Finite set model predictive control to a shunt multilevel active filter

Molina, Hernaldo Saldías; Rojas, Juan Dixon; Tamayo, Luis Morán

doi:10.1108/compel-03-2013-0087

Cited by 5 publications

(1 citation statement)

References 27 publications

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“…A hybrid active power filter using a proportional-resonant controller has been developed to suppress the selected harmonics and compensate for the reactive power (Rahim et al , 2013). Because of the improvement of microprocessor speed, MPC has been introduced as an inverter control scheme (Malinowski et al , 2010; Maalandish et al , 2018; Saldías Molina et al , 2015; Alejandro et al , 2016).…”

Section: Introductionmentioning

confidence: 99%

Multi-constraints based predictive current control of simplified neutral point clamped inverter

Tariquzzaman

Habibullah

Podder

2021

WJE

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Purpose Maintaining a balanced neutral point, reducing power loss, execution time are important criteria for the controlling of neutral point clamped (NPC) inverter. However, it is tough to meet all the challenges and also supplying the load current within the harmonic limit. This paper aims to maintain load current quality within the Institute of Electrical and Electronics Engineers 519 standard and meet the above-mentioned challenges. Design/methodology/approach The output load current of a three-level simplified neutral point clamped (3 L-SNPC) inverter is controlled in this paper using model predictive control (MPC). The 3 L-SNPC inverters is considered because fewer semiconductor devices are used in this topology; this will enhance the reliability of the system. MPC is used as a controller because it can handle the direct current-link capacitors’ voltage balancing problem in a very intuitive way. The proposed 3 L-SNPC yields similar current total harmonic distortion (THD), transient and steady-state responses, voltage stress and over current protection capability as the conventional NPC inverter. To reduce the computational burden of the proposed SNPC system, two simplified MPC strategies are proposed, namely, single voltage vector prediction-based MPC and selective voltage vector prediction-based MPC. Findings The system shows a current THD of 2.33% at 8.96 kHz. The overall loss of the system is reduced significantly to be useful in medium power applications. The required execution times for the simplified MPC strategies are tested on the hardware dSPACE 1104 platform. It is found that the single voltage vector prediction-based MPC and the selective voltage vector prediction-based MPC are computationally efficient by 8.28% and 62.9%, respectively, in comparison with the conventional MPC-based conventional NPC system. Originality/value Multiple system constraints are considered throughout the paper and also compare the SNPC to the conventional NPC inverter. Proper current tracking, over-current protection, overall power loss reduction especially switching loss and maintaining capacitor voltages balance at a neutral point are achieved. The improvement of execution time has also been verified and calculated using hardware-in-loop of the dSPACE DS1104 platform.

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Section: Introductionmentioning

confidence: 99%

Multi-constraints based predictive current control of simplified neutral point clamped inverter

Tariquzzaman

Habibullah

Podder

2021

WJE

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CSF-PC based grid tied improved hybrid three quasi Z source converter

Alla

Chowdhury

2020

COMPEL

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Purpose A new control method is proposed for grid integration of improved hybrid three quasi z source converter (IHTQZSC). The proposed controller provides a constant switching frequency with an improved dynamic response with fewer computations. The proposed constant switching frequency predictive controller (CSF-PC) does not need weighting factors and reduces the complexity of the control circuit. Design/methodology/approach A single PI controller is intended to control voltage across dc-link by generating the necessary shoot-through duty ratio. The predictive controller produces the modulating signals required to inject the desired grid current. The performance of the proposed controller is validated with MATLAB/Simulink software. Findings The discrete-time instantaneous model on the grid side in the proposed controller influences the inductor current with minimum ripples. Dynamic response and computational complexity of the converter with the PI controller, finite set model predictive controller (FS-MPC) and the proposed controller are discussed. Practical implications The converter belongs to impedance source converters (ISC) family, delivers higher voltage gain in a single-stage power conversion process, extract the energy from the intermittent nature of renewable energy conversion systems. Implementing CSF-PC for ISC is simple, as it has a single PI controller. Originality/value Grid integration of high voltage gain IHTQZSC is accomplished with PI, FS-MPC and CSF-PC. Though the FS-MPC exhibits superior dynamic response under input voltage disturbance and grid current variation, total harmonic distortion (THD) in the grid current is high. CSF-PC provides better THD with a good dynamic response with reduced inductor current ripples.

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Sensorless finite-state predictive torque control of induction motor fed by four-switch inverter using extended Kalman filter

Mohamed

Goléa

Benchouia

et al. 2018

COMPEL

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Purpose Direct Torque Control (DTC) of induction motor drives is a well-established technique owing to features such as fast dynamic and insensibility to motor parameters. However, conventional DTC scheme, based on comparators and the switching table, suffers from large torque and flux ripples. To improve DTC performance, this study aims to propose and implement a sensorless finite-state predictive torque control using extended Kalman Filter in dSPACE environment. Design/methodology/approach This paper deals with the design of an extended Kalman filter for estimating the state of an induction motor model and for sensorless control of systems using this type of motor as an actuator. A complex-valued model is adopted that simultaneously allows a simpler observability analysis of the system and a more effective state estimation. Findings Simulation and experimental results reveal that the drive system, associated with this technique, can effectively reduce flux and torque ripples with better dynamic and steady state performance. Further, the proposed approach maintains a constant switching frequency. Originality/value The proposed speed observer have been developed and implemented experimentally under different operating conditions such as parameter variation, no-load/load disturbances and speed variations in different speed operation regions.

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Finite set model predictive control to a shunt multilevel active filter

Cited by 5 publications

References 27 publications

Multi-constraints based predictive current control of simplified neutral point clamped inverter

Multi-constraints based predictive current control of simplified neutral point clamped inverter

CSF-PC based grid tied improved hybrid three quasi Z source converter

Sensorless finite-state predictive torque control of induction motor fed by four-switch inverter using extended Kalman filter

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