Stochastic Response of Dynamical Systems with Fractional Derivative Term under Wide-Band Excitation

Abstract: Transient solution of a fractional stochastic dynamical system under wide-band noise excitation is investigated. Generalized Harmonic Balance technique is firstly used to approximate restoring force of the given system as an amplitude-dependent form. In this way, stochastic averaging method then can be applied to transform the system into an Ito differential equation. Furthermore, the fractional derivative in the integral-differential form can be equivalent to a combination of periodic functions after the aver… Show more

“…The governing equation of motion of a linear single-degree-of-freedom system equipped with a viscoelastic 52 device reads 53 mÿ(t) + gD α y(t) + ky(t) = f (t) (1) where m is the mass, k is the stiffness, g is the fractional damping coefficient and D α is the Riemann-Liouville 54 fractional derivative operator defined as …”

Multiple timescale spectral analysis of a linear fractional viscoelastic system under colored excitation

“…The governing equation of motion of a linear single-degree-of-freedom system equipped with a viscoelastic 52 device reads 53 mÿ(t) + gD α y(t) + ky(t) = f (t) (1) where m is the mass, k is the stiffness, g is the fractional damping coefficient and D α is the Riemann-Liouville 54 fractional derivative operator defined as …”

Multiple timescale spectral analysis of a linear fractional viscoelastic system under colored excitation

Cell Renormalized Fokker–Planck equation method (CR-FPK) for fractional order nonlinear system