Large-Model-Driven Supercomputer Center Cooling System Intelligent Operations and Maintenance: Mechanism-Based Digital Twin and Knowledge-Augmented Multi-Agent Collaboration
ID:77 View Protection:ATTENDEE Updated Time:2025-11-10 11:40:47 Hits:311 Oral Presentation

Start Time:2025-11-23 08:30(Asia/Shanghai)

Duration:20min

Session:S4 Parallel Session 4 » S4-2Parallel Session 4-23 AM

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Abstract
Efficient and reliable cold source supply is vital for large-scale supercomputing systems, especially during batch computing or training, where temperature fluctuations directly affect throughput and hardware lifespan. However, conventional cooling strategies often struggle to adapt to the dynamic and complex thermal loads in modern high-performance computing (HPC), resulting in energy inefficiency and potential hardware failures. This paper introduces DCAIM-GPT—a mechanism-knowledge hybrid framework that integrates high-fidelity digital twins with a multi-agent decision engine empowered by enhanced Retrieval-Augmented Generation (RAG) technology. This framework autonomously optimizes critical operational parameters—including but not limited to the number of operating pumps, pump operating frequencies, fan speeds, and cooling tower hierarchical operation modes—under fluctuating computational workloads and outdoor temperature/humidity conditions. It incorporates a large-model-driven multi-agent iterative mechanism to determine optimal parameters while ensuring the supercomputer's cooling source remains within safe operating limits. Experiments in digital twin environments demonstrate that DCAIM-GPT consistently maintains cooling safety and enhances energy efficiency under both dynamic and extreme conditions, evidenced by stable PUE metrics and improved coefficient of performance (COP). This research provides a scalable, universal solution for large-model-empowered efficient and reliable supercomputing operations, laying the foundation for broader vertical industrial large-model applications across the supercomputing domain.
Keywords
digital twin,multi-agent,Large Language Models (LLM),retrieval-augmented generation,energy efficiency,supercomputer center cooling management
Speaker
Yutong Xu
Student University of Electronic Science and Technology of China

Submission Author
Yutong Xu University of Electronic Science and Technology of China
Jiacheng Dai University of Electronic Science and Technology of China
Liyuan Ren Institute of Applied Physics and Computational Mathematics
Linping Wu Institute of Applied Physics and Computational Mathematics
Ying Li Institute of Applied Physics and Computational Mathematics
Huan Wang City University of Hong Kong
Zhiliang Liu University of Electronic Science and Technology of China
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Important Date
  • Conference Date

    Nov 21

    2025

    to

    Nov 23

    2025

  • Oct 20 2025

    Draft paper submission deadline

  • Dec 08 2025

    Registration deadline

Sponsored By
IEEE Instrumentation and Measurement Society
South China University of Technology
Organized By
South China University of Technology