Stochastic Dynamic Optimization and Model Predictive Control based on Polynomial Chaos Theory and Symbolic Arithmetic

Abstract Understanding how variation impacts a multibody dynamic (MBD) system's response is important to ensure the robustness of a system. However, how the variation propagates into the MBD system is complicated because MBD systems are typically governed by a system of large differential algebraic equations. This paper presents a novel process, variational work, along with the polynomial chaos multibody dynamics (PCMBoD) automation process for utilizing polynomial chaos theory (PCT) in the analysis of uncertainties in an MBD system. Variational work allows the complexity of the traditional PCT approach to be reduced. With variational work and the constrained Lagrangian formulation, the equations of motion of an MBD PCT system can be constructed using the PCMBoD automated process. To demonstrate the PCMBoD process, two examples, a mass-spring-damper and a two link slider–crank mechanism, are shown.

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A MATLAB graphical user interface for nonintrusive polynomial chaos theory

2012 Complexity in Engineering (COMPENG). Proceedings ◽

10.1109/compeng.2012.6242955 ◽

2012 ◽

Cited By ~ 2

Author(s):

K. Togawa ◽

A. Benigni ◽

A. Monti

Keyword(s):

User Interface ◽

Graphical User Interface ◽

Chaos Theory ◽

Polynomial Chaos ◽

Polynomial Chaos Theory

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Uncertainty and Worst Case Analysis for a Low-Pass Filter Using Polynomial Chaos Theory

2007 IEEE International Workshop on Advanced Methods for Uncertainty Estimation in Measurement ◽

10.1109/amuem.2007.4362571 ◽

2007 ◽

Cited By ~ 6

Author(s):

A. Smith ◽

A. Monti ◽

F. Ponci

Keyword(s):

Chaos Theory ◽

Polynomial Chaos ◽

Case Analysis ◽

Worst Case Analysis ◽

Worst Case ◽

Pass Filter ◽

Low Pass Filter ◽

Low Pass ◽

Polynomial Chaos Theory

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Battery State of Health and Charge Estimation Using Polynomial Chaos Theory

Volume 1: Aerial Vehicles; Aerospace Control; Alternative Energy; Automotive Control Systems; Battery Systems; Beams and Flexible Structures; Biologically-Inspired Control and its Applications; Bio-Medical and Bio-Mechanical Systems; Biomedical Robots and Rehab; Bipeds and Locomotion; Control Design Methods for Adv. Powertrain Systems and Components; Control of Adv. Combustion Engines, Building Energy Systems, Mechanical Systems; Control, Monitoring, and Energy Harvesting of Vibratory Systems ◽

10.1115/dscc2013-4088 ◽

2013 ◽

Cited By ~ 4

Author(s):

Saeid Bashash ◽

Hosam K. Fathy

Keyword(s):

Parameter Estimation ◽

Chaos Theory ◽

Polynomial Chaos ◽

Search Algorithm ◽

Estimation Method ◽

Experimental Tests ◽

Internal Resistance ◽

Battery State Of Charge ◽

Gradient Based ◽

Polynomial Chaos Theory

In this effort, we use the generalized Polynomial Chaos theory (gPC) for the real-time state and parameter estimation of electrochemical batteries. We use an equivalent circuit battery model, comprising two states and five parameters, and formulate the online parameter estimation problem using battery current and voltage measurements. Using a combination of the conventional recursive gradient-based search algorithm and gPC framework, we propose a novel battery parameter estimation strategy capable of estimating both battery state-of-charge (SOC) and parameters related to battery health, e.g., battery charge capacity, internal resistance, and relaxation time constant. Using a combination of experimental tests and numerical simulations, we examine and demonstrate the effectiveness of the proposed battery estimation method.

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