H
Hadi Y. Kanaan
Researcher at Saint Joseph's University
Publications - 248
Citations - 3539
Hadi Y. Kanaan is an academic researcher from Saint Joseph's University. The author has contributed to research in topics: Power factor & AC power. The author has an hindex of 26, co-authored 232 publications receiving 3041 citations. Previous affiliations of Hadi Y. Kanaan include Saint Joseph University & École Normale Supérieure.
Papers
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Sliding-Mode Robot Control With Exponential Reaching Law
TL;DR: A novel approach is proposed, which allows chattering reduction on control input while keeping high tracking performance of the controller in steady-state regime by designing a nonlinear reaching law by using an exponential function that dynamically adapts to the variations of the controlled system.
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Real-Time Implementation of Model-Predictive Control on Seven-Level Packed U-Cell Inverter
TL;DR: The dynamic performance of the controller during sudden changes in dc capacitor voltage, supply current, and PF demonstrates the fast and accurate response and the superior operation of the proposed controller.
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Design and Implementation of Space Vector Modulation-Based Sliding Mode Control for Grid-Connected 3L-NPC Inverter
TL;DR: The performance of the proposed hybrid controller to inject a desired active/reactive power to the grid is investigated through external perturbations such as change in the line current amplitude/phase shift, ac voltage fluctuation, as well as dc voltage variation.
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Sliding Mode Fixed Frequency Current Controller Design for Grid-Connected NPC Inverter
TL;DR: In this article, a fixed-frequency pulsewidth modulation (PWM) based on sliding-mode current controller is designed and applied to a utility interface three-phase/wire/level neutral-point-clamped inverter.
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Vienna Rectifier With Power Quality Added Function
TL;DR: Experimental results obtained with a digital-signal-processor-based DS1103 controller and the converter operating at a 20-kHz switching frequency proved the effectiveness of the theoretical study and the high performance of the proposed control strategy in compensating load harmonics and limited reactive power.