Parametric Optimal Design Of Uncertain Dynamical Systems

Description

This research effort develops a comprehensive computational framework to support the parametric optimal design of uncertain dynamical systems. Uncertainty comes from various sources, such as: system parameters, initial conditions, sensor and actuator noise, and external forcing. Treatment of uncertainty in design is of paramount practical importance because all real-life systems are affected by it; not accounting for uncertainty may result in poor robustness, sub-optimal performance and higher manufacturing costs.

Contemporary methods for the quantification of uncertainty in dynamical systems are computationally intensive which, so far, have made a robust design optimization methodology prohibitive. Some existing algorithms address uncertainty in sensors and actuators during an optimal design; however, a comprehensive design framework that can treat all kinds of uncertainty with diverse distribution characteristics in a unified way is currently unavailable. The computational framework uses Generalized Polynomial Chaos methodology to quantify the effects of various sources of uncertainty found in dynamical systems; a Least-Squares Collocation Method is used to solve the corresponding uncertain differential equations. This technique is significantly faster computationally than traditional sampling methods and makes the construction of a parametric optimal design framework for uncertain systems feasible.

The novel framework allows to directly treat uncertainty in the parametric optimal design process. Specifically, the following design problems are addressed: motion planning of fully-actuated and under-actuated systems; multi-objective robust design optimization; and optimal uncertainty apportionment concurrently with robust design optimization. The framework advances the state-of-the-art and enables engineers to produce more robust and optimally performing designs at an optimal manufacturing cost. / Ph. D.

Links & Downloads

1. etd-09012011-162500
2. http://hdl.handle.net/10919/28850
3. http://scholar.lib.vt.edu/theses/available/etd-09012011-162500/

Tags

Ordinary Differential Equations (ODEs)

Trajectory Planning

Motion Planning

Generalized Polynomial Chaos (gPC)

Uncertainty Quantification

Multi-Objective Optimization (MOO)

Nonlinear Programming (NLP)

Dynamic Optimization

Optimal Control

Robust Design Optimization (RDO)

Collocation

Uncertainty Apportionment

Tolerance Allocation

Multibody Dynamics

Differential Algebraic Equations (DAEs)

Additional Fields

Identifer	oai:union.ndltd.org:VTETD/oai:vtechworks.lib.vt.edu:10919/28850
Date	02 September 2011
Creators	Hays, Joseph T.
Contributors	Mechanical Engineering, Ross, Shane D., Southward, Steve C., Sandu, Adrian, Sandu, Corina, Hong, Dennis W.
Publisher	Virginia Tech
Source Sets	Virginia Tech Theses and Dissertation
Detected Language	English
Type	Dissertation
Format	application/pdf
Rights	In Copyright, http://rightsstatements.org/vocab/InC/1.0/
Relation	Hays_JT_T_2011.pdf