Stochastic Calculus for Quantitative Finance
Auteur : Gushchin Alexander A
In 1994 and 1998 F. Delbaen and W. Schachermayer published two breakthrough papers where they proved continuous-time versions of the Fundamental Theorem of Asset Pricing. This is one of the most remarkable achievements in modern Mathematical Finance which led to intensive investigations in many applications of the arbitrage theory on a mathematically rigorous basis of stochastic calculus. Mathematical Basis for Finance: Stochastic Calculus for Finance provides detailed knowledge of all necessary attributes in stochastic calculus that are required for applications of the theory of stochastic integration in Mathematical Finance, in particular, the arbitrage theory. The exposition follows the traditions of the Strasbourg school.
This book covers the general theory of stochastic processes, local martingales and processes of bounded variation, the theory of stochastic integration, definition and properties of the stochastic exponential; a part of the theory of Lévy processes. Finally, the reader gets acquainted with some facts concerning stochastic differential equations.
- Contains the most popular applications of the theory of stochastic integration
- Details necessary facts from probability and analysis which are not included in many standard university courses such as theorems on monotone classes and uniform integrability
- Written by experts in the field of modern mathematical finance
Date de parution : 08-2015
Ouvrage de 208 p.
15x22.8 cm
Thème de Stochastic Calculus for Quantitative Finance :
Mots-clés :
continuous-time versions; Fundamental Theorem; Asset Pricing; arbitrage theory; stochastic calculus; stochastic integration; optional and predictable s-algebras; predictable stopping times; decomposition; local martingales; bounded variation; stochastic integral; semimartingale; locally bounded integrands; Ito's formula; s-martingale; Ansel-Stricker lemma; exponential; Lévy processes; differential equations; probability; analysis; uniform integrability