Title :
Parameter estimation in a tokamak transport model and application to L- and H-mode simulations
Author :
Qiang, Ji ; Singer, Clifford E.
Author_Institution :
Dept. of Nucl. Eng., Illinois Univ., Urbana, IL, USA
fDate :
8/1/1996 12:00:00 AM
Abstract :
A systematic parameter estimation method has been established and applied to estimating a priori uncertain multipliers of flux formulas in a gyro-Bohm tokamak transport model. Results from simulating two tokamak discharge profiles with the model calibrated here are shown. The method used here can deal with limited and relatively uncertain experimental data by using estimates of prior knowledge concerning the accuracy of the data. Confidence regions are given to assess the accuracy of estimators. The estimated multipliers are much larger than in a similar study using a nongyro-Bohm transport model suggesting that mechanisms, in addition to early estimates of E×B driven fluxes from resistive ballooning and quasi-linear drift/ηi turbulence, are needed for a complete theoretical model of flux surface-averaged transport in tokamaks
Keywords :
ballooning instability; plasma density; plasma instability; plasma simulation; plasma temperature; plasma toroidal confinement; plasma transport processes; plasma turbulence; E×B driven fluxes; H-mode simulations; L-mode simulations; a priori uncertain multipliers; confidence regions; flux formulas; flux surface-averaged transport; gyro-Bohm tokamak transport model; nongyro-Bohm transport model; parameter estimation method; quasi-linear drift turbulence; resistive ballooning; tokamak discharge profiles; tokamak transport model; tokamaks; Bayesian methods; Gaussian distribution; Kinetic theory; Magnetic flux; Maximum likelihood estimation; Parameter estimation; Plasma simulation; Probability distribution; Testing; Tokamaks;
Journal_Title :
Plasma Science, IEEE Transactions on
