Vincenzo Ignazio scite author profile

In this article we prove the existence of classical solutions to a system of mean field games arising in the study of exhaustible resource production under market competition. Individual trajectories are modeled by a controlled diffusion process with jumps, which adds a nonlocal term to the PDE system. The assumptions on the Hamiltonian are sufficiently general to cover a large class of examples proposed in the literature on Bertrand and Cournot mean field games. Uniqueness also holds under a sufficient restriction on the structure of the Hamiltonian, which in practice amounts to a small upper bound on the substitutability of goods.

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Mean Field Game Partial Differential Equations and Measured Valued Jump Diffiusons

Ignazio¹

2020

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Vincenzo Ignazio

Viscosity Solutions for Controlled McKean--Vlasov Jump-Diffusions

Nonlocal Bertrand and Cournot mean field games with general nonlinear demand schedule

Viscosity solutions for controlled McKean--Vlasov jump-diffusions

Nonlocal Bertrand and Cournot Mean Field Games with General Nonlinear Demand Schedule

Mean Field Game Partial Differential Equations and Measured Valued Jump Diffiusons

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