We are not able to resolve this OAI Identifier to the repository landing page. If you are the repository manager for this record, please head to the Dashboard and adjust the settings.
Solving a random differential equation means to obtain an exact or
approximate expression for the solution stochastic process, and to compute its
statistical properties, mainly the mean and the variance functions. However, a
major challenge is the computation of the probability density function of the
solution. In this article we construct reliable approximations of the probability
density function to the randomized non-autonomous complete linear differential equation by assuming that the diffusion coefficient and the source term are
stochastic processes and the initial condition is a random variable. The key
tools to construct these approximations are the random variable transformation technique and Karhunen-Lo`eve expansions. The study is divided into a
large number of cases with a double aim: firstly, to extend the available results
in the extant literature and, secondly, to embrace as many practical situations
as possible. Finally, a wide variety of numerical experiments illustrate the
potentiality of our findings
Is data on this page outdated, violates copyrights or anything else? Report the problem now and we will take corresponding actions after reviewing your request.