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Monic Chebyshev pseudospectral differentiation matrices for higher-order IVPs and BVPs: applications to certain types of real-life problems

M. Abdelhakem, Abd El-Latif S. Ahmed, Dumitru Bǎleanu, M. El-Kady

2022Computational and Applied Mathematics29 citationsDOIOpen Access PDF

Abstract

Abstract We introduce new differentiation matrices based on the pseudospectral collocation method. Monic Chebyshev polynomials (MCPs) were used as trial functions in differentiation matrices (D-matrices). Those matrices have been used to approximate the solutions of higher-order ordinary differential equations (H-ODEs). Two techniques will be used in this work. The first technique is a direct approximation of the H-ODE. While the second technique depends on transforming the H-ODE into a system of lower order ODEs. We discuss the error analysis of these D-matrices in-depth. Also, the approximation and truncation error convergence have been presented to improve the error analysis. Some numerical test functions and examples are illustrated to show the constructed D-matrices’ efficiency and accuracy.

Topics & Concepts

OdeMonic polynomialOrdinary differential equationCollocation (remote sensing)MathematicsTruncation (statistics)Chebyshev polynomialsApplied mathematicsTruncation errorChebyshev filterChebyshev equationConvergence (economics)Matrix (chemical analysis)Differential equationMathematical analysisPolynomialComputer scienceOrthogonal polynomialsMachine learningStatisticsMaterials scienceEconomic growthComposite materialClassical orthogonal polynomialsEconomicsMatrix Theory and AlgorithmsNumerical methods for differential equationsFractional Differential Equations Solutions
Monic Chebyshev pseudospectral differentiation matrices for higher-order IVPs and BVPs: applications to certain types of real-life problems | Litcius