A backward problem for the time-fractional pseudo-parabolic equation with a variable coefficient
This work addresses an inverse reconstruction problem in mathematical modeling, but it is incremental as it applies known regularization methods to a specific fractional equation.
The paper tackles the inverse problem of recovering an unknown initial state from final-time observations for a time-fractional pseudo-parabolic equation with a variable coefficient, achieving theoretical existence and uniqueness results and validating the approach with numerical simulations that test resilience to perturbations.
This work addresses an inverse reconstruction task for a time-fractional pseudo-parabolic model with a temporally varying coefficient. By imposing Dirichlet boundary conditions, we aim to recover the unknown initial state from observations collected at the final time. From a theoretical perspective, we derive existence and uniqueness results by proving that, under suitable hypotheses, the problem admits a unique solution. Computationally, we introduce a finite-difference discretisation based on a time-stepping strategy and provide a detailed stability and convergence analysis. Leveraging the resulting forward solver, we then formulate an initial-data identification procedure using Tikhonov regularisation. The proposed approach is validated with numerical simulations, and its resilience is assessed via experiments that incorporate perturbations in the final-time measurements.