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A Two-Stage Learning-to-Defer Approach for Multi-Task Learning

Machine Learning 2025-08-15 v5 Human-Computer Interaction Machine Learning

Abstract

The Two-Stage Learning-to-Defer (L2D) framework has been extensively studied for classification and, more recently, regression tasks. However, many real-world applications require solving both tasks jointly in a multi-task setting. We introduce a novel Two-Stage L2D framework for multi-task learning that integrates classification and regression through a unified deferral mechanism. Our method leverages a two-stage surrogate loss family, which we prove to be both Bayes-consistent and (G,R)(\mathcal{G}, \mathcal{R})-consistent, ensuring convergence to the Bayes-optimal rejector. We derive explicit consistency bounds tied to the cross-entropy surrogate and the L1L_1-norm of agent-specific costs, and extend minimizability gap analysis to the multi-expert two-stage regime. We also make explicit how shared representation learning -- commonly used in multi-task models -- affects these consistency guarantees. Experiments on object detection and electronic health record analysis demonstrate the effectiveness of our approach and highlight the limitations of existing L2D methods in multi-task scenarios.

Keywords

Cite

@article{arxiv.2410.15729,
  title  = {A Two-Stage Learning-to-Defer Approach for Multi-Task Learning},
  author = {Yannis Montreuil and Shu Heng Yeo and Axel Carlier and Lai Xing Ng and Wei Tsang Ooi},
  journal= {arXiv preprint arXiv:2410.15729},
  year   = {2025}
}
R2 v1 2026-06-28T19:29:15.726Z