
doi: 10.3390/math9090918
A computational framework for the construction of solutions to linear homogenous partial differential equations (PDEs) with variable coefficients is developed in this paper. The considered class of PDEs reads: ∂p∂t−∑j=0m∑r=0njajrtxr∂jp∂xj=0 F-operators are introduced and used to transform the original PDE into the image PDE. Factorization of the solution into rational and exponential parts enables us to construct analytic solutions without direct integrations. A number of computational examples are used to demonstrate the efficiency of the proposed scheme.
linear PDE with variable coefficients, partial differential equation, Fourier transform, QA1-939, Mathematics, operator calculus
linear PDE with variable coefficients, partial differential equation, Fourier transform, QA1-939, Mathematics, operator calculus
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