Extended Group Finite Element Method for a port‐Hamiltonian Formulation of the Non‐Isothermal Euler Equations

Authors

Sarah-Alexa Hauschild, Nicole Marheineke

Abstract

This paper deals with a port‐Hamiltonian (pH) formulation of the non‐isothermal compressible Euler equations for a pipe flow. In the pH‐framework physical properties, like mass conservation and energy dissipation, are encoded in the system structure. Applying a structure‐preserving Galerkin approximation with mixed finite elements in space yields a nonlinear system with state‐dependent matrices. Assembly of these matrices in each time step is computationally expensive and makes model reduction inefficient, since the nonlinearities still depend on the full order state. We investigate the use of the extended group finite element method (EGFEM) to efficiently handle pH structure‐preservation. EGFEM separates the systems matrices into products of a state‐independent (precomputable) tensor and a state‐dependent vector for the nonlinearities, making the system easily accessible for complexity reduction.

Citation

• Journal: PAMM
• Year: 2021
• Volume: 21
• Issue: 1
• Pages:
• Publisher: Wiley
• DOI: 10.1002/pamm.202100032

BibTeX

@article{Hauschild_2021,
  title={{Extended Group Finite Element Method for a port‐Hamiltonian Formulation of the Non‐Isothermal Euler Equations}},
  volume={21},
  ISSN={1617-7061},
  DOI={10.1002/pamm.202100032},
  number={1},
  journal={PAMM},
  publisher={Wiley},
  author={Hauschild, Sarah-Alexa and Marheineke, Nicole},
  year={2021}
}

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References

• Hauschild, S.-A. & Marheineke, N. Structure‐preserving discretization of a port‐Hamiltonian formulation of the non‐isothermal Euler equations. Proc Appl Math and Mech 20, (2021) – 10.1002/pamm.202000014