A data-driven model reduction approach for backward fractional diffusion-wave equations
For researchers working on inverse problems for fractional diffusion-wave equations, this provides a more efficient computational method.
The paper proposes a data-driven model reduction approach for backward fractional diffusion-wave equations, showing that model reduction for an observation system also works for the forward problem, improving inverse problem efficiency. Numerical examples support the findings.
In this work, we propose an observation system based on the available data which solution is one-be-one mapping to the forward problem(with the unknown initial function) solution. It implies their solutions share the same linear structure in the finite dimensional space. Theoretical results show model reduction approaches constructed for the observation system also work well for the forward problem, which significantly improve the efficiency of solving the inverse problem. Several numerical examples are presented to support our finding.