A unified framework for utility maximization problems: An Orlicz space approach

A unified framework for utility maximization problems: An Orlicz space approach

Sara Biagini and Marco Frittelli

Source: Ann. Appl. Probab. Volume 18, Number 3 (2008), 929-966.

Abstract

We consider a stochastic financial incomplete market where the price processes are described by a vector-valued semimartingale that is possibly nonlocally bounded. We face the classical problem of utility maximization from terminal wealth, with utility functions that are finite-valued over (a, ∞), a∈[−∞, ∞), and satisfy weak regularity assumptions. We adopt a class of trading strategies that allows for stochastic integrals that are not necessarily bounded from below. The embedding of the utility maximization problem in Orlicz spaces permits us to formulate the problem in a unified way for both the cases a∈ℝ and a=−∞. By duality methods, we prove the existence of solutions to the primal and dual problems and show that a singular component in the pricing functionals may also occur with utility functions finite on the entire real line.

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Primary Subjects: 60G48, 60G44, 49N15, 91B28

Secondary Subjects: 46E30, 46N30, 91B16

Keywords: Utility maximization; nonlocally bounded semimartingale; incomplete market; σ-martingale measure; Orlicz space; convex duality; singular functionals

Full-text: Open access

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Links and Identifiers

Permanent link to this document: http://projecteuclid.org/euclid.aoap/1211819790
Digital Object Identifier: doi:10.1214/07-AAP469
Mathematical Reviews number (MathSciNet): MR2418234
Zentralblatt MATH identifier: 1151.60019

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