Graduate School of Science and Engineering Science of Environment and Mathematical Modeling
- Course Outline
- Earth System Science / Environmental Magnetism Laboratory
- Geo-environmental Science Laboratory
- Wild Life Preservation Laboratory
- Advanced Materials Science and Process Systems Laboratory
- New Energy System Laboratory
- Environmental Systems Engineering Laboratory
- Regional Environment Laboratory
- Geometry Laboratory
- Functional Equations Laboratory
- Statistical Finance Laboratory
- Computational Mathematics Laboratory
- Laboratory of Mathematics for Information
- Discrete Mathematics Laboratory
- Analysis Laboratory
Analysis Laboratory
Staff
TAKEI Yoshitsugu
[Professor]
| Acceptable course | |
|---|---|
| Master's degree course | ✓ |
| Doctoral degree course | ✓ |
Telephone : +81-774-65-6653
ytakei@mail.doshisha.ac.jp
Office : HS-310
Database of Researchers
Research Topics
- Algebraic analysis of singular perturbation theory
- Exact WKB analysis of differential equations
Research Contents
The main subject of my research is algebraic analysis of singular perturbation theory, in particular, the exact WKB
analysis of linear differential equations and nonlinear differential equations.
It is well known that a one-dimensional Schrödinger equation containing Planck's constant as a small parameter has
asymptotic formal solutions called WKB solutions. In the exact WKB analysis we give an analytic meaning to WKB
solutions through the Borel resummation method. Using the exact WKB analysis, we can analyze the global behavior of
solutions in a very explicit manner. For example, together with T. Kawai (RIMS, Kyoto Univ.) and T. Aoki (Kindai
Univ.) I have succeeded in providing a recipe for computing the monodromy group of Fuchsian equations, i.e., second
order ordinary differential equations with regular singularities, in terms of the Borel sum of WKB solutions.
Recently I have been studying higher order equations and systems of differential equations from the viewpoint of the
exact WKB analysis.
My research interest lies also in the analysis of nonlinear differential equations and difference equations. As a
matter of fact, the exact WKB analysis gives a powerful tool for the global analysis of Painlevé equations, typical
second order nonlinear ordinary differential equations that have close relationship with the soliton-type partial
differential equations (i.e., the so-called integrable systems), and their discrete analogues. I am now trying to
establish the fundamental theory of the exact WKB analysis for Painlevé equations and discrete Painlevé equations.
Keywords
- Differential equations
- Exact WKB analysis
- Theory of resurgent functions
- Painlevé equations