Abstract
This work considers the estimation of internal volumetric heat generation, as well as the heat capacity of a solid spherical sample, heated by a homogeneous, time-varying electromagnetic field. To that end, the numerical strategy solves the corresponding inverse problem. Three functional forms (linear, sinusoidal, and exponential) for the electromagnetic field were considered. White Gaussian noise was incorporated into the theoretical temperature profile (i.e. the solution of the direct problem) to simulate a more realistic situation. Temperature was pretended to be read through four sensors. The inverse problem was solved through three different kinds of approach: using a traditional optimizer, using modern techniques, and using a mixture of both. In the first case, we used a traditional, deterministic Levenberg-Marquardt (LM) algorithm. In the second one, we considered three stochastic algorithms: Spiral Optimization Algorithm (SOA), Vortex Search (VS), and Weighted Attraction Method (WAM). In the final case, we proposed a hybrid between LM and the metaheuristics algorithms. Results show that LM converges to the expected solutions only if the initial conditions (IC) are within a limited range. Oppositely, metaheuristics converge in a wide range of IC but exhibit low accuracy. The hybrid approaches converge and improve the accuracy obtained with the metaheuristics. The difference between expected and obtained values, as well as the RMS errors, are reported and compared for all three methods.
Highlights
Real-time measurement of parameters within an electromagnetic field, such as internal heat generation or heat capacity, is technically unfeasible
The objective function (OF) that provides the minimum variance in an inverse problem is the ordinary least squares (OLS) norm
This article described the estimation of the internal volumetric heat generation and the heat calorific capacity parameters during microwave heating of a solid spherical sample
Summary
Real-time measurement of parameters within an electromagnetic field, such as internal heat generation or heat capacity, is technically unfeasible To overcome this situation, those parameters can be estimated by solving the corresponding inverse problem. To estimate the time-dependent heat generation at the interface of cylindrical bars during the rotary friction welding process, they used an inverse algorithm based on the conjugate gradient method and the discrepancy principle. Dealing with a heat conduction process, Wang et al (Wang & Liu, 2016) estimated thermal conductivity using a nonlinear parabolic equation with a temperature-dependent source They solved the inverse problem using an iterative optimization algorithm. Mohebbi et al ( 2016), using the conventional conjugate gradient method and the two-dimensional inverse heat conduction problem, estimated thermal conductivity, heat transfer coefficient, and heat flux in irregular bodies. Giraldo et al (2012) used the inverse problem in order to estimate neural activity from electroencephalographic signals
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