An Adaptive Integral Backstepping SMC and Robust Functional Expanded Multikernel BLS Based MPPT Control in PV-Battery DC Microgrid System

In this paper, a robust functional expanded multikernel broad learning system (RFEMBLS) is proposed to compute the complex nonlinear solar photovoltaic (PV) reference voltage more accurately by importing the irradiance and temperature in different uncertainty conditions. The novel droop control mech...

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Bibliographic Details
Published inIEEE transactions on power electronics Vol. 39; no. 3; pp. 1 - 13
Main Authors Sahani, Mrutyunjaya, Biswal, Baladev, Prasad, Eluri NVDV, Dash, Pradipta Kishore, Panda, Sanjib Kumar
Format Journal Article
LanguageEnglish
Published New York IEEE 01.03.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Adaptive control
Adaptive integral backstepping sliding mode control
Adaptive systems
Backstepping
Batteries
Control systems design
Controllers
Data buses
Distributed generation
dSPACE hardware in loop
Electric potential
Energy sources
Functional expanded broad learning system
Irradiance
Kernel learning
Lyapunov criteria
Maximum power point tracking
Microgrids
Photovoltaic
Photovoltaic cells
Robust control
Robustness
Sliding mode control
Stability analysis
Steady-state
Voltage
Voltage control
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Summary:In this paper, a robust functional expanded multikernel broad learning system (RFEMBLS) is proposed to compute the complex nonlinear solar photovoltaic (PV) reference voltage more accurately by importing the irradiance and temperature in different uncertainty conditions. The novel droop control mechanism is introduced to obtain reference current to reduce dependence on different connected renewable energy resources. An adaptive integral backstepping sliding mode controller (AIBSMC) is designed to control the DC bus voltage under different abnormal scenarios for the proposed DC microgrid. An asymptotical stability analysis is developed using Lyapunov theory for the PV-battery DC microgrid. A new adoption rule is proposed for the estimation of both references of PV voltage and battery current. Furthermore, the system steady-state error and tracking convergence of the error are improved by adding an integral action. The backstepping method based on the DC bus voltage feedback results in a faster response and negligible chattering. A sliding mode controller is proposed to improve the control precision and robustness. Finally, the proposed RFEMBLS-AIBSMC method is tested using dSPACE platform in the scale-down lab environment to verify the robustness, practicability, feasibility, and efficacy of the proposed system in the real-time scenario.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2023.3332641