English

Pace: Physics-Aware Attentive Temporal Convolutional Network for Battery Health Estimation

Machine Learning 2026-01-26 v3

Abstract

Batteries are critical components in modern energy systems such as electric vehicles and power grid energy storage. Effective battery health management is essential for battery system safety, cost-efficiency, and sustainability. In this paper, we propose Pace, a physics-aware attentive temporal convolutional network for battery health estimation. Pace integrates raw sensor measurements with battery physics features derived from the equivalent circuit model. We develop three battery-specific modules, including dilated temporal blocks for efficient temporal encoding, chunked attention blocks for context modeling, and a dual-head output block for fusing short- and long-term battery degradation patterns. Together, the modules enable Pace to predict battery health accurately and efficiently in various battery usage conditions. In a large public dataset, Pace performs much better than existing models, achieving an average performance improvement of 6.5 and 2.0x compared to two best-performing baseline models. We further demonstrate its practical viability with a real-time edge deployment on a Raspberry Pi. These results establish Pace as a practical and high-performance solution for battery health analytics.

Keywords

Cite

@article{arxiv.2512.11332,
  title  = {Pace: Physics-Aware Attentive Temporal Convolutional Network for Battery Health Estimation},
  author = {Sara Sameer and Wei Zhang and Dhivya Dharshini Kannan and Xin Lou and Yulin Gao and Terence Goh and Qingyu Yan},
  journal= {arXiv preprint arXiv:2512.11332},
  year   = {2026}
}

Comments

Accepted at the ACM Symposium On Applied Computing (SAC), 2026

R2 v1 2026-07-01T08:21:52.467Z