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1. Model Predictive Current Control with Inherent Damping for Inverters under Weak Grid Conditions

   Lee, S. and (January 2019, Proceedings of the 52nd Frontiers of Power Conference)

   null (Ed.)

   Increased capacity associated with renewable energy sources has created a need for improved methods for controlling power flows from inverter-based generation. This research provides a comparative study of finite-control-set model predictive current control (FCS-MPC-based) with respect to conventional proportional-integral-based (PI-based) synchronous current control for a three-phase voltage source inverter (VSI). The inverter is accompanied by an inductive-capacitive-inductive (LCL) filter to attenuate pulse width modulation (PWM) switching harmonics. However, an LCL filter introduces a resonance near to the control stability boundary, giving rise to substantial complexity from a control perspective. In order to avoid potential instability caused by the resonance, active damping can be included in the PI-based current control. Though properly designed active damping can improve inverter stability, in practice the robustness of standard PI control is not attainable due to variability in the grid inductance at the point of common coupling (PCC). This is due to impedance variations causing large shifts in the LCL resonance frequency. Weak grid conditions (i.e., a low short-circuit ratio) and a correspondingly high line impedance are particularly susceptible to LCL induced resonance instabilities. As an approach to operate with grid impedance variations and weak grid conditions, FCS-MPC has the potential to produce superior performance compared to PI-based current control methods. This comparative study indicates that FCS-MPC has improved resonance damping and fast dynamic capability in a system with renewable energy sources under weak grid conditions. Detailed results from MATLAB/SimPower are presented to validate the suggested FCS-MPC method where it is robust to uncertainty in the grid impedance variations. Overall results indicate an improvement over conventional PI-based current control methods. 

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2. Stability Analysis of Multiple Grid-Connected Inverters Using Different Feedback Currents

   https://doi.org/10.1109/PEDG.2018.8447657  

   Carballo, David; Escala, Edgar; Balda, Juan Carlos (June 2018, 2018 9th IEEE International Symposium on Power Electronics for Distributed Generation Systems (PEDG))

   Distributed generation is gaining greater penetration levels in distribution grids due to government incentives for integrating distributed energy resources (DERs) and DER cost reductions. The frequency response of a grid-connected single inverter changes as other inverters are connected in parallel due to the couplings among grid inductance and/or inverter output filters. The selection of the inverter- or grid-side currents as feedback control signals is then not trivial because each one has tradeoffs. This paper analyses the system stability for multiple parallel- and grid-connected inverters using the inverter- or gridside currents as feedback signals. Modeling of both feedback signals is performed using the current separation technique. Moreover, the stability range for different conditions including active damping is analyzed through the root locus technique. The grid-side current has a wider range of stability, but the inverterside current allows for higher values of the proportional gain near the critical frequency and no extra sensors are needed since measurement of the inverter current is needed for protection in high-power applications. 

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3. Transient behaviour verification and controller tuning for an uncertain grid‐connected photovoltaic system using reachability analysis

   https://doi.org/10.1049/rpg2.12212  

   Shabestari, Parisa_M; Mehrizi‐Sani, Ali (May 2021, IET Renewable Power Generation)

   Abstract Power electronics–based converters for photovoltaic (PV) systems are susceptible to overcurrents; it is important to design their controllers to reduce the transient current for all viable operating conditions. To design a current controller and find the maximum transient current via simulation‐based techniques, the exact values of the system parameters, initial states, and inputs are required. However, they are not precisely known in practice, some system parameters such as inductances may change over time, and output power and load are variable. The uncertainty in the parameter (filter inductance) and input of the system (injected power) should be considered in the analysis of a PV system controllers as it can degrade their performance, which are designed for the system nominal parameters. This paper employs reachability analysis for a grid‐connected PV system to (1) find the maximum transient current, (2) devise an improved PI current controller and (3) compare the maximum transient current in PI‐ and internal model control (IMC)‐based controllers with uncertain‐but‐bounded input power and inductance error. Simulation and experimental studies showcase the results. 

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4. Emergent magneto-inductance effect in permalloy thin films on flexible polycarbonate substrates at room temperature

   https://doi.org/10.1063/5.0181272  

   Matsushima, Yu; Zhang, Zijing; Ohashi, Yuri; Hatakeyama, Tsunagu; Xiao, Gang; Funato, Takumi; Matsuo, Mamoru; Kaiju, Hideo (January 2024, Applied Physics Letters)

   Emergent inductance has attracted significant interest for its relevance in both interesting fundamental physics and practical applications in magnetic devices that demand miniaturization without compromising inductance. In this Letter, we report the discovery of a stepwise magnetic field-induced emergent magneto-inductance (EML) effect in Permalloy (Py) thin films deposited on polycarbonate (PC) substrates. Remarkably, Py/PC devices exhibit an exceptionally large inductance variation exceeding 1 μH at room temperature, and intriguingly, a sign reversal of inductance occurs around the zero magnetic field. The dependencies of the EML effect on frequency, step magnetic field changes, and film width can be explained from the theory based on the spin motive force driven by transient domain wall motion. This study opens up exciting avenues for advancing our understanding of emergent inductance in fundamental physics and paves the way for practical applications in flexible magnetic devices. 

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5. Evaluation of 1.2 kV SiC MOSFETs in Modular Multilevel Cascaded H-Bridge Three-Phase Inverter for Medium Voltage Grid Applications

   Umuhoza, J; Mhiesan, H; Mordi, K; Farnell, C.; Mantooth, A (May 2018, 2018 WiPDA Asia)

   This paper describes a study evaluating 1.2 kV SiC MOSFETs in modular multilevel cascaded H-bridge (CHB) threephase inverter for medium voltage ac grid applications. The main purpose of this topology is to remove the need of a bulk 60 Hz transformer that is normally used to step up the output signal of a voltage source inverter to the medium voltage level. Using SiC devices (1.2 kV ~ 6.5 kV SiC MOSFETs), with their high breakdown voltage, enables the system to meet and withstand the medium voltage stress, with a minimized number of cascaded modules. The SiC-based power electronics, when used in the presented topology, they significantly reduce the complexity usually faced when Si devices are used to meet the medium voltage level and the power scalability. The simulation and preliminary experimental results, on a low-voltage prototype, verifies the ninelevel CHB topology that is presented in this paper. 

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