Maximum-Likelihood Estimation of Discretely Sampled Diffusions: A Closed-Form Approach
Yacine Ait-Sahalia
Princeton University - Department of Economics; National Bureau of Economic Research (NBER)
January 1998
Center for Research in Security Prices (CRSP) Working Paper No. 467
Abstract:
When a continuous-time diffusion is observed only at discrete dates, not necessarily close together, the likelihood function of the observations is in most cases not explicitly computable. Researchers have relied on simulations of sample paths in between the observation points, or numerical solutions of partial differential equations, to obtain estimates of the function to be maximized. By contrast, we construct a sequence of fully explicit functions which we show converge under very general conditions, including non-ergodicity, to the true (but unknown) likelihood function of the discretely-sampled diffusion. We document that the rate of convergence of the sequence is extremely fast for a number of examples relevant in finance. We then show that maximizing the sequence instead of the true function results in an estimator which converges to the true maximum-likelihood estimator and shares its asymptotic properties of consistency, asymptotic normality and efficiency. Applications to the valuation of derivative securities are also discussed.
JEL Classifications: G12, C13, C22
Working Paper Series
Suggested Citation
Ait-Sahalia, Yacine, Maximum-Likelihood Estimation of Discretely Sampled Diffusions: A Closed-Form Approach (January 1998). Center for Research in Security Prices (CRSP) Working Paper No. 467. Available at SSRN: http://ssrn.com/abstract=94135 or doi:10.2139/ssrn.94135
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