Fractional Sensitivity Equation Method: Applications to Fractional Model Construction
For researchers working on fractional differential equation models, this provides a new method for sensitivity analysis and parameter estimation, but the contribution is incremental as it extends existing sensitivity analysis techniques to the fractional case.
The paper develops a fractional sensitivity equation method for sensitivity analysis and parameter estimation in fractional differential equation models, enabling accurate construction of fractional models from data.
Fractional differential equations provide a tractable mathematical framework to describe anomalous behavior in complex physical systems, yet they introduce new sensitive model parameters, i.e. derivative orders, in addition to model coefficients. We formulate a sensitivity analysis of fractional models by developing a fractional sensitivity equation method. We obtain the adjoint fractional sensitivity equations, in which we present a fractional operator associated with logarithmic-power law kernel. We further construct a gradient-based optimization algorithm to compute an accurate parameter estimation in fractional model construction. We develop a fast, stable, and convergent Petrov-Galerkin spectral method to numerically solve the coupled system of original fractional model and its corresponding adjoint fractional sensitivity equations.