Construction of Neoclassical Transport Database for Large Helical Device Plasma Applying Neural Network Method
スポンサーリンク
概要
- 論文の詳細を見る
A neoclassical transport database for the large helical device (LHD) plasma, DCOM/NNW, is constructed using the neural network method. Monoenergetic neoclassical transport coefficients evaluated by the Monte Carlo code, DCOM, are used as training data of the neural network. The databases for two typical magnetic field configurations in LHD, namely, standard and inward-shifted configurations, are constructed and transport coefficients for thermal plasma are evaluated. The plasma parameter dependencies and the ambipolar radial electric field are investigated.
- Published by the Japan Society of Applied Physics through the Institute of Pure and Applied Physicsの論文
- 2007-03-15
著者
-
MURAKAMI Sadayoshi
Department of Nuclear Engineering, Kyoto University
-
Wakasa Arimitsu
Graduate School Of Engineering Hokkaido University
-
Itagaki Masafumi
Graduate School Of Engineering Hokkaido University
-
Oikawa Shun-ichi
Graduate School Of Engineering Hokkaido Univ. Sapporo 060-8628 Jpn
-
Murakami Sadayoshi
Department of Nuclear Engineering, Kyoto University, Kyoto 606-8501, Japan
-
Itagaki Masafumi
Graduate School of Engineering, Hokkaido University, Sapporo 060-8628, Japan
-
Wakasa Arimitsu
Graduate School of Engineering, Hokkaido University, Sapporo 060-8628, Japan
関連論文
- Construction of Neoclassical Transport Database for Large Helical Device Plasma Applying Neural Network Method
- Monte Carlo Study Based on a Real Coordinate System for Tangentially Injected High-Energy Particles in the Large Helical Device
- LHD周辺プラズマの理論モデル
- Field line and Particle orbit Analysis in the Periphery of the Large Helical Device
- Application of Algebraic Approximation to Three Dimensional Multibody Coulomb Problem: Implementation of GPGPU
- Preliminary Study of Uncertainty-Driven Plasma Diffusion II
- Algebraic Analysis Approach for Multibody Problems II
- Effect of Halo Neutrals on Fast-Ion Charge Exchange Spectroscopy Measurements in LHD
- Turbulence Response in the High Ti Discharge of the LHD
- Electrostatic Potential Measurement by Using 6-MeV Heavy Ion Beam Probe on LHD
- Electron Heat Transport Analysis of Low-Collisionality Plasmas in the Neoclassical-Transport-Optimized Configuration of LHD
- A Novel Boundary Element Method for Nonuniform Neutron Diffusion Problems
- Particle Transport and Fluctuation Characteristics around the Neoclassically Optimized Configuration in LHD
- Configuration Effects on Local Transport in High-Beta LHD Plasmas
- Memorial-Index-Based Inverse Kinetics Method for Continuous Measurement of Reactivity and Source Strength
- Particle Orbit Analysis in the Finite Beta Plasma of the Large Helical Device using Real Coordinates
- Quantum Mechanical Plasma Scattering
- Preliminary Study of Uncertainty-Driven Plasma Diffusion
- Algebraic Analysis Approach for Multibody Problems
- Binary Interaction Approximation to N-Body Problems
- Evaluation of Fast-Ion Confinement Using a Radially Injected Neutral Beam in the LHD
- Monte-Carlo Study Based on Real Coordinates for Perpendicularly Injected High-Energy Ions in the LHD High-Beta Plasma
- Development of Integrated Transport Code, TASK3D, and Its Applications to LHD Experiment
- Construction of Neoclassical Transport Database for Large Helical Device Plasma Applying Neural Network Method
- Formation of Electron-Root Radial Electric Field and its Effect on Thermal Transport in LHD High Te Plasma
- Density Regimes of Complete Detachment and Serpens Mode in LHD
- Effect of Ellipticity on Thermal Transport in ECH Plasmas in LHD
- Study of Neoclassical Transport in LHD Plasmas by Applying the DCOM/NNW Neoclassical Transport Database
- Measurements of Micro-Turbulence in High Beta and High Density Regimes of LHD and Comparison with Resistive G-Mode Scaling
- Effectiveness of GPGPU for Solving the Magnetohydrodynamics Equations Using the CIP-MOCCT Method
- Neoclassical Transport Properties in High-Ion-Temperature Hydrogen Plasmas in the Large Helical Device (LHD)
- Simulation Study of ECCD in Helical Plasmas