Co-simulation of Power Grid, Information Network and Transportation Network Simulation System

被引：3

作者：

Yongmin, Shuai ^{[1
]}

Zhang, Yu ^{[2
]}

Liu, Fuhao ^{[2
]}

Qiao, Xiaobin ^{[1
]}

Xiong, Yunfei ^{[3
]}

Zeng, Yong ^{[3
]}

机构：

[1] Wuhan Maritime Commun Res Inst, Wuhan, Peoples R China

[2] Cent China Normal Univ, Coll Phys Sci & Technol, Wuhan, Peoples R China

[3] Wuhan Fiberhome Tech Serv Co Ltd, Wuhan, Peoples R China

来源：

2022 2ND IEEE INTERNATIONAL CONFERENCE ON SOFTWARE ENGINEERING AND ARTIFICIAL INTELLIGENCE (SEAI 2022) | 2022年

关键词：

power grid; information network; transportation network; co-simulation system;

D O I：

10.1109/SEAI55746.2022.9832036

中图分类号：

TP18 [人工智能理论];

学科分类号：

081104 ; 0812 ; 0835 ; 1405 ;

摘要：

The three-network integration of power grid, information network and transportation network has become a global issue and trend. However, the current research on triple play is still in its infancy. Most of the researches define the concept of triple play, and lack of simulation research on the power grid-information network-transportation network coupling system. Therefore, this paper studies the key technologies of power grid-information network-transportation network co-simulation. The key technologies of simulation are data interaction method and time synchronization method. By building a simulation prototype system, it provides simulation support for the theoretical study of the power grid-information network-transportation network coupling system.

引用

页码：199 / 203

页数：5

共 10 条

[1]

Daniel Vera Silva Carlos, 2018, VISION ELECT, V12, P149

[2] OMNET plus plus and Maple software environments for IT Bachelor studies [J].

Dronyuk, Ivanna ;

Fedevych, Olga ;

Stolyarchuk, Roksolyana ;

Auzinger, Winfried .

16TH INTERNATIONAL CONFERENCE ON MOBILE SYSTEMS AND PERVASIVE COMPUTING (MOBISPC 2019),THE 14TH INTERNATIONAL CONFERENCE ON FUTURE NETWORKS AND COMMUNICATIONS (FNC-2019),THE 9TH INTERNATIONAL CONFERENCE ON SUSTAINABLE ENERGY INFORMATION TECHNOLOGY, 2019, 155 :654-659

[3] Optimal charging scheduling for large-scale EV (electric vehicle) deployment based on the interaction of the smart-grid and intelligent-transport systems [J].

Luo, Yugong ;

Zhu, Tao ;

Wan, Shuang ;

Zhang, Shuwei ;

Li, Keqiang .

ENERGY, 2016, 97 :359-368

[4] Assessment of the Impact of Electric Vehicles on the Design and Effectiveness of Electric Distribution Grid with Distributed Generation [J].

Mancini, Enrico ;

Longo, Michela ;

Yaici, Wahiba ;

Zaninelli, Dario .

APPLIED SCIENCES-BASEL, 2020, 10 (15)

[5] Quantifying The Impact of Electric Vehicles On The Electric Grid - A Simulation Based Case-Study [J].

Ramanujam, Arvind ;

Sankaranarayanan, Pandeeswari ;

Vasan, Arun ;

Jayaprakash, Rajesh ;

Sarangan, Venkatesh ;

Sivasubramaniam, Anand .

PROCEEDINGS OF THE 8TH INTERNATIONAL CONFERENCE ON FUTURE ENERGY SYSTEMS (E-ENERGY'17), 2017, :228-233

[6] Building a Large-Scale Micro-Simulation Transport Scenario Using Big Data [J].

Schweizer, Joerg ;

Poliziani, Cristian ;

Rupi, Federico ;

Morgano, Davide ;

Magi, Mattia .

ISPRS INTERNATIONAL JOURNAL OF GEO-INFORMATION, 2021, 10 (03)

[7] Nodal Impact Assessment and Alleviation of Moving Electric Vehicle Loads: From Traffic Flow to Power Flow [J].

Tang, Difei ;

Wang, Peng .

IEEE TRANSACTIONS ON POWER SYSTEMS, 2016, 31 (06) :4231-4242

[8]

Wegener A., 2008, P 11 COMM NETW SIM S, P155, DOI DOI 10.1145/1400713.1400740

[9]

Ying Zhang, 2021, ENG APPL ARTIF INTEL, P104

[10]

Zhongzhi Li, 2011, WSEAS Transactions on Computers, V10, P61

← 1 →