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Neural Mean-Field Games: Extending Mean-Field Game Theory with Neural Stochastic Differential Equations

reinforcement-learning › multi-agent

📄 Abstract

Abstract: Mean-field game theory relies on approximating games that are intractible to model due to a very large to infinite population of players. While these kinds of games can be solved analytically via the associated system of partial derivatives, this approach is not model-free, can lead to the loss of the existence or uniqueness of solutions, and may suffer from modelling bias. To reduce the dependency between the model and the game, we introduce neural mean-field games: a combination of mean-field game theory and deep learning in the form of neural stochastic differential equations. The resulting model is data-driven, lightweight, and can learn extensive strategic interactions that are hard to capture using mean-field theory alone. In addition, the model is based on automatic differentiation, making it more robust and objective than approaches based on finite differences. We highlight the efficiency and flexibility of our approach by solving two mean-field games that vary in their complexity, observability, and the presence of noise. Lastly, we illustrate the model's robustness by simulating viral dynamics based on real-world data. Here, we demonstrate that the model's ability to learn from real-world data helps to accurately model the evolution of an epidemic outbreak. Using these results, we show that the model is flexible, generalizable, and requires few observations to learn the distribution underlying the data.

Authors (3)

Anna C. M. Thöni

Yoram Bachrach

Tal Kachman

Submitted

April 17, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

This paper introduces neural mean-field games by combining mean-field game theory with neural stochastic differential equations. This data-driven approach is lightweight, learns extensive strategic interactions, and is more robust than traditional methods due to automatic differentiation, addressing limitations of analytical solutions and modeling bias.

Business Value

Enables more accurate and flexible modeling of complex systems with many interacting agents, leading to better decision-making in areas like financial markets, autonomous vehicle coordination, and resource allocation.

Paper Metadata

Innovation Type

Methodological

Deployment Feasibility

Potentially high, as it leverages deep learning and automatic differentiation, which are well-established. However, requires significant computational resources for training and validation.

Limitations Addressed

Model-dependency of analytical solutions,Loss of existence/uniqueness of solutions,Modelling bias,Difficulty in capturing extensive strategic interactions,Inflexibility of finite difference methods

Technical Tags

mean-field gamesneural stochastic differential equationsdeep learningdata-driven modelingautomatic differentiationgame theorystrategic interactionsmodel-free learningpopulation dynamicscontrol theory

Research Topics

Game TheoryMachine LearningDifferential EquationsAgent-Based ModelingComputational Economics

Methods & Architectures

Neural Stochastic Differential Equations (NSDEs)Deep LearningAutomatic DifferentiationModel-Free Learning Neural Stochastic Differential Equations

Applications & Tasks

Economics Finance Robotics Resource Management Modeling complex systemsApproximating intractable gamesLearning strategic interactionsSolving differential equations Solving mean-field gamesLearning agent strategiesPredicting population behavior

Related Fields

Game TheoryMachine LearningStochastic ProcessesPartial Differential EquationsControl TheoryEconomicsComputational Finance

Keywords

mean-field gamesneural stochastic differential equationsdeep learninggame theorydata-drivenmodel-freeautomatic differentiationstrategic interactionpopulation dynamicscontroleconomicsfinanceroboticsresource management

Academic Context

#Game Theory#Machine Learning#Differential Equations#Agent-Based Modeling#Computational Economics

Technology Stack

Frameworks & Libraries

Deep Learning Frameworks (e.g., PyTorch, TensorFlow)

Commercial Potential

Potential Products

Simulation platforms for economic/financial systemsDecision support systems for multi-agent coordinationTools for optimizing resource allocation

Target Industries

FinanceEconomicsAutonomous SystemsEnergyLogistics

Use Case Examples

Modeling stock market dynamicsCoordinating fleets of autonomous vehiclesOptimizing energy grid managementSimulating crowd behavior

Competitive Edge

Offers a more flexible, data-driven, and robust alternative to traditional analytical methods for solving mean-field games, particularly when analytical solutions are intractable or prone to bias.

Resource Requirements

Compute Needs

High, especially for training complex neural networks and simulating large populations.

Data Requirements

Requires data that captures the interactions and dynamics of the system being modeled.

Deployment Constraints

Computational cost,Data availability and quality,Interpretability of learned strategies

Scalability

Scalability depends on the complexity of the NSDEs and the size of the population being modeled. Deep learning frameworks generally offer good scalability.

Production Readiness

Maturity Level

Research

Time to Market

Long, as it's a foundational research paper.

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