Sliding mode control of double input buck buck–boost fused converter

This paper develops a hysteresis band‐based multivariable sliding mode control (SMC) for the double input buck buck–boost fused converter. The considered converter is operated at a controlled output voltage, while supplied from two different levels of input voltages from two different sources. The p...

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Bibliographic Details
Published in:Asian journal of control 2022-03, Vol.24 (2), p.845-858
Main Authors: Sen, Dibyendu, Saha, Tapas Kumar, Dey, Jayati
Format: Article
Language:English
Subjects:
Converters
DC–DC converter
Dependent variables
Electric potential
MATLAB simulation
Multivariable control
Perturbation
real‐time system
Sliding mode control
Stability analysis
Voltage
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Summary:This paper develops a hysteresis band‐based multivariable sliding mode control (SMC) for the double input buck buck–boost fused converter. The considered converter is operated at a controlled output voltage, while supplied from two different levels of input voltages from two different sources. The proposed control is to ensure the faster time of responses during the variation in the dual references, the output voltage, and low‐voltage source current, simultaneously. The controller is developed by considering these two controlled variables, which are directly dependent on each other. This multivariable SMC is shown to perform successfully to maintain the controlled variables at their desired values despite the variation in the input voltage sources and also during perturbation in the load impedance. The stability analysis for the closed‐loop system is established with the Lyapunov method, which confirms that both of the controlled variables reach the desired stable band at the steady state. The control is implemented in the simulation environment for different operating conditions. A laboratory prototype is developed to implement the multivariable SMC. The experimental results successfully validate their simulated counterparts.
ISSN:1561-8625
1934-6093
DOI:10.1002/asjc.2481