Scaffold with Stochastic Gradients: New Analysis with Linear Speed-Up

Paul Mangold; Alain Durmus; Aymeric Dieuleveut; Eric Moulines

Scaffold with Stochastic Gradients: New Analysis with Linear Speed-Up

Ecole polytechnique

Résultats de recherche: Contribution à un journal › Article de conférence › Revue par des pairs

Résumé

This paper proposes a novel analysis for the Scaffold algorithm, a popular method for dealing with data heterogeneity in federated learning. While its convergence in deterministic settings—where local control variates mitigate client drift—is well established, the impact of stochastic gradient updates on its performance is less understood. To address this problem, we first show that its global parameters and control variates define a Markov chain that converges to a stationary distribution in the Wasserstein distance. Leveraging this result, we prove that Scaffold achieves linear speed-up in the number of clients up to higher-order terms in the step size. Nevertheless, our analysis reveals that Scaffold retains a higher-order bias, similar to FedAvg, that does not decrease as the number of clients increases. This highlights opportunities for developing improved stochastic federated learning algorithms.

langue originale	Anglais
Pages (de - à)	42902-42946
Nombre de pages	45
journal	Proceedings of Machine Learning Research
Volume	267
état	Publié - 1 janv. 2025
Evénement	42nd International Conference on Machine Learning, ICML 2025 - Vancouver, Canada Durée: 13 juil. 2025 → 19 juil. 2025

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title = "Scaffold with Stochastic Gradients: New Analysis with Linear Speed-Up",

abstract = "This paper proposes a novel analysis for the Scaffold algorithm, a popular method for dealing with data heterogeneity in federated learning. While its convergence in deterministic settings—where local control variates mitigate client drift—is well established, the impact of stochastic gradient updates on its performance is less understood. To address this problem, we first show that its global parameters and control variates define a Markov chain that converges to a stationary distribution in the Wasserstein distance. Leveraging this result, we prove that Scaffold achieves linear speed-up in the number of clients up to higher-order terms in the step size. Nevertheless, our analysis reveals that Scaffold retains a higher-order bias, similar to FedAvg, that does not decrease as the number of clients increases. This highlights opportunities for developing improved stochastic federated learning algorithms.",

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AU - Durmus, Alain

AU - Dieuleveut, Aymeric

AU - Moulines, Eric

PY - 2025/1/1

Y1 - 2025/1/1

N2 - This paper proposes a novel analysis for the Scaffold algorithm, a popular method for dealing with data heterogeneity in federated learning. While its convergence in deterministic settings—where local control variates mitigate client drift—is well established, the impact of stochastic gradient updates on its performance is less understood. To address this problem, we first show that its global parameters and control variates define a Markov chain that converges to a stationary distribution in the Wasserstein distance. Leveraging this result, we prove that Scaffold achieves linear speed-up in the number of clients up to higher-order terms in the step size. Nevertheless, our analysis reveals that Scaffold retains a higher-order bias, similar to FedAvg, that does not decrease as the number of clients increases. This highlights opportunities for developing improved stochastic federated learning algorithms.

AB - This paper proposes a novel analysis for the Scaffold algorithm, a popular method for dealing with data heterogeneity in federated learning. While its convergence in deterministic settings—where local control variates mitigate client drift—is well established, the impact of stochastic gradient updates on its performance is less understood. To address this problem, we first show that its global parameters and control variates define a Markov chain that converges to a stationary distribution in the Wasserstein distance. Leveraging this result, we prove that Scaffold achieves linear speed-up in the number of clients up to higher-order terms in the step size. Nevertheless, our analysis reveals that Scaffold retains a higher-order bias, similar to FedAvg, that does not decrease as the number of clients increases. This highlights opportunities for developing improved stochastic federated learning algorithms.

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AN - SCOPUS:105023826032

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JO - Proceedings of Machine Learning Research

JF - Proceedings of Machine Learning Research

Y2 - 13 July 2025 through 19 July 2025

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Scaffold with Stochastic Gradients: New Analysis with Linear Speed-Up

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