Title :
Multistep Finite Control Set Model Predictive Control for Power Electronics
Author :
Geyer, Tobias ; Quevedo, D.E.
Author_Institution :
ABB Corp. Res., Baden-Dättwil, Switzerland
Abstract :
For direct model predictive control with reference tracking of the converter current, we derive an efficient optimization algorithm that allows us to solve the control problem for very long prediction horizons. This is achieved by adapting sphere decoding principles to the underlying optimization problem. The proposed algorithm requires only few computations and directly provides the optimal switch positions. Since the computational burden of our algorithm is effectively independent of the number of converter output levels, the concept is particularly suitable for multilevel topologies with a large number of voltage levels. Our method is illustrated for the case of a variable speed drive system with a three-level voltage source converter.
Keywords :
electric current control; optimisation; power convertors; power electronics; predictive control; switches; variable speed drives; converter current reference tracking; direct model predictive control; multilevel topologies; multistep finite control set model predictive control; optimal switch positions; optimization algorithm; power electronics; sphere decoding principles; three-level voltage source converter; variable speed drive system; voltage levels; Inverters; Optimization; Prediction algorithms; Rotors; Stators; Switches; Branch and bound; drive systems; finite control set; model predictive control (MPC); power electronics; quantization; sphere decoding;
Journal_Title :
Power Electronics, IEEE Transactions on
DOI :
10.1109/TPEL.2014.2306939
