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Main Authors: Zeng, Sihan, Evans, Benjamin Patrick, Bhatt, Sujay, Ardon, Leo, Ganesh, Sumitra, Koppel, Alec
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.15392
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author Zeng, Sihan
Evans, Benjamin Patrick
Bhatt, Sujay
Ardon, Leo
Ganesh, Sumitra
Koppel, Alec
author_facet Zeng, Sihan
Evans, Benjamin Patrick
Bhatt, Sujay
Ardon, Leo
Ganesh, Sumitra
Koppel, Alec
contents We study policy optimization in Stackelberg mean field games (MFGs), a hierarchical framework for modeling the strategic interaction between a single leader and an infinitely large population of homogeneous followers. The objective can be formulated as a structured bi-level optimization problem, in which the leader needs to learn a policy maximizing its reward, anticipating the response of the followers. Existing methods for solving these (and related) problems often rely on restrictive independence assumptions between the leader's and followers' objectives, use samples inefficiently due to nested-loop algorithm structure, and lack finite-time convergence guarantees. To address these limitations, we propose AC-SMFG, a single-loop actor-critic algorithm that operates on continuously generated Markovian samples. The algorithm alternates between (semi-)gradient updates for the leader, a representative follower, and the mean field, and is simple to implement in practice. We establish the finite-time and finite-sample convergence of the algorithm to a stationary point of the Stackelberg objective. To our knowledge, this is the first Stackelberg MFG algorithm with non-asymptotic convergence guarantees. Our key assumption is a "gradient alignment" condition, which requires that the full policy gradient of the leader can be approximated by a partial component of it, relaxing the existing leader-follower independence assumption. Simulation results in a range of well-established economics environments demonstrate that AC-SMFG outperforms existing multi-agent and MFG learning baselines in policy quality and convergence speed.
format Preprint
id arxiv_https___arxiv_org_abs_2509_15392
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning in Stackelberg Mean Field Games: A Non-Asymptotic Analysis
Zeng, Sihan
Evans, Benjamin Patrick
Bhatt, Sujay
Ardon, Leo
Ganesh, Sumitra
Koppel, Alec
Machine Learning
We study policy optimization in Stackelberg mean field games (MFGs), a hierarchical framework for modeling the strategic interaction between a single leader and an infinitely large population of homogeneous followers. The objective can be formulated as a structured bi-level optimization problem, in which the leader needs to learn a policy maximizing its reward, anticipating the response of the followers. Existing methods for solving these (and related) problems often rely on restrictive independence assumptions between the leader's and followers' objectives, use samples inefficiently due to nested-loop algorithm structure, and lack finite-time convergence guarantees. To address these limitations, we propose AC-SMFG, a single-loop actor-critic algorithm that operates on continuously generated Markovian samples. The algorithm alternates between (semi-)gradient updates for the leader, a representative follower, and the mean field, and is simple to implement in practice. We establish the finite-time and finite-sample convergence of the algorithm to a stationary point of the Stackelberg objective. To our knowledge, this is the first Stackelberg MFG algorithm with non-asymptotic convergence guarantees. Our key assumption is a "gradient alignment" condition, which requires that the full policy gradient of the leader can be approximated by a partial component of it, relaxing the existing leader-follower independence assumption. Simulation results in a range of well-established economics environments demonstrate that AC-SMFG outperforms existing multi-agent and MFG learning baselines in policy quality and convergence speed.
title Learning in Stackelberg Mean Field Games: A Non-Asymptotic Analysis
topic Machine Learning
url https://arxiv.org/abs/2509.15392