Development of Power System Models for Distributed Real-Time Simulations

Shen, Zhenjiang; Arraño-Vargas, Felipe; Wickramasinghe, Harith R.; Konstantinou, Georgios

doi:10.1109/access.2022.3216596

Cited by 7 publications

(9 citation statements)

References 47 publications

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“…By incorporating such a model into additional libraries, it becomes possible to test new applications and algorithms with a focus on LPS. For instance, the benchmark model has been later used for: i) testing new algorithms for decoupling models for distributed simulations [36], ii) developing adaptive power reserve control strategies for PV plants [37], and iii) demonstrating a virtual testbed for digital twin applications [38]. In addition, simulations and results using the Simplified Australian 14-Generator can be cross-verified along various software and platforms [39].…”

Section: Large-scale Modeling: Benchmark Models and Synthetic Gridsmentioning

confidence: 99%

UNSW Sydney's Real-Time Simulations Laboratory (RTS@UNSW): Supporting Power Electronics Defined Power Systems, Down Under

Arraño-Vargas,

Agelidis,

Konstantinou

2024

IEEE Open J. Power Electron.

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Real-time simulations (RTS) and hardware-in-the-loop (HiL) testing are becoming increasingly vital to the power industry in order to support the pace of the ongoing energy transition. Such methods enable the optimization of power systems and validation of solutions, applications and components under realistic operational conditions while minimizing associated risks. The Real-Time Simulations Laboratory at The University of New South Wales, in Sydney Australia (RTS@UNSW) is a dedicated research facility built with a focus on enabling and advancing the use of RTS and HiL in Australia. The lab is equipped with state-of-the-art simulators and testing equipment supporting integration of power electronics at scale and the development and deployment of power electronics defined power systems. This paper will provide a brief introduction to the Australian context related to the energy transition, an overview of the available facilities, and some of the key research and industry-related projects that it supports.INDEX TERMS Co-simulation, engineering education, hardware-in-the-loop (HiL) testing, large-scale modeling, rapid control prototyping (RCP), real-time digital simulation (RTS), RTS@UNSW.

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Section: Large-scale Modeling: Benchmark Models and Synthetic Gridsmentioning

confidence: 99%

UNSW Sydney's Real-Time Simulations Laboratory (RTS@UNSW): Supporting Power Electronics Defined Power Systems, Down Under

Arraño-Vargas,

Agelidis,

Konstantinou

2024

IEEE Open J. Power Electron.

Self Cite

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“…Digital PHIL simulators have been used in several works of literature to co-simulate with grid emulators and physical systems; however, due to the real interface's low voltage, sensors and amplifiers are needed to send signals at the power side. Providentially, for simulatorto-simulator data sharing, which is also applicable in GDRTCS, the communication network and interface simplify the interface of IA [41]. Thus, some challenges listed in Table 1 may not exist in simulator-to-simulator data sharing.…”

Section: H Summary Of Interface Algorithmsmentioning

confidence: 99%

“…The remote side then reconstructs signals and provides a delay compensation and synchronization. Lastly, the reconstructed signals are introduced into the distributed subsystem [41].…”

Section: ) Wave Variable Transformationmentioning

confidence: 99%

“…Remote subsystem synchronization using GPS signals is frequent. GPS signals ensure subsystems start their simulations simultaneously [41].…”

Section: Gps Synchronizationmentioning

confidence: 99%

“…Digital RT co-simulation power system splitting is suggested in [41], where Figure 30 shows a six-step flowchart. Splitting a power system begins with identifying splitting points.…”

Section: ) Interface Energy Conservationmentioning

confidence: 99%

See 2 more Smart Citations

Overview of Interface Algorithms, Interface Signals, Communication and Delay in Real-Time Co-Simulation of Distributed Power Systems

Buraimoh,

Ozkan,

Timilsina

et al. 2023

IEEE Access

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In recent years, there has been growing research interest in the virtual integration of hardware and software assets across different geographical locations. However, achieving joint real-time simulation in virtually connected laboratories presents several challenges that must be addressed. One critical aspect involves selecting suitable interface algorithms to conserve energy, ensure signal decomposition, and reconstruct data accurately, thereby preventing distortions. Additionally, communication latencies must be taken into account to maintain experiment fidelity. The establishment of fast and reliable communication between real-time simulators in different laboratories through coupling interfaces, is of utmost importance for successful real-time cosimulation. Nevertheless, assuming the constant availability of reliable and delay-free communication is unrealistic, which can lead to performance degradation and system instability. These requirements pose significant obstacles to implementing virtual integration involving various real-time simulators and hardware-in-the-loop setups across diverse laboratories. The real-time co-simulation of power systems, in particular, is highly susceptible to ineffective interface algorithms, signal decomposition, and reconstruction, as well as communication delays, potentially causing loss of synchronism and negatively impacting simulation fidelity. Consequently, these limitations render such setups unsuitable for dynamic and transient studies. In light of these challenges, this paper aims to provide an overview of interface algorithms, signal decomposition and reconstruction techniques, communication protocols, and delay compensation approaches. The goal is to ensure system fidelity, enhance coupling point modeling, and improve the accuracy of real-time co-simulation in virtual environments across long distances while preserving ongoing research confidentiality, safeguarding intellectual property, and facilitating collaborative research.

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Longitudinal power systems for modern and future grid studies: A graph theory analysis

Arraño-Vargas,

Konstantinou

2023

Sustainable Energy, Grids and Networks

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Development of Power System Models for Distributed Real-Time Simulations

Cited by 7 publications

References 47 publications

UNSW Sydney's Real-Time Simulations Laboratory (RTS@UNSW): Supporting Power Electronics Defined Power Systems, Down Under

UNSW Sydney's Real-Time Simulations Laboratory (RTS@UNSW): Supporting Power Electronics Defined Power Systems, Down Under

Overview of Interface Algorithms, Interface Signals, Communication and Delay in Real-Time Co-Simulation of Distributed Power Systems

Longitudinal power systems for modern and future grid studies: A graph theory analysis

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