PWM-Based Predictive Direct Torque Control of Switched Reluctance Machine for Accurate Torque Tracking With Minimization of Phase RMS Currents

This paper proposes a novel PWM-based optimal predictive torque controller for Switched Reluctance Machines (SRMs). The highly non-linear characteristics of flux-linkage and phase torque present challenges in achieving real-time optimal torque control in SRMs. In this work, a cost function, encompas...

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Bibliographic Details
Published in:IEEE transactions on industry applications 2024-09, Vol.60 (5), p.6899-6912
Main Authors: Thirumalasetty, Mouli, Narayanan, G.
Format: Article
Language:English
Subjects:
Computational modeling
Control systems
Inductance
optimal control
Predictive control
pulse width modulation
Reluctance machines
Switches
Torque
Torque control
torque ripple
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Summary:This paper proposes a novel PWM-based optimal predictive torque controller for Switched Reluctance Machines (SRMs). The highly non-linear characteristics of flux-linkage and phase torque present challenges in achieving real-time optimal torque control in SRMs. In this work, a cost function, encompassing the instantaneous torque error and the RMS values of phase currents is formulated to be minimized. An analytical expression for the optimal duty ratio towards this objective is derived resulting in improved computational efficiency. The performance of the proposed torque controller is compared with two state-of-the-art finite control set predictive torque controllers through extensive simulations and experiments. The tests are conducted at various operating torque and speed levels on a 4-phase, 8/6 pole SRM. Results demonstrate that the proposed controller delivers better torque tracing performance in terms of lower average and RMS torque errors than the existing techniques. Also the proposed method results in higher torque per ampere, lower sound pressure levels (SPL emission), and lower computational time. The proposed controller tracks the torque accurately even in the presence of −20% to +20% modeling errors.
ISSN:0093-9994
1939-9367
DOI:10.1109/TIA.2024.3400174