Open AccessDynamic equilibrium limit order book model and optimal execution problem
Author(s) -
Jin Ma,
Xinyang Wang,
Jianfeng Zhang
Publication year - 2015
Publication title -
mathematical control and related fields
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.658
H-Index - 21
eISSN - 2156-8472
pISSN - 2156-8499
DOI - 10.3934/mcrf.2015.5.557
Subject(s) - bellman equation , limit (mathematics) , dynamic programming , viscosity solution , mathematics , mathematical optimization , function (biology) , partial differential equation , argument (complex analysis) , zero (linguistics) , variational inequality , order (exchange) , mathematical economics , computer science , mathematical analysis , economics , biochemistry , finance , evolutionary biology , biology , chemistry , linguistics , philosophy
In this paper we propose a dynamic model of Limit Order Book (LOB). The main feature of our model is that the shape of the LOB is determined endogenously by an expected utility function via a competitive equilibrium argument. Assuming zero resilience, the resulting equilibrium density of the LOB is random, nonlinear, and time inhomogeneous. Consequently, the liquidity cost can be defined dynamically in a natural way. We next study an optimal execution problem in our model. We verify that the value function satisfies the Dynamic Programming Principle, and is a viscosity solution to the corresponding Hamilton-Jacobi-Bellman equation which is in the form of an integro-partial-differential quasi-variational inequality. We also prove the existence and analyze the structure of the optimal strategy via a verification theorem argument, assuming that the PDE has a classical solution.
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