Your search keyword '"Mitchell Easley"' showing total 9 results

1. Autonomous Model Predictive Controlled Smart Inverter With Proactive Grid Fault Ride-Through Capability

Author

Sarthak Jain, Haitham Abu-Rub, Mitchell Easley, and Mohammad B. Shadmand

Subjects

Model predictive control, Control theory, Computer science, Photovoltaic system, Energy Engineering and Power Technology, Inverter, Electrical and Electronic Engineering, Low voltage ride through, AC power, Grid, Maximum power point tracking

Abstract

This article presents an autonomous model predictive controlled smart photovoltaic (PV) inverter with proactive grid fault-ride through capability. The proposed smart inverter control features decoupled active and reactive power. It can seamlessly switch between the anticipated modes of operation based on grid condition or grid operator command. The smart inverter autonomously adjusts its active and reactive power set-points according to the grid condition, it operates in maximum power point tracking (MPPT) and low voltage ride through (LVRT) modes in normal grid and faulty grid condition modes, respectively. The proposed novel autonomous model predictive control (AMPC) scheme is leveraged to enhance the operation of the smart inverter. The AMPC includes online weight factor auto-tuning and control objective normalization to eliminate the required trial-and-error weight factor design stage in conventional model predictive control. This feature is particularly beneficial to the dual-mode smart inverter operation. The performance of the proposed grid-tied smart inverter based on the AMPC is verified experimentally. The results demonstrate that the proposed AMPC-based smart inverter features robust grid fault detection, autonomous adjustment of active and reactive power set-points, seamless transition between modes of operation, and elimination of controller tuning effort.

Published

2020

2. Computationally Efficient Distributed Predictive Controller for Cascaded Multilevel Impedance Source Inverter With LVRT Capability

Author

Haitham Abu-Rub, Mitchell Easley, Mohammad B. Shadmand, and Sarthak Jain

Subjects

reactive power compensator, General Computer Science, Maximum power principle, model predictive control, Computer science, 02 engineering and technology, Impedance source inverter, Solar irradiance, Control theory, 0202 electrical engineering, electronic engineering, information engineering, 0501 psychology and cognitive sciences, General Materials Science, Low voltage ride through, Electrical impedance, 050107 human factors, LVRT, 05 social sciences, Photovoltaic system, General Engineering, 020207 software engineering, AC power, Grid, Model predictive control, Impedance network, photovoltaic systems, Power quality, Inverter, lcsh:Electrical engineering. Electronics. Nuclear engineering, lcsh:TK1-9971, Energy harvesting, Voltage

Abstract

This paper presents a decoupled active and reactive power control scheme for grid-tied quasi-impedance source cascaded multilevel inverter (qZS-CMI). For photovoltaic (PV) applications, the proposed control scheme is based on an enhanced finite-set model predictive control (MPC) to harvest the desired active power from the PV modules with the ability to provide the ancillary services for the grid. The proposed control scheme has two modes of operation: normal grid mode and low voltage ride through (LVRT) mode. In normal grid mode, the controller commands the qZS-CMI to operate at the global maximum power point (MPP). The proposed technique regulates the impedance network's current and voltage according to the MPP of PV strings and grid current/voltage requirements. In LVRT mode, the controller commands the qZS-CMI to provide the required reactive power to the grid during voltage sags as an ancillary service from the inverter as imposed by the grid codes. The main features of the proposed system include the global MPP operation during normal grid condition, LVRT capability during a grid voltage sag, mitigation of the PV modules mismatch effect on overall energy harvesting, seamless transition between a normal grid and LVRT modes of operation, and an efficient predictive controller that exploits the model redundancies in the control objectives. Several real-time experiments are conducted to verify the system performance with transients in both the solar irradiance and the grid voltage.

Published

2019

3. PLL-less Active and Reactive Power Controller for Grid-Following Inverter

Author

Ahmad Khan, Haitham Abu-Rub, Poria Fajri, Mitchell Easley, Mohsen Hosseinzadehtaher, and Mohammad B. Shadmand

Subjects

Computer science, 05 social sciences, Dual loop, Synchronizing, 020207 software engineering, 02 engineering and technology, AC power, Grid, Phase-locked loop, Nonlinear system, Robustness (computer science), Control theory, 0202 electrical engineering, electronic engineering, information engineering, Inverter, 0501 psychology and cognitive sciences, 050107 human factors

Abstract

This paper presents a control scheme for single-phase grid-following inverters that does not rely on the phase-locked-loop (PLL) algorithm for synchronizing the injected current with the grid. The absence of the PLL avoids unstable low damping modes that are possibly originated from the PLL’s nonlinear nature. Thereby, assuring the control scheme robustness, especially, in weak grid conditions. Furthermore, the proposed PLL-less control achieves tracking the commanded active and reactive power (PQ) set-point references in a single loop control scheme. Hence, reducing controller design complexity compared to conventional cascaded dual loop PQ control scheme. This work also illustrates the necessary conditions to assure that the control is asymptotically stable with weak resistive and inductive grids. Finally, several case studies are implemented to validate the theory developed.

Published

2020

4. Resonance Suppression based on Predictive Control of Grid-following Inverters with LCL Filter in Weak Grid Condition

Author

Silvanus D'silva, Brevann Nun, Mohammad B. Shadmand, Ahmad Khan, Muhammad Farooq Umar, and Mitchell Easley

Subjects

Model predictive control, Short circuit ratio, Control theory, Computer science, Inverter, Resonance, AC power, Grid, Signal

Abstract

This paper presents an effective resonance suppression control when grid interactive inverter with LCL filter experience weak grid conditions. The resonance suppression mechanism is based on finite-set model predictive control (FS- MPC) with adaptive cost function to alter the controller objectives seamlessly. The large parasitic impedance and low short circuit ratio (SCR) of weak grid challenges the operation of grid- connected inverters. Specifically, the LCL filter resonance may get excited, resulting in collapse of the inverter operation. To address this issue, an effective active damping approach is implemented in the proposed control. In the proposed active damping scheme for resonance suppression, the feedback currents are switched based on the operating conditions of inverter. During the stiff grid conditions, grid current serves as feedback to the controller. While in the weak grid conditions, the inverter current is selected as feedback signal. The toggling action between these two feedback currents is determined by comparing moving RMS of grid current with threshold current as constraint in the cost function of the proposed MPC scheme. The threshold current for toggling action is based on the reference active and reactive power setpoints plus an acceptable band of variation. The theoretical analysis is verified by several case studies.

Published

2020

5. Auto-tuned Model Parameters in Predictive Control of Power Electronics Converters

Author

Amin Y. Fard, Mohammad B. Shadmand, Mitchell Easley, Fariba Fateh, and Haitham Abu-Rub

Subjects

Computer science, 05 social sciences, 020207 software engineering, 02 engineering and technology, AC power, Network topology, Inductance, Model predictive control, Control theory, Filter (video), 0202 electrical engineering, electronic engineering, information engineering, 0501 psychology and cognitive sciences, Transient response, Electrical impedance, 050107 human factors

Abstract

Model predictive controlled (MPC) power electronics converters (PECs) features numerous benefits including fast transient response, multi-objective control in single-loop, and inclusion of constraints and nonlinearities in a simple manner. However, the control approach requires the accurate knowledge of the model parameters of the system. Potential model parameter mismatches with the actual values will result in performance deterioration of the MPC. Various agents like aging and harsh environmental conditions would yield changes in circuit impedance. This paper proposes an autonomous MPC for PECs subject to the variations and uncertainties in input filter impedance. The proposed controller adaptively tunes the model parameters used in the predictive equations, alleviating mismatch among the predictive model parameters and the actual system. The proposed auto-tuned modeling scheme requires no additional sensors while maintaining the simplicity of the controller. The proposed method is applicable to all types of PECs and filter topologies. The theoretical analysis and results demonstrate that the proposed approach embedded in the MPC makes the control algorithm robust to variations of model parameters of the system.

Published

2019

6. Computationally-efficient Hierarchical Optimal Controller for Grid-tied Cascaded Multilevel Inverters

Author

Amin Y. Fard, Mitchell Easley, Mohsen Hosseinzadehtaher, Mohammad B. Shadmand, and Haitham Abu-Rub

Subjects

Computer science, 05 social sciences, Battery energy storage, 020207 software engineering, 02 engineering and technology, AC power, Grid, Phase-locked loop, Model predictive control, Control theory, Robustness (computer science), Power electronics, 0202 electrical engineering, electronic engineering, information engineering, 0501 psychology and cognitive sciences, 050107 human factors, Minimum energy control

Abstract

This paper proposes a hierarchical optimal active and reactive power control while minimizing the switching events for three-phase grid-tied cascaded multilevel inverters (CMI) for battery energy storage applications. Model predictive control (MPC) is known as a potential approach for multi-objective control schemes in single-loop manner for power electronics interfaces. However, MPC schemes are suffering from high computational burden. Furthermore, one of the main challenges while designing MPC is tuning of the cost function weight factors in multi-objective control schemes. The weight factors design and tuning directly affect the performance and robustness of the MPC. The proposed high performance hierarchical multi-objective optimal controller doesn’t have the aforementioned limitations of the MPC. The proposed control scheme utilizes a dynamic look-up matrix as an internal optimizer tool. The redundant switching states are cycled to equalize the power drawn from the independent battery energy storage sources while achieving a minimum energy control. The theoretical analysis and case studies verify robustness, fast dynamic response, and computational efficiency of the proposed multi-criteria optimal controller.

Published

2019

7. Hierarchical Model Predictive Control for Cascaded Multilevel Inverters

Author

Fariba Fateh, Sarthak Jain, Mitchell Easley, Mohammad B. Shadmand, and Behrooz Mirafzal

Subjects

Computer science, 020209 energy, 05 social sciences, 02 engineering and technology, AC power, Grid, Hierarchical database model, Model predictive control, Control theory, Reactive power control, 0202 electrical engineering, electronic engineering, information engineering, Redundancy (engineering), 0501 psychology and cognitive sciences, Voltage source, MATLAB, computer, 050107 human factors, computer.programming_language

Abstract

This paper presents a hierarchical finite-set model predictive control (MPC) scheme for grid-tied cascaded multilevel inverters (CMI) with independent active and reactive power injection capabilities. The proposed controller has a hierarchical framework to eliminate the computationally burdensome cost function optimization and associated weight factors of the control objectives. The control formulation approach allows for multi-objective optimization with an error-tolerance framework. The control scheme achieves active and reactive power control with switching loss minimization while extracting power evenly from the independent voltage sources. The control is modularized for each phase, making the system robust to unbalanced grid conditions. The proposed control scheme is validated for grid-voltage transients in MATLAB/Simulink.

Published

2019

8. Distributed Predictive Control Scheme for Grid-Tied Cascaded Multilevel Impedance Source Inverter with LVRT Capability

Author

Mohammad B. Shadmand, Sarthak Jain, Fariba Fateh, and Mitchell Easley

Subjects

Model predictive control, Control theory, Computer science, 020209 energy, Voltage sag, 020208 electrical & electronic engineering, Photovoltaic system, 0202 electrical engineering, electronic engineering, information engineering, Inverter, 02 engineering and technology, Low voltage ride through, AC power, Grid

Abstract

This paper presents a decoupled power control scheme for grid-tied single-phase quasi-impedance-source cascaded multilevel inverter (qZS-CMI) for photovoltaic (PV) applications. The proposed control scheme for the grid-tied qZSI-CMI is based on finite-set model predictive control (MPC) to harvest the desired active power from PV modules with ability to provide ancillary services for the grid. The proposed control scheme has two modes of operation: normal grid mode and low voltage ride through (LVRT) mode. In normal grid mode, the controller commands the qZS-CMI to operate at global maximum power point (MPP). The proposed technique regulates the impedance network elements' voltage and current according to the MPP of PV panels and grid voltage/current requirements. In LVRT mode, the controller commands the qZS-CMI to provide the required reactive power for grid during voltage sag as an ancillary service from the inverter as imposed by grid codes. The main features of the proposed system include: global MPP operation during normal grid condition, LVRT capability during grid voltage sag, mitigation of the PV modules mismatch on overall energy harvesting, and seamless transition between normal grid and LVRT modes of operation. Several real-time experiments are conducted to verfiy the system performance with transients in both solar irradiance and the grid voltage.

Published

2018

9. Decoupled active and reactive power predictive control of impedance source microinverter with LVRT capability

Author

Mitchell Easley, Mohammad B. Shadmand, Sarthak Jain, and Behrooz Mirafzal

Subjects

Model predictive control, Solar micro-inverter, Maximum power principle, Control theory, Computer science, 020209 energy, Photovoltaic system, 0202 electrical engineering, electronic engineering, information engineering, 02 engineering and technology, Low voltage ride through, AC power, Maximum power point tracking

Abstract

This paper presents a decoupled active and reactive power predictive control for quasi-Z-source (qZS) single-phase grid connected photovoltaic (PV) microinverter with low voltage ride through (LVRT) capability. The control algorithm structure is based on model predictive control (MPC) framework to facilitate switching between modes of operation: maximum power point tracking (MPPT) and LVRT modes. The proposed controller extracts the maximum power from the PV panels during the normal grid condition. The system is capable of injecting reactive power based on LVRT requirements by the grid codes based on commanded reactive power injection strategy. The proposed algorithm has simple structure with less complexity and computational time for easier and effective implementation. It can respond to rapidly changing PV ambient and grid conditions and appropriately alter the current injection. The performance of the controller is verified experimentally for three reactive power injection strategies.

Published

2018