Virtual oscillator‐based methods for grid‐forming inverter control: A review

Aghdam, Sima Azizi; Agamy, Mohammed

doi:10.1049/rpg2.12398

Cited by 30 publications

(10 citation statements)

References 111 publications

(328 reference statements)

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“…A novel concept of Virtual Oscillator Control (VOC) based on dynamical systems theory is a recent major development in inverter control systems. Herein the inverter and a non-linear oscillator with a stable limit cycle trajectory are coupled to each other, thereby achieving efficiency and additional functionalities with minimal design complexity (Aghdam et al 2022;Costa et al 2021). Synchronisation of coupled oscillators is the key element of the VOC approach that provides sustained oscillations in the inverter output (Joshi et al 2016).…”

Section: Research Articlementioning

confidence: 99%

Virtual oscillator with delayed feedback for transient mitigation in inverter-based islanded microgrids

Salim,

Babu,

Krishna

2024

Int. J. Renew. Energy Dev.

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In recent years, the conventional control schemes for renewable energy-based inverter-dominated microgrids have been expeditiously replaced by Virtual Oscillator-based Control (VOC). The method of VOC ensures fast synchronisation and efficient load-sharing capabilities in inverter-based renewable energy systems. This work evaluates the effectiveness of VOC-based inverters in mitigating the transient dynamics of power system parameters like voltage, frequency and current under different types of switching events involving active and reactive load combinations. Further, to enhance the control efficiency of VOC under such load-switching scenarios a modified form of VOC is proposed utilizing the ability of the feedback mechanism to strengthen the state space trajectory of dynamical systems. In the proposed method, the control oscillator of conventional VOC driven by the inverter current is modified by providing a feedback signal in the form of an integral function of the error between the drive oscillator and the trajectory of the inverter output. The efficiencies of different forms of feedback are quantified in terms of percentage deviation in power system parameters as well as THD. The proposed feedback strategy can improve the control performance by bringing down the voltage deviation from 57 % in conventional VOC to around 4%. Likewise, the frequency deviation is brought down to 0.14% from 19.26 %. These advantages are achieved without any significant adverse impact on the THD. The proposed approach can be utilized in multi-inverter-based systems serving sensitive loads in microgrids.

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Section: Research Articlementioning

confidence: 99%

Virtual oscillator with delayed feedback for transient mitigation in inverter-based islanded microgrids

Salim,

Babu,

Krishna

2024

Int. J. Renew. Energy Dev.

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“…• Another trend is to model the internal dynamics of the dc-ac converters by oscillator dynamics. This approach is often adopted when studying the stability of interconnected converter-based systems; see [17] for a review and [12], [18] for experimental investigations.…”

Section: Power-preserving Averaged Dc-ac Converter Modelmentioning

confidence: 99%

“…proposed that synthesize the converter control based on the structural dynamic similarities with the SM [15], [16]. Along a different design direction, the nonlinear oscillators dynamics are recently exploited for a GFM control design [17]- [19]. Finally, the combination of aforementioned techniques has resulted in several hybrid control architectures [20]- [23].…”

Section: Introductionmentioning

confidence: 99%

Grid-Forming Hybrid Angle Control and Almost Global Stability of the DC-AC Power Converter

Tayyebi

Anta

Dörfler³

2022

IEEE Trans. Automat. Contr.

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This work explores the stability, behavior, variants, and a controller-hardware-in-the-loop (C-HiL) verification of the recently proposed grid-forming (GFM) hybrid angle control (HAC). We revisit the foundation of GFM HAC, and highlight its behavioral properties in relation to the conventional synchronous machine (SM). Next, we introduce the required complementary controls to be combined with the HAC to realize a GFM behavior. The characterization of the analytical operating point and nonlinear energy-based stability analysis of a grid-connected converter under the HAC is presented. Further, we consider various output filter configurations and derive an approximation for the original control proposal. Moreover, we provide details on the integration of GFM HAC into a complex converter control architecture and introduce several variants of the standard HAC. Finally, the performance of GFM HAC is verified by several test scenarios in a C-HiL setup to test its behavior against real-world effect such as noise and delays.

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“…In [28], the author presented inverter-based resources and GFM inverter controllers, which regulate terminal voltage, enable island operation, maintain grid stability, and help with black start capability. A virtual oscillator controller (VOC) is a time-domain control technique that instructs the inverter to simulate the dynamics of a nonlinear electrical oscillator using a digital controller [29]. It can synchronize multiple units, has droop characteristics, and does not require a power filter.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Grid-Forming Inverter Controls for Grid-Connected and Islanded Microgrid Integration

Ward,

Subburaj,

Demir

et al. 2024

Sustainability

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Autonomous grid-forming (GFM) inverter testbeds with scalable platforms have attracted interest recently. In this study, a self-synchronized universal droop controller (SUDC) was adopted, tested, and scaled in a small network and a test feeder using a real-time simulation tool to operate microgrids without synchronous generators. We presented a novel GFM inverter control adoption to better understand the dynamic behavior of the inverters and their scalability, which can impact the distribution system (DS). This paper provides a steady-state and transient analysis of the GFM power inverter controller via simulation to better understand voltage and frequency stabilization and ensure that the critical electric loads are not affected during a prolonged power outage. The controllers of the GFM inverter are simulated in HYPERSIM to examine voltage and frequency fluctuations. This analysis includes assessing the black start capability for photovoltaic microgrids, both grid-connected and islanded, during transient fault conditions. The high photovoltaic PV penetration levels open exciting opportunities and challenges for the DS. The GFM inverter control demonstrated appropriate response times for synchronization, connection, and disconnection to the grid. The DS has become more resilient and independent of fossil fuels by increasing the penetration of inverter-based distributed energy resources (DERs).

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Virtual oscillator‐based methods for grid‐forming inverter control: A review

Cited by 30 publications

References 111 publications

Virtual oscillator with delayed feedback for transient mitigation in inverter-based islanded microgrids

Virtual oscillator with delayed feedback for transient mitigation in inverter-based islanded microgrids

Grid-Forming Hybrid Angle Control and Almost Global Stability of the DC-AC Power Converter

Analysis of Grid-Forming Inverter Controls for Grid-Connected and Islanded Microgrid Integration

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