English

Cloud-Edge Collaborative Large Models for Robust Photovoltaic Power Forecasting

Machine Learning 2026-03-26 v2 Networking and Internet Architecture

Abstract

Photovoltaic (PV) power forecasting in edge-enabled grids requires balancing forecasting accuracy, robustness under weather-driven distribution shifts, and strict latency constraints. Existing models work well under normal conditions but often struggle with rare ramp events and unexpected weather changes. Relying solely on cloud-based large models often leads to significant communication delays, which can hinder timely and efficient forecasting in practical grid environments. To address these issues, we propose a condition-adaptive cloud-edge collaborative framework *CAPE* for PV forecasting. *CAPE* consists of three main modules: a site-specific expert model for routine predictions, a lightweight edge-side model for enhanced local inference, and a cloud-based large retrieval model that provides relevant historical cases when needed. These modules are coordinated by a screening module that evaluates uncertainty, out-of-distribution risk, weather mutations, and model disagreement. Furthermore, we employ a Lyapunov-guided routing strategy to dynamically determine when to escalate inference to more powerful models under long-term system constraints. The final forecast is produced through adaptive fusion of the selected model outputs. Experiments on two real-world PV datasets demonstrate that *CAPE* achieves superior performance in terms of forecasting accuracy, robustness, routing quality, and system efficiency.

Keywords

Cite

@article{arxiv.2603.22343,
  title  = {Cloud-Edge Collaborative Large Models for Robust Photovoltaic Power Forecasting},
  author = {Nan Qiao and Shuning Wang and Sijing Duan and Wenpeng Cui and Yuzhe Chen and Qingchen Yang and Xingyuan Hua and Ju Ren},
  journal= {arXiv preprint arXiv:2603.22343},
  year   = {2026}
}
R2 v1 2026-07-01T11:33:54.157Z