中文

Sparse space-time spectral methods can time-step by peel and pass

数值分析 2026-07-07 v1

摘要

Global space-time spectral methods give spectral accuracy in time but typically require the whole space-time history to be resolved and stored on a single tensor-product domain T×ΩT \times \Omega. We record that in an endpoint-benign Legendre or Chebyshev-TT time basis, whose polynomials all equal one at the right endpoint, the final time slice of a space-time block is recovered exactly by summing the stored coefficients along the time index. This peel-and-pass step is a special case of a Jacobi endpoint identity, which also gives derivative formulae for higher-order equations. Writing such higher-order equations as first-order systems preserves the benign value-passing structure. The result is a sparse space-time spectral element method that advances block by block, stores only one block, and needs far fewer time coefficients per solve for long-time problems. We prove the identities, give resident-memory, solve-cost and error-propagation models, and demonstrate the method on (1+1)(1{+}1)D heat, wave and Klein--Gordon equations, and on (2+1)(2{+}1)D fractional heat on the disk with weighted Zernike polynomials in space.

引用

@article{arxiv.2607.06449,
  title  = {Sparse space-time spectral methods can time-step by peel and pass},
  author = {Timon S. Gutleb},
  journal= {arXiv preprint arXiv:2607.06449},
  year   = {2026}
}

备注

24 pages, 10 figures