Inverse design for hyperbolic conservation laws is exemplified through the 1D Burgers equation which is motivated by aircraft's sonic-boom minimization issues. In particular, we prove that, as soon as the target function (usually a N-wave) isn't continuous, there is a whole convex set of possible initial data, the backward entropy solution being possibly its centroid. Further, an iterative strategy based on a gradient algorithm involving "reversible solutions" solving the linear adjoint problem is set up. In order to be able to recover initial profiles different from the backward entropy solution, a filtering step of the backward adjoint solutoin is inserted, mostly relying on scale-limited (wavelet) subspaces. Numerical illustrations, along with profiles similar to F-functions, are presented.
Filtered Gradient Algorithms for Inverse Design Problems of One-Dimensional Burgers Equation
2017
Abstract
Inverse design for hyperbolic conservation laws is exemplified through the 1D Burgers equation which is motivated by aircraft's sonic-boom minimization issues. In particular, we prove that, as soon as the target function (usually a N-wave) isn't continuous, there is a whole convex set of possible initial data, the backward entropy solution being possibly its centroid. Further, an iterative strategy based on a gradient algorithm involving "reversible solutions" solving the linear adjoint problem is set up. In order to be able to recover initial profiles different from the backward entropy solution, a filtering step of the backward adjoint solutoin is inserted, mostly relying on scale-limited (wavelet) subspaces. Numerical illustrations, along with profiles similar to F-functions, are presented.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
