Predictive Direct Power Control of Three-Phase PWM Rectifier Based on Linear Active Disturbance Rejection Control

Conference paper
Part of the Lecture Notes in Electrical Engineering book series (LNEE, volume 482)

Abstract

A dual closed loop for PWM rectifier, consisted of an inner instantaneous power loop and an outer dc-bus voltage loop, is presented in this paper. The inner loop adopts predictive direct power control (PDPC) and the outside one adopts linear active disturbance rejection control (LADRC) strategy. In order to achieve the expected switching voltage vectors, the instantaneous power values are forced to be equal to references at the next sampling instance in PDPC. The state space form can be established according to instantaneous active power balance equation, and then the generalized disturbance can be compensated. And the instantaneous active power reference can be achieved by LADRC structure. Finally, the presented structure is tested by simulation in Matlab/Simulink environment. And simulation results verified the feasibility and the effectiveness of the proposed system.

Keywords

Rectifier Instantaneous power Predictive power control Linear active disturbance rejection control 

References

  1. 1.
    Abdelouahab B, Jean-paul G, Fateh K (2010) Predictive direct power control of three-phase pulsewidth modulation (PWM) rectifier using space-vector modulation(SVM). IEEE Trans Power Electron 25(1):228–236CrossRefGoogle Scholar
  2. 2.
    Brando G, Dannier A, Del Pizzo A, Di Noia LP, Spina I (2015) Quick and high performance direct power control for multilevel voltage source rectifiers. Electr Power Syst Res 121:152–169CrossRefGoogle Scholar
  3. 3.
    Ma J, Song W, Feng X (2016) A model predictive direct power control of single-phase three-level PWM rectifiers. Proc CSEE 36(4):1098–1105 (in Chinese)Google Scholar
  4. 4.
    Leng Y, Yang H, Wang Z (2017) A method of suppressing low-frequency oscillation in traction network based on two-degree-of-freedom internal model control. Power Sys Technol 41(1):258–264 (in Chinese)Google Scholar
  5. 5.
    Omar FR, Angelica MT, Irwin ADD, Ilse C, Nancy V, Ciro N, Ernesto B (2016) Controllability of rectifiers and three point hysteresis line current control. Control Eng Pract 55:212–225CrossRefGoogle Scholar
  6. 6.
    Han J (1998) Active disturbance rejection controller and its applications. Control Decis 13(1):19–23 (in Chinese)MathSciNetGoogle Scholar
  7. 7.
    Tan W, Fu C (2016) Linear active disturbance-rejection control: analysis and tuning via IMC. IEEE Trans Ind Electron 63(4):2350–2359Google Scholar
  8. 8.
    Li J, Xia Y, Qi X, Gao Z (2017) On the necessity scheme and basis of the linear-nonlinear switching in active disturbance rejection control. IEEE Trans Ind Electron 64(2):1425–1435CrossRefGoogle Scholar

Copyright information

© Springer Nature Singapore Pte Ltd. 2018

Authors and Affiliations

  1. 1.School of Automation and Electrical EngineeringTianjin University of Technology and EducationHexi District, TianjinChina

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