Help
Cart
Skip main navigation

Available Issues

April 10, 2013 - May 8, 2026

Available Issues

April 10, 2013 - May 8, 2026

Localization and Exact Simulation of Brownian Motion-Driven Stochastic Differential Equations

Published Online:29 Mar 2013https://doi.org/10.1287/moor.2013.0585

References

  • Aït-Sahalia Y. Transition densities for interest rate and other nonlinear diffusions. J. Finance (1999) 70:1361–1395CrossrefGoogle Scholar
  • Aït-Sahalia Y. Maximum likelihood estimation of discretely sampled diffusions: A closed-form approximation approach. Econometrica (2002) 70:223–262CrossrefGoogle Scholar
  • Aït-Sahalia Y. Closed-form likelihood expansions for multivariate diffusions. Ann. Statist. (2008) 36:906–937CrossrefGoogle Scholar
  • Alfonsi A. On the discretization schemes for the cir (and bessel squared) processes. Monte Carlo Methods Appl. (2005) 11:355–384CrossrefGoogle Scholar
  • Alfonsi A. High order discretization schemes for the cir process: Application to affine term structure and heston model. Math. Comput. (2010) 79:209–237CrossrefGoogle Scholar
  • Andersen L. Simple and efficient simulation of the heston stochastic volatility model. J. Computational Finance (2008) 11:1–42CrossrefGoogle Scholar
  • Asmussen S, Glynn PW. Stochastic Simulation: Algorithms and Analysis (2007) (Springer-Verlag, New York) CrossrefGoogle Scholar
  • Bally V, Talay D. The law of the euler scheme for stochastic differential equations I: Convergence rate of the distribution function. Probab. Theory and Related Fields (1996) 104:43–60CrossrefGoogle Scholar
  • Berkaoui A, Bossy M, Diop A. Euler scheme for SDEs with non-Lipschitz diffusion coefficient: Strong convergence. ESAIM: Probab. Statist. (2008) 12:1–11CrossrefGoogle Scholar
  • Beskos A, Roberts GO. Exact simulation of diffusions. Ann. Appl. Probab. (2005) 15:2422–2444CrossrefGoogle Scholar
  • Beskos A, Papaspiliopoulos O, Roberts GO. Retrospective exact simulation of diffusion sample paths with applications. Bernoulli (2006) 12:1077–1098CrossrefGoogle Scholar
  • Beskos A, Papaspiliopoulos O, Roberts GO. A factorisation of diffusion measure and finite sample path constructions. Metholodogy Comput. Appl. Probab. (2008) 10:85–104CrossrefGoogle Scholar
  • Broadie M, Kaya O, Ingalls , et al. Exact simulation of option Greeks under stochastic volatility and jump diffusion models. Proc. of the 2004 Winter Simulation Conf.(IEEE, Piscataway, NJ) 1607–1615Google Scholar
  • Broadie M, Kaya O. Exact simulation of stochastic volatility and other affine jump diffusion processes. Oper. Res. (2006) 54:217–231LinkGoogle Scholar
  • Burq ZA, Jones OD. Simulation of Brownian motion at first-passage times. Math. Comput. Simulation (2008) 77:64–81CrossrefGoogle Scholar
  • Casella B, Roberts GO. Exact Monte Carlo simulation of killed diffusions. Adv. Appl. Probab. (2007) 40:273–291CrossrefGoogle Scholar
  • Chan KC, Karolyi GA, Longstaff FA, Sanders AB. An empirical comparison of alternative models of the short-term interest rate. J. Finance (1992) 47:1209–1227CrossrefGoogle Scholar
  • Chen N, Huang Z. Brownian meanders, importance sampling and unbiased simulation of diffusion extremes. Oper. Res. Lett. (2012) 40:554–563CrossrefGoogle Scholar
  • Cox JC, Ingersoll JE, Ross SA. A theory of the term structure of interest rates. Econometrica (1985) 53:129–151CrossrefGoogle Scholar
  • Deelstra G, Delbaen F. Convergence of discretized stochastic (interest rate) processes with stochastic drift term. Appl. Stochastic Models and Data Anal. (1998) 14:77–84CrossrefGoogle Scholar
  • Devroye L. Non-Uniform Random Variate Generation (1986) (Springer-Verlag, New York) CrossrefGoogle Scholar
  • Duffie D, Glynn P. Efficient Monte Carlo simulation of security prices. Ann. Appl. Probab. (1995) 5:897–905CrossrefGoogle Scholar
  • Feller W. Two singular diffusion problems. Ann. Math. (1951) 54:173–182CrossrefGoogle Scholar
  • Florens D. Estimation of the diffusion coefficient from crossing. Statist. Inference for Stochastic Processes (1999) 1:175–195CrossrefGoogle Scholar
  • Giles MB. Multi-level Monte Carlo path simulation. Oper. Res. (2008) 56:607–617LinkGoogle Scholar
  • Glasserman P. Monte Carlo Methods in Financial Engineering (2004) (Springer-Verlag, New York) CrossrefGoogle Scholar
  • Glasserman P, Kim K. Gamma expansion of the Heston stochastic volatility model. Finance and Stochastics (2011) 15:267–296CrossrefGoogle Scholar
  • Heston S. A closed-form solution of options with stochastic volatility with applications to bond and currency options. Rev. Financial Stud. (1993) 6:327–343CrossrefGoogle Scholar
  • Higham DJ, Mao X. Convergence of the Monte Carlo simulations involving the mean reverting square root process. J. Computational Finance (2005) 8:35–62CrossrefGoogle Scholar
  • Imhof JP. Density factorizations for Brownian motion, meander and the three-dimensional Bessel process, and applications. J. Appl. Probab. (1984) 21:500–510CrossrefGoogle Scholar
  • Kahl C, Jäckel P. Fast strong approximation Monte-Carlo schemes for stochastic models. Quant. Finance (2006) 6:513–536CrossrefGoogle Scholar
  • Karatzas I, Shreve SE. Browinian Motion and Stochastic Calculus (1991) 2nd ed.(Springer, New York) Google Scholar
  • Karlin S, Talor HM. A Second Course in Stochastic Processes (1981) (Academic Press, San Diego) Google Scholar
  • Kebaier A. Statistical Romberg extrapolation: a new variance reduction method and applications to option pricing. Ann. Appl. Probab. (2005) 15:2681–2705CrossrefGoogle Scholar
  • Kloeden PE, Platen E. Numerical Solution of Stochastic Differential Equations (1992) (Springer-Verlag, Berlin) CrossrefGoogle Scholar
  • Lewis PAW, Shedler GS. Simulation of nonhomogeneous Poisson processes by thinning. Naval Res. Log. Quart. (1979) 26:403–413CrossrefGoogle Scholar
  • Lord R, Koekkoek R, van Dijk D. A comparison of biased simulation schemes for stochastic volatility models. Quant. Finance (2010) 10:177–194CrossrefGoogle Scholar
  • Milstein GN. Approximate integration of stochastic differential equations. Theory Probab. Its Appl. (1974) 19:557–562Google Scholar
  • Pötzelberger K, Wang L. Boundary crossing probability for Brownian motion. J. Appl. Probab. (2001) 38:152–164CrossrefGoogle Scholar
  • Propp JG, Wilson DB. Exact sampling with coupled Markov chains and applications to statistical mechanics. Random Structures and Algorithms (1996) 9:223–252CrossrefGoogle Scholar
  • Talay D, Tubaro L. Expansion of the global error for numerical schemes solving stochastic differential equations. Stochastic Anal. Appl. (1990) 8:94–120CrossrefGoogle Scholar
  • Vasicek OA. An equilibrium characterization of the term structure. J. Financial Econom. (1977) 5:177–188CrossrefGoogle Scholar
  • Williams D. Decomposing the Brownian Path. Bull. Amer. Math. Soc. (1970) 76:871–873CrossrefGoogle Scholar
Previous
Back to Top
INFORMS site uses cookies to store information on your computer. Some are essential to make our site work; Others help us improve the user experience. By using this site, you consent to the placement of these cookies. Please read our Privacy Statement to learn more.
Agree