A novel quasilinear turbulent transport model DeKANIS has been constructed founded on the gyrokinetic analysis of JT-60U plasmas. DeKANIS predicts particle and heat fluxes fast with a neural network (NN) based approach and distinguishes diffusive and non-diffusive transport processes. The original model only considered particle transport, but its capability has been extended to cover multi-channel turbulent transport. To solve a set of particle and heat transport equations stably in integrated codes with DeKANIS, the NN model embedded in DeKANIS has been modified. DeKANIS originally determined turbulent saturation levels semi-empirically based on JT-60U experimental data, but now it can also estimate them using a theory-based saturation rul...
In fusion devices such as tokamaks, the achievement of good energy confinement is a key issue. The e...
Fusion performance in tokamaks depends on the core and edge regions as well as on their nonlinear fe...
The RAPTOR code is a control-oriented core plasma profile simulator with various applications in con...
The gyrokinetic-based turbulent transport models are essential to predict density and temperature pr...
Novel turbulent particle transport modelling has been proposed following joint analyses with gyrokin...
A quasilinear particle flux is modelled based on gyrokinetic calculations. The particle flux is esti...
We present an ultrafast neural network model, QLKNN, which predicts core tokamak transport heat and ...
17 pages, 11 figures, Physics of Plasmas, ICDDPS 2019 conference paperWe present an ultrafast neural...
A real-time capable core turbulence tokamak transport model is developed. This model is constructed ...
A fast and accurate turbulence transport model based on quasilinear gyrokinetics is developed. The m...
Within integrated tokamak plasma modeling, turbulent transport codes are typically the computational...
International audienceA real-time capable core turbulence tokamak transport model is ă developed. Th...
In fusion devices such as tokamaks, the achievement of good energy confinement is a key issue. The e...
Fusion performance in tokamaks depends on the core and edge regions as well as on their nonlinear fe...
The RAPTOR code is a control-oriented core plasma profile simulator with various applications in con...
The gyrokinetic-based turbulent transport models are essential to predict density and temperature pr...
Novel turbulent particle transport modelling has been proposed following joint analyses with gyrokin...
A quasilinear particle flux is modelled based on gyrokinetic calculations. The particle flux is esti...
We present an ultrafast neural network model, QLKNN, which predicts core tokamak transport heat and ...
17 pages, 11 figures, Physics of Plasmas, ICDDPS 2019 conference paperWe present an ultrafast neural...
A real-time capable core turbulence tokamak transport model is developed. This model is constructed ...
A fast and accurate turbulence transport model based on quasilinear gyrokinetics is developed. The m...
Within integrated tokamak plasma modeling, turbulent transport codes are typically the computational...
International audienceA real-time capable core turbulence tokamak transport model is ă developed. Th...
In fusion devices such as tokamaks, the achievement of good energy confinement is a key issue. The e...
Fusion performance in tokamaks depends on the core and edge regions as well as on their nonlinear fe...
The RAPTOR code is a control-oriented core plasma profile simulator with various applications in con...