English

Online Learning for Multi-Layer Hierarchical Inference under Partial and Policy-Dependent Feedback

Machine Learning 2026-03-05 v1 Artificial Intelligence

Abstract

Hierarchical inference systems route tasks across multiple computational layers, where each node may either finalize a prediction locally or offload the task to a node in the next layer for further processing. Learning optimal routing policies in such systems is challenging: inference loss is defined recursively across layers, while feedback on prediction error is revealed only at a terminal oracle layer. This induces a partial, policy-dependent feedback structure in which observability probabilities decay with depth, causing importance-weighted estimators to suffer from amplified variance. We study online routing for multi-layer hierarchical inference under long-term resource constraints and terminal-only feedback. We formalize the recursive loss structure and show that naive importance-weighted contextual bandit methods become unstable as feedback probability decays along the hierarchy. To address this, we develop a variance-reduced EXP4-based algorithm integrated with Lyapunov optimization, yielding unbiased loss estimation and stable learning under sparse and policy-dependent feedback. We provide regret guarantees relative to the best fixed routing policy in hindsight and establish near-optimality under stochastic arrivals and resource constraints. Experiments on large-scale multi-task workloads demonstrate improved stability and performance compared to standard importance-weighted approaches.

Keywords

Cite

@article{arxiv.2603.04247,
  title  = {Online Learning for Multi-Layer Hierarchical Inference under Partial and Policy-Dependent Feedback},
  author = {Haoran Zhang and Seohyeon Cha and Hasan Burhan Beytur and Kevin S Chan and Gustavo de Veciana and Haris Vikalo},
  journal= {arXiv preprint arXiv:2603.04247},
  year   = {2026}
}

Comments

preprint

R2 v1 2026-07-01T11:03:22.383Z