Title :
Polynomial chaos based uncertainty quantification in Hamiltonian and chaotic systems
Author :
Pasini, Jose Miguel ; Sahai, Tuhin
Author_Institution :
United Technol. Res. Center, East Hartford, CT, USA
Abstract :
Polynomial chaos is a powerful technique for propagating uncertainty through ordinary and partial differential equations. Random variables are expanded in terms of orthogonal polynomials and differential equations are derived for the coefficients. Here we study the structure and dynamics of these differential equations when the original system has Hamiltonian structure or displays chaotic dynamics. In particular, we prove that the differential equations for the expansion coefficients in generalized polynomial chaos expansions of Hamiltonian systems retain the Hamiltonian structure relative to the ensemble average Hamiltonian. Additionally, using the forced Duffing oscillator as an example, we demonstrate that when the original dynamical system displays chaotic dynamics, the resulting dynamical system from polynomial chaos also displays chaotic dynamics, limiting its applicability.
Keywords :
chaos; nonlinear control systems; partial differential equations; polynomials; time-varying systems; uncertain systems; Hamiltonian systems; chaotic dynamics; chaotic systems; dynamical system; ensemble average Hamiltonian structure; forced Duffing oscillator; generalized polynomial chaos expansion coefficient; ordinary differential equations; orthogonal polynomials; partial differential equations; polynomial chaos based uncertainty quantification; random variables; uncertainty propagation; Chaos; Computational modeling; Mathematical model; Polynomials; Uncertainty;
Conference_Titel :
Decision and Control (CDC), 2013 IEEE 52nd Annual Conference on
Conference_Location :
Firenze
Print_ISBN :
978-1-4673-5714-2
DOI :
10.1109/CDC.2013.6760031
