Bounds on mean variance hedging in jump diffusion
Applicationes Mathematicae, Tome 50 (2023) no. 1, pp. 1-14.

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We compare the maximum principle and the linear quadratic regulator approach (LQR)/well-posedness criterion to mean variance hedging (MVH) when the wealth process follows a jump diffusion. The comparison is made possible via a measurability assumption on the coefficients of the process. Its application to determine an interval range for the MVH is explained. More precisely, in the MVH setup we show that $$0 \leq \inf _{u \in U}\tfrac{1}{2} E\Big[\int_{0}^T{y’_sy_s}\,ds+y’_Ty_T\Big] = \tfrac{1}{2}y’P^0_0y+f(P^0_0) \leq \tfrac{1}{2}y’P_0y+f(P_0),$$ where P0 and P satisfy a backward stochastic differential equation (BSDE) and f is a measurable function affine in its only argument. The upper bound holds under the measurability assumption that all coefficients including the intensity of the jumps that drive P are in fact predictable with respect to the filtration generated only by the Brownian motion. The lower bound is achieved expectedly under perfect hedging when the Föllmer–Schweizer minimal martingale probability measure is equivalent to the physical measure.
DOI : 10.4064/am2462-6-2023
Mots-clés : compare maximum principle linear quadratic regulator approach lqr well posedness criterion mean variance hedging mvh wealth process follows jump diffusion comparison made possible via measurability assumption coefficients process its application determine interval range mvh explained precisely mvh setup leq inf tfrac int tfrac leq tfrac where satisfy backward stochastic differential equation bsde measurable function affine its only argument upper bound holds under measurability assumption coefficients including intensity jumps drive predictable respect filtration generated only brownian motion lower bound achieved expectedly under perfect hedging llmer schweizer minimal martingale probability measure equivalent physical measure

A. Deshpande 1

1 London Metropolitan University London, UK
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A. Deshpande. Bounds on mean variance hedging in jump diffusion. Applicationes Mathematicae, Tome 50 (2023) no. 1, pp. 1-14. doi : 10.4064/am2462-6-2023. https://geodesic-test.mathdoc.fr/articles/10.4064/am2462-6-2023/

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