基于物理融合的联合仿真技术研究

Fengming Ai; Shouhong Feng; Xingzhuang Liang; Weilin Li; Qinzhou Lin

doi:10.11985/2021.01.010

基于物理融合的联合仿真技术研究

Translated title of the contribution: Research on Joint Simulation Technology Based on Physical Fusion

Fengming Ai, Shouhong Feng, Xingzhuang Liang, Weilin Li, Qinzhou Lin

School of Automation

Research output: Contribution to journal › Article › peer-review

Abstract

In recent years, the power hardware-in-the-loop (PHIL) simulation technology of electrical systems based on real-time digital simulators has attracted widespread attention. It combines the advantages of digital simulation and physical simulation, which can effectively improve simulation accuracy and shorten the development cycle of simulation systems. However, due to the unsatisfactory power interface, the constructed PHIL simulation system will have stability problems. Based on the theory of PHIL simulation system of ideal transformer (ITM) interface algorithm, a method of introducing compensation signal into the control signal of controlled current source is proposed. The research on system stability analysis can provide guidance for meeting the needs of multi-scale system co-simulation and implementing co-simulation of different systems.

Translated title of the contribution	Research on Joint Simulation Technology Based on Physical Fusion
Original language	Chinese (Traditional)
Pages (from-to)	70-76
Number of pages	7
Journal	Journal of Electrical Engineering (China)
Volume	16
Issue number	1
DOIs	https://doi.org/10.11985/2021.01.010
State	Published - Mar 2021

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abstract = "In recent years, the power hardware-in-the-loop (PHIL) simulation technology of electrical systems based on real-time digital simulators has attracted widespread attention. It combines the advantages of digital simulation and physical simulation, which can effectively improve simulation accuracy and shorten the development cycle of simulation systems. However, due to the unsatisfactory power interface, the constructed PHIL simulation system will have stability problems. Based on the theory of PHIL simulation system of ideal transformer (ITM) interface algorithm, a method of introducing compensation signal into the control signal of controlled current source is proposed. The research on system stability analysis can provide guidance for meeting the needs of multi-scale system co-simulation and implementing co-simulation of different systems.",

keywords = "PHIL, interface algorithm, parallel impedance",

author = "Fengming Ai and Shouhong Feng and Xingzhuang Liang and Weilin Li and Qinzhou Lin",

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T1 - 基于物理融合的联合仿真技术研究

AU - Ai, Fengming

AU - Feng, Shouhong

AU - Liang, Xingzhuang

AU - Li, Weilin

AU - Lin, Qinzhou

PY - 2021/3

Y1 - 2021/3

N2 - In recent years, the power hardware-in-the-loop (PHIL) simulation technology of electrical systems based on real-time digital simulators has attracted widespread attention. It combines the advantages of digital simulation and physical simulation, which can effectively improve simulation accuracy and shorten the development cycle of simulation systems. However, due to the unsatisfactory power interface, the constructed PHIL simulation system will have stability problems. Based on the theory of PHIL simulation system of ideal transformer (ITM) interface algorithm, a method of introducing compensation signal into the control signal of controlled current source is proposed. The research on system stability analysis can provide guidance for meeting the needs of multi-scale system co-simulation and implementing co-simulation of different systems.

AB - In recent years, the power hardware-in-the-loop (PHIL) simulation technology of electrical systems based on real-time digital simulators has attracted widespread attention. It combines the advantages of digital simulation and physical simulation, which can effectively improve simulation accuracy and shorten the development cycle of simulation systems. However, due to the unsatisfactory power interface, the constructed PHIL simulation system will have stability problems. Based on the theory of PHIL simulation system of ideal transformer (ITM) interface algorithm, a method of introducing compensation signal into the control signal of controlled current source is proposed. The research on system stability analysis can provide guidance for meeting the needs of multi-scale system co-simulation and implementing co-simulation of different systems.

KW - PHIL

KW - interface algorithm

KW - parallel impedance

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DO - 10.11985/2021.01.010

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SN - 2095-9524

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EP - 76

JO - Journal of Electrical Engineering (China)

JF - Journal of Electrical Engineering (China)

IS - 1

ER -

基于物理融合的联合仿真技术研究

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