On Learning Latent Models with Multi-Instance Weak Supervision
Abstract
We consider a weakly supervised learning scenario where the supervision signal is generated by a transition function of labels associated with multiple input instances. We formulate this problem as \emph{multi-instance Partial Label Learning (multi-instance PLL)}, which is an extension to the standard PLL problem. Our problem is met in different fields, including latent structural learning and neuro-symbolic integration. Despite the existence of many learning techniques, limited theoretical analysis has been dedicated to this problem. In this paper, we provide the first theoretical study of multi-instance PLL with possibly an unknown transition . Our main contributions are as follows. Firstly, we propose a necessary and sufficient condition for the learnability of the problem. This condition non-trivially generalizes and relaxes the existing small ambiguity degree in the PLL literature, since we allow the transition to be deterministic. Secondly, we derive Rademacher-style error bounds based on a top- surrogate loss that is widely used in the neuro-symbolic literature. Furthermore, we conclude with empirical experiments for learning under unknown transitions. The empirical results align with our theoretical findings; however, they also expose the issue of scalability in the weak supervision literature.
Cite
@article{arxiv.2306.13796,
title = {On Learning Latent Models with Multi-Instance Weak Supervision},
author = {Kaifu Wang and Efthymia Tsamoura and Dan Roth},
journal= {arXiv preprint arXiv:2306.13796},
year = {2024}
}