Parameter Estimation In Heat Transfer And Elasticity Using Trained Pod-rbf Network Inverse Methods

Rogers, Craig

01 January 2010

In applied mechanics it is always necessary to understand the fundamental properties of a system in order to generate an accurate numerical model or to predict future operating conditions. These fundamental properties include, but are not limited to, the material parameters of a specimen, the boundary conditions inside of a system, or essential dimensional characteristics that define the system or body. However in certain instances there may be little to no knowledge about the systems conditions or properties; as a result the problem cannot be modeled accurately using standard numerical methods. Consequently, it is critical to define an approach that is capable of identifying such characteristics of the problem at hand. In this thesis, an inverse approach is formulated using proper orthogonal decomposition (POD) with an accompanying radial basis function (RBF) network to estimate the current material parameters of a specimen with little prior knowledge of the system. Specifically conductive heat transfer and linear elasticity problems are developed in this thesis and modeled with a corresponding finite element (FEM) or boundary element (BEM) method. In order to create the truncated POD-RBF network to be utilized in the inverse approach, a series of direct FEM or BEM solutions are used to generate a statistical data set of temperatures or deformations in the system or body, each having a set of various material parameters. The data set is then transformed via POD to generate an orthonormal basis to accurately solve for the desired material characteristics using the Levenberg-Marquardt (LM) algorithm. For now, the LM algorithm can be simply defined as a direct relation to the minimization of the Euclidean norm of the objective Least Squares function(s). The trained POD-RBF inverse technique outlined in this thesis provides a flexible by which this inverse approach can be implemented into various fields of engineering and mechanics. More importantly this approach is designed to offer an inexpensive way to accurately estimate material characteristics or properties using nondestructive techniques. While the POD-RBF inverse approach outlined in this thesis focuses primarily in application to conduction heat transfer, elasticity, and fracture mechanics, this technique is designed to be directly applicable to other realistic conditions and/or industries.

Parameter Estimation

Inverse Problem

Proper Orthogonal Decomposition

POD

Heat Transfer

Elasticity

Engineering

Mechanical Engineering

Application of Trained POD-RBF to Interpolation in Heat Transfer and Fluid Mechanics

Ashley, Rebecca A

01 January 2018

To accurately model or predict future operating conditions of a system in engineering or applied mechanics, it is necessary to understand its fundamental principles. These may be the material parameters, defining dimensional characteristics, or the boundary conditions. However, there are instances when there is little to no prior knowledge of the system properties or conditions, and consequently, the problem cannot be modeled accurately. It is therefore critical to define a method that can identify the desired characteristics of the current system without accumulating extensive computation time. This thesis formulates an inverse approach using proper orthogonal decomposition (POD) with an accompanying radial basis function (RBF) interpolation network. This method is capable of predicting the desired characteristics of a specimen even with little prior knowledge of the system. This thesis first develops a conductive heat transfer problem, and by using the truncated POD – RBF interpolation network, temperature values are predicted given a varying Biot number. Then, a simple bifurcation problem is modeled and solved for velocity profiles while changing the mass flow rate. This bifurcation problem provides the data and foundation for future research into the left ventricular assist device (LVAD) and implementation of POD – RBF. The trained POD – RBF inverse approach defined in this thesis can be implemented in several applications of engineering and mechanics. It provides model reduction, error filtration, regularization and an improvement over previous analysis utilizing computational fluid dynamics (CFD).

Proper Orthogonal Decomposition

Radial Basis Function

Parameter Estimation

Inverse Problem

Heat Transfer

Fluid Mechanics

Mechanical Engineering

Sequential Monte Carlo Parameter Estimation for Differential Equations

Arnold, Andrea

11 June 2014

No description available.

Applied Mathematics

Statistics

Sequential Monte Carlo

parameter estimation

linear multistep methods

particle filters

ensemble Kalman filters

Maximum Likelihood Estimation for Stochastic Differential Equations Using Sequential Kriging-Based Optimization

Schneider, Grant W.

January 2014

No description available.

Statistics

Discretely sampled diffusions

Expected improvement

Gaussian process

Sequential Monte Carlo

Parameter estimation

The Self-Optimizing Inverse Methodology for Material Parameter Identification and Distributed Damage Detection

Weaver, Josh

29 May 2015

No description available.

Civil Engineering

inverse parameter estimation

parallelization

Self-optim

ABAQUS

sensitivity analysis

stochastic

damage detection

Parameter Analysis in Models of Yeast Cell Polarization and Stem Cell Lineage

Renardy, Marissa

10 August 2018

No description available.

Mathematics

mathematical biology

computational biology

parameter estimation

sensitivity analysis

cell polarization

cell lineage

Matrix Pencil Method for Direction of Arrival Estimation with Uniform Circular Arrays

Statzer, Eric L.

23 September 2011

No description available.

Electrical Engineering

Direction of arrival estimation

Matrix pencil method

Signal processing

Signal parameter estimation

A GENERALIZED RESIDUALS MODEL FOR THE UNIFIED MATRIX POLYNOMIAL APPROACH TO FREQUENCY DOMAIN MODAL PARAMETER ESTIMATION

FLADUNG, JR., WILLIAM A.

11 October 2001

No description available.

Engineering, Mechanical

generalized residuals

frequency domain

modal parameter estimation

unified matrix polynomial approach

Stochastic Demand-hydraulic Model of Water Distribution Systems

Chen, Jinduan

19 October 2015

No description available.

Environmental Engineering

Water distribution system

Real-time hydraulic model

Water demand

Time series forecasting

Parameter estimation

Sparse Methods for Model Estimation with Applications to Radar Imaging

Austin, Christian David

19 June 2012

No description available.

Applied Mathematics

Electrical Engineering

Statistics

sparse reconstruction

parameter estimation

model order estimation

radar imaging

SAR