La finance de marché est devenue un des domaines d'ap- plication privilégiés de la recherche opérationnelle. D'un autre côté, rares sont les applications touchant la banque de détail, tournée vers le grand public. Dans ce papier, nous abordons un problème d'actualité dans le secteur bancaire français : l'optimisation de plans de financement immobiliers. Le travail que nous présentons a été effectué dans le cadre du développement par la société Experian-Prologia d'une nouvelle application d'instruction...

The goal of this paper is to make an attempt to generalise the model of pricing European options with an illiquid underlying asset considered by Rogers and Singh (2010). We assume that an investor's decisions have only a temporary effect on the price, which is proportional to the square of the change of the number of asset units in the investor's portfolio. We also assume that the underlying asset price follows a CEV model. To prove existence and uniqueness of the solution, we use techniques similar...

The paper presents a discontinuous Galerkin method for solving partial integro-differential equations arising from the European as well as American option pricing when the underlying asset follows an exponential variance gamma process. For practical purposes of numerical solving we introduce the modified option pricing problem resulting from a localization to a bounded domain and an approximation of small jumps, and we discuss the related error estimates. Then we employ a robust numerical procedure...

Let ${𝔽}_{}^{}$F be a filtration andτbe a random time. Let ${𝔾}_{}^{}$G be the progressive enlargement of ${𝔽}_{}^{}$F withτ. We study the following formula, called the optional splitting formula: For any ${𝔾}_{}^{}$G-optional processY, there exists an ${𝔽}_{}^{}$F-optional processY′ and a function Y′′ defined on [0,∞] × (ℝ+ × Ω) being $ℬ[0,\infty ]\otimes 𝒪\left({𝔽}_{}^{}\right)$ℬ[0,∞]⊗x1d4aa;(F) measurable, such that $Y=Y^{\text{'}}{1}_{[0,\tau )}^{}+Y^{\text{'}\text{'}}\left(\tau \right){\mathbb{1}}_{[\tau ,\infty )}^{}.$Y=Y′1[0,τ)+Y′′(τ)1[τ,∞). (This formula can also be formulated for multiple random timesτ1,...,τk). We are interested in this formula because of its fundamental role in many...