A contour method for time-fractional PDEs and an application to fractional viscoelastic beam equations

Abstract: We develop a rapid and accurate contour method for the solution of time-fractional PDEs. The method inverts the Laplace transform via an optimised stable quadrature rule, suitable for infinitedimensional operators, whose error decreases like exp(−cN/ log(N )) for N quadrature points. The method is parallisable, avoids having to resolve singularities of the solution as t ↓ 0, and avoids the large memory consumption that can be a challenge for time-stepping methods applied to time-fractional PDEs. The ODEs resul… Show more

“…For the computation of general semigroups with error control using rectangular truncations, we refer the reader to [27,29]. Related to the method we adopt here, many works use contour methods to invert the Laplace transform and solve time evolution problems, with a focus on parabolic PDEs [39,48,49,74,77,94,108,109].…”

Computing spectral properties of topological insulators without artificial truncation or supercell approximation

“…For the computation of general semigroups with error control using rectangular truncations, we refer the reader to [27,29]. Related to the method we adopt here, many works use contour methods to invert the Laplace transform and solve time evolution problems, with a focus on parabolic PDEs [39,48,49,74,77,94,108,109].…”

Computing spectral properties of topological insulators without artificial truncation or supercell approximation