Power Stabilization for AI Training Datacenters
Abstract
Large Artificial Intelligence (AI) training workloads spanning several tens of thousands of GPUs present unique power management challenges. These arise due to the high variability in power consumption during the training. Given the synchronous nature of these jobs, during every iteration there is a computation-heavy phase, where each GPU works on the local data, and a communication-heavy phase where all the GPUs synchronize on the data. Because compute-heavy phases require much more power than communication phases, large power swings occur. The amplitude of these power swings is ever increasing with the increase in the size of training jobs. An even bigger challenge arises from the frequency spectrum of these power swings which, if harmonized with critical frequencies of utilities, can cause physical damage to the power grid infrastructure. Therefore, to continue scaling AI training workloads safely, we need to stabilize the power of such workloads. This paper introduces the challenge with production data and explores innovative solutions across the stack: software, GPU hardware, and datacenter infrastructure. We present the pros and cons of each of these approaches and finally present a multi-pronged approach to solving the challenge. The proposed solutions are rigorously tested using a combination of real hardware and Microsoft's in-house cloud power simulator, providing critical insights into the efficacy of these interventions under real-world conditions.
Cite
@article{arxiv.2508.14318,
title = {Power Stabilization for AI Training Datacenters},
author = {Esha Choukse and Brijesh Warrier and Scot Heath and Luz Belmont and April Zhao and Hassan Ali Khan and Brian Harry and Matthew Kappel and Russell J. Hewett and Kushal Datta and Yu Pei and Caroline Lichtenberger and John Siegler and David Lukofsky and Zaid Kahn and Gurpreet Sahota and Andy Sullivan and Charles Frederick and Hien Thai and Rebecca Naughton and Daniel Jurnove and Justin Harp and Reid Carper and Nithish Mahalingam and Srini Varkala and Alok Gautam Kumbhare and Satyajit Desai and Venkatesh Ramamurthy and Praneeth Gottumukkala and Girish Bhatia and Kelsey Wildstone and Laurentiu Olariu and Ileana Incorvaia and Alex Wetmore and Prabhat Ram and Melur Raghuraman and Mohammed Ayna and Mike Kendrick and Ricardo Bianchini and Aaron Hurst and Reza Zamani and Xin Li and Michael Petrov and Gene Oden and Rory Carmichael and Tom Li and Apoorv Gupta and Pratikkumar Patel and Nilesh Dattani and Lawrence Marwong and Rob Nertney and Hirofumi Kobayashi and Jeff Liott and Miro Enev and Divya Ramakrishnan and Ian Buck and Jonah Alben},
journal= {arXiv preprint arXiv:2508.14318},
year = {2025}
}