Thermo-electric co-simulation on geographically distributed real-time simulators

Faruque, M. Omar; Sloderbeck, M.; Steurer, M.; Dinavahi, Venkata

doi:10.1109/pes.2009.5275631

Cited by 22 publications

(17 citation statements)

References 12 publications

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“…Co-simulation is the concept of composing coupled simulators that cooperate with each other while running on their own solvers and models. Co-simulation is particularly useful for coupling models with different time scales (transient/steady state) or with distinct natures (continuous/discrete event), in eventually different domains (e.g., power and ICT, electric and thermo) [31][32][33].…”

Section: Testbed Technologymentioning

confidence: 99%

ERIGrid Holistic Test Description for Validating Cyber-Physical Energy Systems

et al. 2019

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Smart energy solutions aim to modify and optimise the operation of existing energy infrastructure. Such cyber-physical technology must be mature before deployment to the actual infrastructure, and competitive solutions will have to be compliant to standards still under development. Achieving this technology readiness and harmonisation requires reproducible experiments and appropriately realistic testing environments. Such testbeds for multi-domain cyber-physical experiments are complex in and of themselves. This work addresses a method for the scoping and design of experiments where both testbed and solution each require detailed expertise. This empirical work first revisited present test description approaches, developed a newdescription method for cyber-physical energy systems testing, and matured it by means of user involvement. The new Holistic Test Description (HTD) method facilitates the conception, deconstruction and reproduction of complex experimental designs in the domains of cyber-physical energy systems. This work develops the background and motivation, offers a guideline and examples to the proposed approach, and summarises experience from three years of its application.

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Section: Testbed Technologymentioning

confidence: 99%

ERIGrid Holistic Test Description for Validating Cyber-Physical Energy Systems

et al. 2019

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“…Geographically distributed simulation as an approach to multidomain simulation was pursued for thermo-electric co-simulation of an all-electric ship [13]. Within this context, two different offthe-shelf simulators, RT digital simulator (RTDS) and OPAL-RT were interconnected over the distance of 3500 km.…”

Section: Summary Of Related Workmentioning

confidence: 99%

Multi‐site European framework for real‐time co‐simulation of power systems

Stevic

Estebsari

Vogel

et al. 2017

IET Generation, Transmission & Distribution

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Abstract:The framework for virtual integration of laboratories enables co-simulation and joint experiments that include hardware and software resources hosted at geographically distributed laboratories. The underlying concept of such framework is geographically distributed real-time (RT) co-simulation. To this end, digital RT simulators are interfaced over long distances via shared communication network such as the Internet. This study proposes an architecture for a modular framework supporting virtual integration of laboratories that enable flexible integration of digital RT simulators across Europe. In addition, the framework includes an interface that enables access for third parties via a web browser. A co-simulation interface algorithm adopted in this study is based on representation of interface quantities in form of dynamic phasors. Time delay between RT digital simulators is compensated by means of phase shift that enables simulation fidelity for slow transients.

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“…A case of thermoelectric cosimulation for electric ship was reported in [68] where a combined electrical and thermal simulation was carried out using two RT digital simulators located geographically apart from each other. The electrical model was developed on the first DRTS at the Center for Advanced Power Systems, Florida State University, Tallahassee, FL, USA, while the thermal model was developed on another DRTS of different type located at the RTX-Lab of the University of Alberta (U of A), Edmonton, AB, Canada.…”

Section: B Electric Ship: Geographically Distributed Thermo-electricmentioning

confidence: 99%

Applications of Real-Time Simulation Technologies in Power and Energy Systems

Guillaud

Faruque

Teninge

et al. 2015

IEEE Power Energy Technol. Syst. J.

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164

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Real-time (RT) simulation is a highly reliable simulation method that is mostly based on electromagnetic transient simulation of complex systems comprising many domains. It is increasingly used in power and energy systems for both academic research and industrial applications. Due to the evolution of the computing power of RT simulators in recent years, new classes of applications and expanded fields of practice could now be addressed with RT simulation. This increase in computation power implies that models can be built more accurately and the whole simulation system gets closer to reality. This Task Force paper summarizes various applications of digital RT simulation technologies in the design, analysis, and testing of power and energy systems. INDEX TERMS Applications, design, distribution networks, electric power circuits, hardware-in-theloop (HIL), modeling, rapid prototyping (RP), real-time (RT) simulation, testing, transmission networks. I. INTRODUCTION D IGITAL real-time (RT) simulators exploit advanced digital hardware and parallel computing methods to solve differential equations characterizing the system

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Thermo-electric co-simulation on geographically distributed real-time simulators

Abstract: In this paper, we report a combined electrical and thermal simulation carried out using two real-time digital simulators located approximately 3500 km from each other. The electrical model was developed on the RTDS simulator at the

Cited by 22 publications

References 12 publications

ERIGrid Holistic Test Description for Validating Cyber-Physical Energy Systems

ERIGrid Holistic Test Description for Validating Cyber-Physical Energy Systems

Multi‐site European framework for real‐time co‐simulation of power systems

Applications of Real-Time Simulation Technologies in Power and Energy Systems

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