Multisensor methods to estimate thermal diffusivity

Author

Henderson, Thomas C. ; Knight, Gwen ; Grant, Edward

Author_Institution

Sch. of Comput., Univ. of Utah, Salt Lake City, UT, USA

fYear

2012

fDate

13-15 Sept. 2012

Firstpage

313

Lastpage

317

Abstract

Several methods for the estimation of thermal diffusivity are studied in this work. In many application scenarios, the thermal diffusivity is unknown and must be estimated in order to perform other estimation functions (e.g., tracking of the physical phenomenon, or solving other inverse problems like localization or sensor variance, etc.). In particular, we describe: 1) The use of minimization methods (the Golden Mean and Lagarias´ simplex) to determine the thermal diffusivity coefficient which when used in a forward heat flow simulation results in the least (vector) distance between the sampled data and the simulated data. 2) The Maximum Likelihood Estimate for thermal diffusivity. 3) The Extended Kalman Filter to recover the thermal diffusivity. We apply these methods to the determination of thermal diffusivity in snow.

Keywords

Kalman filters; heat transfer; inverse problems; maximum likelihood estimation; minimisation; sensor fusion; temperature measurement; thermal diffusivity; extended Kalman filter; forward heat flow simulation; inverse problem; maximum likelihood estimation; minimization method; multisensor method; thermal diffusivity coefficient; thermal diffusivity estimation; Bayesian methods; Computational modeling; Estimation; Heating; Temperature measurement; Thermal noise; Uncertainty;

fLanguage

English

Publisher

ieee

Conference_Titel

Multisensor Fusion and Integration for Intelligent Systems (MFI), 2012 IEEE Conference on

Conference_Location

Hamburg

Print_ISBN

978-1-4673-2510-3

Electronic_ISBN

978-1-4673-2511-0

Type

conf

DOI

10.1109/MFI.2012.6343037

Filename

6343037