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We consider the stochastic differential equation $X_{t} = X ₀ + \int_{0}^{t} (A_{s} + B_{s} X_{s}) d s + \int_{0}^{t} C_{s} d Y_{s}$ , where $A_{t}$ , $B_{t}$ , $C_{t}$ are nonrandom continuous functions of t, X₀ is an initial random variable, $Y = (Y_{t}, t \geq 0)$ is a Gaussian process and X₀, Y are independent. We give the form of the solution ( $X_{t}$ ) to (0.1) and then basing on the results of Plucińska [Teor. Veroyatnost. i Primenen. 25 (1980)] we prove that ( $X_{t}$ ) is a quasi-diffusion proces.

Reliability of difference analogues to preserve stability properties of stochastic Volterra integro-differential equations.

Shaikhet, Leonid E., Roberts, Jason A. (2006)

Advances in Difference Equations [electronic only]

The existence and exponential stability for random impulsive integrodifferential equations of neutral type.

Chen, Huabin, Zhang, Xiaozhi, Zhao, Yang (2010)

Advances in Difference Equations [electronic only]

The set of probability distribution solutions of a linear functional equation

Janusz Morawiec, Ludwig Reich (2008)

Annales Polonici Mathematici

Let (Ω,,P) be a probability space and let τ: ℝ×Ω → ℝ be a function which is strictly increasing and continuous with respect to the first variable, measurable with respect to the second variable. Given the set of all continuous probability distribution solutions of the equation $F (x) = \int_{Ω} F (τ (x, ω)) d P (ω)$ we determine the set of all its probability distribution solutions.

Volterra equations with fractional stochastic integrals.

El-Borai, Mahmoud M., El-Nadi, Khairia El-Said, Mostafa, Osama L., Ahmed, Hamdy M. (2004)

Mathematical Problems in Engineering

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