, ranging from matrix filtering to zero-shot learning. To this end, we focus on closed-form efficient instantiations of Kronecker kernel ridge regression. We show that independent task kernel ridge regression, two-step kernel ridge regression and a linear matrix filter arise naturally as a special case of Kronecker kernel ridge regression, implying that all these methods implicitly minimize a squared loss. In addition, we analyze universality, consistency and spectral filtering properties. Our theoretical results provide valuable insights in assessing the advantages and limitations of existing pairwise learning methods.
Cite
@article{arxiv.1803.01575,
title = {A Comparative Study of Pairwise Learning Methods based on Kernel Ridge Regression},
author = {Michiel Stock and Tapio Pahikkala and Antti Airola and Bernard De Baets and Willem Waegeman},
journal= {arXiv preprint arXiv:1803.01575},
year = {2018}
}
Comments
arXiv admin note: text overlap with arXiv:1606.04275