Error Analysis for a Fractional-Derivative Parabolic Problem on Quasi-Graded Meshes using Barrier Functions

Abstract: An initial-boundary value problem with a Caputo time derivative of fractional order α ∈ (0, 1) is considered, solutions of which typically exhibit a singular behaviour at an initial time. For this problem, we give a simple and general numerical-stability analysis using barrier functions, which yields sharp pointwise-in-time error bounds on quasi-graded temporal meshes with arbitrary degree of grading. L1-type and Alikhanov-type discretization in time are considered. In particular, those results imply that mild… Show more

“…1 & 2. For R 0 , the errors on the adaptive meshes were compared with the errors on the optimal graded meshes {t j = T (j/M ) r } M j=0 with r = (2 − α)/α [3,5,9] for the same values of M . We observe that in both cases the optimal global rates of convergence 2−α are attained.…”

“…For the second bound in (2.3a), set E 1 (t) := max{τ, t} α−1 for t > 0 with E 1 (0) := 0 (a similar barrier was used in [3, Appendix A], [5,Lemma 2.3]). Now it suffices to check that…”

Pointwise-in-time a posteriori error control for time-fractional parabolic equations

“…1 & 2. For R 0 , the errors on the adaptive meshes were compared with the errors on the optimal graded meshes {t j = T (j/M ) r } M j=0 with r = (2 − α)/α [3,5,9] for the same values of M . We observe that in both cases the optimal global rates of convergence 2−α are attained.…”

“…For the second bound in (2.3a), set E 1 (t) := max{τ, t} α−1 for t > 0 with E 1 (0) := 0 (a similar barrier was used in [3, Appendix A], [5,Lemma 2.3]). Now it suffices to check that…”

Pointwise-in-time a posteriori error control for time-fractional parabolic equations

“…By calculation, C 0 D α t+t1 w(t + t 1 ) = g(w(t + t 1 )). Hence, w(t + t 1 , w 0 ) is a solution of system (9). Further, w(t + t 1 , w 0 )| t=0 = w(t 1 , w 0 ) = w 1 .…”

“…We consider system (7) with two-group case, which is suitable for infectious diseases transmitted between two cities or communities. Furthermore, system (7) with two groups (n = 2) can be calculated by the central difference method in L 1 -type space and Alikhanov-type discretization in time [9]. Furthermore, we consider the following incidence rate as an example:…”

Global dynamics for a class of reaction–diffusion multigroup SIR epidemic models with time fractional-order derivatives

“…Chen-Stynes [2] prove the second-order convergence of the L2-1 σ scheme on fitted meshes combining the graded meshes and quasiuniform meshes. Kopteva-Meng [10] provide sharp pointwise-in-time error bounds for quasi-graded termporal meshes with arbitrary degree of grading for the L1 and L2-1 σ schemes. Later Kopteva generalize this sharp pointwise error analysis to an L2-type scheme on quasi-graded meshes [9].…”

On stability and convergence of L2-1$_σ$ method on general nonuniform meshes for subdiffusion equation