Improved Model Predictive Control with Prescribed Performance for Aggregated Thermostatically Controlled Loads

被引：1

作者：

Yang Yu ^{[1
]}

Li Quan ^{[1
]}

Zengqiang Mi ^{[1
]}

Jianbin Lu ^{[1
]}

Shengqiang Chang ^{[2
]}

Yubao Yuan ^{[2
]}

机构：

[1] the State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources, North China Electric Power University

[2] the Innovation Center for Hebei Intelligent Grid Distribution Technology, Shijiazhuang Kelin Electric Co, Ltd

来源：

JournalofModernPowerSystemsandCleanEnergy | 2022年 / 10卷 / 02期

关键词：

D O I：

暂无

中图分类号：

TM73 [电力系统的调度、管理、通信];

学科分类号：

080802 ;

摘要：

Aggregate thermostatically controlled loads(ATCLs) are a suitable candidate for power imbalance on demand side to smooth the power fluctuation of renewable energy. A new control scheme based on an improved bilinear aggregate model of ATCLs is investigated to suppress power imbalance.Firstly, the original bilinear aggregate model of ATCLs is extended by the second-order equivalent thermal parameter model to optimize accumulative error over a long time scale. Then,to ensure the control performance of tracking error, an improved model predictive control algorithm is proposed by integrating the Lyapunov function with the error transformation,and theoretical stability of the proposed control algorithm is proven. Finally, the simulation results demonstrate that the accuracy of the improved bilinear aggregate model is enhanced;the proposed control algorithm has faster convergence speed and better tracking accuracy in contrast with the Lyapunov function-based model predictive control without the prescribed performance.

引用

页码：430 / 439

页数：10

共 28 条

[1]

Compensating active power imbalances in power system with large-scale wind power penetration[J]. Abdul BASIT,Anca D.HANSEN,Mufit ALTIN,Poul E.S?RENSEN,Mette GAMST.Journal of Modern Power Systems and Clean Energy. 2016(02)

[2]

Novel prescribed performance-tangent barrier Lyapunov function for neural adaptive control of the chaotic PMSM system by backstepping[J] . Junxing Zhang,Shilong Wang,Peng Zhou,Le Zhao,Shaobo Li.International Journal of Electrical Power and Energy Systems . 2020 (C)

[3] Model predictive current control method for PMSM drives based on an improved prediction model [J].

Fan, Shengwen ;

Tong, Chaonan .

JOURNAL OF POWER ELECTRONICS, 2020, 20 (06) :1456-1466

[4] Velocity-free prescribed performance control for spacecraft hovering over an asteroid with input saturation [J].

Zhang, Bo ;

Jiang, Lihong ;

Bai, Junqiang .

Journal of the Franklin Institute, 2020, 357 (11) :6471-6497

[5]

Flexible satellite control via fixed-time prescribed performance control and fully adaptive component synthesis vibration suppression[J] . Liang Zhang,Shijie Xu,Xiaozhe Ju,Naigang Cui.Nonlinear Dynamics . 2020 (prep)

[6]

Challenges and solution technologies for the integration of variable renewable energy sources—a review[J] . Simon R. Sinsel,Rhea L. Riemke,Volker H. Hoffmann.Renewable Energy . 2020 (C)

[7]

A Day-Ahead Scheduling of Large-Scale Thermostatically Controlled Loads Model Considering Second-Order Equivalent Thermal Parameters Model[J] . Li Min Cheng,Yu Qing Bao.IEEE Access . 2020

[8] Disturbance observer-based fixed-time prescribed performance tracking control for robotic manipulator [J].

Zhang, Yu ;

Hua, Changchun ;

Li, Kuo .

INTERNATIONAL JOURNAL OF SYSTEMS SCIENCE, 2019, 50 (13) :2437-2448

[9]

Dynamic dispatch of thermostatically controlled loads using phase oscillator model[J] . Pratik Bajaria,N.M. Singh.Sustainable Energy, Grids and Networks . 2019

[10]

Model predictive control based robust scheduling of community integrated energy system with operational flexibility[J] . Chaoxian Lv,Hao Yu,Peng Li,Chengshan Wang,Xiandong Xu,Shuquan Li,Jianzhong Wu.Applied Energy . 2019

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