情報数理科学専攻

LIU XUEFENG

  (劉 雪峰)

Profile Information

Affiliation
Professor, Department of Information and Sciences, Tokyo Woman's Christian University
Degree
Bachelor(Jul, 2003, University of Science and Technology of China)
Master (Mathematical science)(Mar, 2006, The University of Tokyo)
Doctor (Mathematical science)(Mar, 2009, The University of Tokyo)

Researcher number
50571220
ORCID ID
 https://orcid.org/0000-0003-4546-1620
J-GLOBAL ID
200901049358442703
researchmap Member ID
6000019908

External link

My current research is on the finite element method, especially its application in the eigenvalue bounds for various differential operators.

Papers

 30
  • Taiga Nakano, Qin Li, Meiling Yue, Xuefeng Liu
    Computational Methods in Applied Mathematics, Apr 1, 2024  
  • Ryoki Endo, Xuefeng Liu
    Journal of Differential Equations, 376 750-772, Dec, 2023  Peer-reviewedLast authorCorresponding author
  • Xuefeng Liu, Tomáš Vejchodský
    Journal of Computational and Applied Mathematics, 429, Sep, 2023  Peer-reviewed
    For conforming finite element approximations of the Laplacian eigenfunctions, a fully computable guaranteed error bound in the L2 norm sense is proposed. The bound is based on the a priori error estimate for the Galerkin projection of the conforming finite element method, and has an optimal speed of convergence for the eigenfunctions with the worst regularity. The resulting error estimate bounds the distance of spaces of exact and approximate eigenfunctions and, hence, is robust even in the case of multiple and tightly clustered eigenvalues. The accuracy of the proposed bound is illustrated by numerical examples.
  • Taiga Nakano, Xuefeng Liu
    Journal of Computational and Applied Mathematics, 425, Jun, 2023  Peer-reviewed
    This paper considers the finite element solution of the boundary value problem of Poisson's equation and proposes a guaranteed local error estimation based on the hypercircle method. Compared to the existing literature on qualitative error estimation, the proposed error estimation provides an explicit and sharp bound for the approximation error in the subdomain of interest, and its efficiency can be enhanced by further utilizing a non-uniform mesh. Such a result is applicable to problems without H2-regularity, since it only utilizes the first order derivative of the solution. The efficiency of the proposed method is demonstrated by numerical experiments for both convex and non-convex 2D domains with uniform or non-uniform meshes.
  • Xuefeng Liu, Tomáš Vejchodský
    Numerische Mathematik, 152(1) 183-221, Sep, 2022  Peer-reviewed
    For compact self-adjoint operators in Hilbert spaces, two algorithms are proposed to provide fully computable a posteriori error estimate for eigenfunction approximation. Both algorithms apply well to the case of tight clusters and multiple eigenvalues, under the settings of target eigenvalue problems. Algorithm I is based on the Rayleigh quotient and the min-max principle that characterizes the eigenvalue problems. The formula for the error estimate provided by Algorithm I is easy to compute and applies to problems with limited information of Rayleigh quotients. Algorithm II, as an extension of the Davis–Kahan method, takes advantage of the dual formulation of differential operators along with the Prager–Synge technique and provides greatly improved accuracy of the estimate, especially for the finite element approximations of eigenfunctions. Numerical examples of eigenvalue problems of matrices and the Laplace operators over convex and non-convex domains illustrate the efficiency of the proposed algorithms.

Books and Other Publications

 3

Teaching Experience

 24

Professional Memberships

 2

Research Projects

 17

Other

 1