TY - GEN
T1 - Direct model predictive current control for matrix converters
AU - Saha, Jaydeep
AU - Ayad, Ayman
AU - Kennel, Ralph
N1 - Publisher Copyright:
© 2017 IEEE.
PY - 2017/6/13
Y1 - 2017/6/13
N2 - This paper proposes a direct model predictive current control (MPC) strategy for matrix converters (MCs). The proposed method aims to regulate the output current of the MC while minimizing the input reactive power at the same time. In addition, in order to reduce the switching losses, the MPC adjusts the average switching frequency of the converter. The MPC scheme uses the discrete-Time model of the MC to predict the future trajectories of the controlled variables of concern. Then, a cost function is formulated to include all the control objectives, i.e. The output current, input reactive power, and switching frequency. Subject to the system dynamics, the cost function is minimized in order to find the optimal control action that can be applied to the converter at the next time-step. In order to examine the proposed control strategy with the MC, simulations based on MATLAB/Simulink are conducted. The simulation results show the effectiveness of the proposed scheme in steady-state and transient operations. The results show that the proposed MPC strategy offers a very good steady-state behavior as well as very fast dynamic responses during transients. Moreover, the switching frequency can be highly reduced which in turn results in low switching losses.
AB - This paper proposes a direct model predictive current control (MPC) strategy for matrix converters (MCs). The proposed method aims to regulate the output current of the MC while minimizing the input reactive power at the same time. In addition, in order to reduce the switching losses, the MPC adjusts the average switching frequency of the converter. The MPC scheme uses the discrete-Time model of the MC to predict the future trajectories of the controlled variables of concern. Then, a cost function is formulated to include all the control objectives, i.e. The output current, input reactive power, and switching frequency. Subject to the system dynamics, the cost function is minimized in order to find the optimal control action that can be applied to the converter at the next time-step. In order to examine the proposed control strategy with the MC, simulations based on MATLAB/Simulink are conducted. The simulation results show the effectiveness of the proposed scheme in steady-state and transient operations. The results show that the proposed MPC strategy offers a very good steady-state behavior as well as very fast dynamic responses during transients. Moreover, the switching frequency can be highly reduced which in turn results in low switching losses.
KW - Current Control
KW - Matrix Converters
KW - Model Predictive Control
KW - Optimisation
KW - Total Harmonic Distortion
UR - http://www.scopus.com/inward/record.url?scp=85022068264&partnerID=8YFLogxK
U2 - 10.1109/ICNTE.2017.7947966
DO - 10.1109/ICNTE.2017.7947966
M3 - Conference contribution
AN - SCOPUS:85022068264
T3 - 2017 International Conference on Nascent Technologies in Engineering, ICNTE 2017 - Proceedings
BT - 2017 International Conference on Nascent Technologies in Engineering, ICNTE 2017 - Proceedings
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2017 International Conference on Nascent Technologies in Engineering, ICNTE 2017
Y2 - 27 January 2017 through 28 January 2017
ER -