Neural Fractional Differential Equations: Optimising the Order of the Fractional Derivative

Neural Fractional Differential Equations: Optimising the Order of the Fractional Derivative

Neural Fractional Differential Equations (Neural FDEs) represent a neural network architecture specifically designed to fit the solution of a fractional differential equation to given data. This architecture combines an analytical component, represented by a fractional derivative, with a neural netw...

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Bibliographic Details
Published in:Fractal and fractional Vol. 8; no. 9; p. 529
Main Authors: Coelho, Cecília, Costa, M. Fernanda P., Ferrás, Luís L.
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-09-2024
Subjects:
Approximation
Boundary value problems
Derivatives
Differential equations
Fractional calculus
fractional differential equations
Impact analysis
Neural networks
Numerical analysis
optimisation
Optimization
Ordinary differential equations
Process parameters
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Summary:Neural Fractional Differential Equations (Neural FDEs) represent a neural network architecture specifically designed to fit the solution of a fractional differential equation to given data. This architecture combines an analytical component, represented by a fractional derivative, with a neural network component, forming an initial value problem. During the learning process, both the order of the derivative and the parameters of the neural network must be optimised. In this work, we investigate the non-uniqueness of the optimal order of the derivative and its interaction with the neural network component. Based on our findings, we perform a numerical analysis to examine how different initialisations and values of the order of the derivative (in the optimisation process) impact its final optimal value. Results show that the neural network on the right-hand side of the Neural FDE struggles to adjust its parameters to fit the FDE to the data dynamics for any given order of the fractional derivative. Consequently, Neural FDEs do not require a unique α value; instead, they can use a wide range of α values to fit data. This flexibility is beneficial when fitting to given data is required and the underlying physics is not known.
ISSN:2504-3110
2504-3110
DOI:10.3390/fractalfract8090529