NeuroRisk: Physics-Informed Neural Optimization for Risk-Aware Traffic Engineering
摘要
In production Wide-Area Networks (WANs), correlated failures dominate availability losses, forcing operators to reserve large safety margins that leave substantial capacity underutilized. Achieving high utilization under strict availability targets therefore requires risk-aware Traffic Engineering (TE) over dozens to hundreds of probabilistic failure scenarios-yet solving this problem at operational timescales remains elusive. We demonstrate that existing risk-aware formulations can be unified under an embedded Sort-and-Select structure, exposing a fundamental trade-off between expressiveness and tractability: classical optimizers either restrict scenario selection for efficiency or incur prohibitive decomposition costs. While deep learning appears promising, prior Deep TE methods mainly target maximum link utilization and rely on scaling-based feasibility, which fundamentally breaks under explicit capacity constraints and scenario-dependent risk. We present NeuroRisk, a physics-informed deep unrolled optimizer that exploits the structure of Sort-and-Select. NeuroRisk enforces feasibility via gated edge-local reservations and represents scenario sets through permutation-invariant, gradient-aligned cues. Evaluations on production-style WANs show that NeuroRisk achieves small optimality gaps relative to the solver with orders of magnitude speedup on risk objectives, while outperforming neural baselines on nominal throughput.
引用
@article{arxiv.2605.12862,
title = {NeuroRisk: Physics-Informed Neural Optimization for Risk-Aware Traffic Engineering},
author = {Yingming Mao and Ximeng Liu and Jingyi Cheng and Xiyuan Liu and Jiashuai Liu and Yike Liu and Zhen Yao and Yuzhou Zhou and Siyuan Feng and Qiaozhu Zhai and Shizhen Zhao},
journal= {arXiv preprint arXiv:2605.12862},
year = {2026}
}