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Diffusion processes are continuous time Markov processes with (almost surely) continuous sample paths. They are defined in terms of stochastic differential equations, and the variety of tools available for solving and handling such equations are referred to as stochastic calculus, often applying celebrated theorems such as those of Itô and Girsanov.
Diffusions frequently appear as a limit of processes with discrete state spaces, and as approximations, they may be easier to handle than the original processes; this is, for example, the case in mathematical finance, where the dynamics in stock prices often are modelled by diffusions - with or without added jumps. Modern techniques in mathematical finance are almost entirely based on stochastic calculus.
Originating from physics more than a century ago, diffusion processes have become one of the most widespread mathematical objects used in stochastic modelling and applied probability, featuring applications in many areas such as insurance risk, queueing theory, biology and stochastic control, to mention a few.
Statistical techniques and the simulation of diffusions (and stochastic differential equations) are both intensive research areas overlapping with applied probability. In particular, Markov chain Monte Carlo and Exact simulation of diffusions and diffusion bridges are important when dealing with continuously or discretely observed diffusions.
Collection created by Professor Mogens Bladt (Københavns Universitet)