Comparison of Quantitative Feedback Theory Dependent Controller with Conventional PID and Sliding Mode Controllers on DC-DC Boost Converter for Microgrid Applications

Singh, Akash; Ghosh, Arnab

doi:10.1007/s40866-022-00133-2

Cited by 9 publications

(2 citation statements)

References 27 publications

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“…[45] presented the cascade system control design and stability analysis for a DC-DC boost converter with proportional integral and sliding mode controller and using singular perturbation theory. Some versions of sliding mode control approaches were presented in [48]- [54]. [53] presented an implementation of sliding mode voltage control controlled buck-boost converter for solar photovoltaic system.…”

Section: Introductionmentioning

confidence: 99%

A Passivity-based Control Combined with Sliding Mode Control for a DC-DC Boost Power Converter

Huynh,

Duong,

Nguyen

2023

Journal of Robotics and Control

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In this paper, a passivity-based control combined with sliding mode control for a DC-DC boost power converter is proposed. Moreover, a passivity-based control for a DC-DC boost power converter is also proposed. Using a co-ordinate transformation of state variables and control input, a DC-DC boost power converter is passive. A new plant is zero-state observable and the equilibrium point at origin of this plant is asymptotically stable. Then, a passivity-based control is applied to this plant such that the capacitor voltage is equal to the desired voltage. Additionally, the sliding mode control law is chosen such that the derivative of Lyapunov function is negative semidefinite. Finally, a passivity-based control combined with sliding mode control law is applied to this plant such that the capacitor voltage is equal to the desired voltage. The simulation results of the passivity-based control, the sliding mode control and the passivity-based control combined with sliding mode control demonstrate the effectiveness and show that the capacitor voltage is kept at the desired voltage when the desired voltage, the input voltage E and the load resistor R are changed. The results show that compared with the passivity-based control, the passivity-based control combined with sliding mode control has better performance such as shorter settling time, 8.5 ms when R changes and it has smaller steady-state error, which is indicated by the value of integral absolute error (IAE), 0.0679 when the desired voltage changes. The paper has limitations such as the assumed circuit parameters.

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Section: Introductionmentioning

confidence: 99%

A Passivity-based Control Combined with Sliding Mode Control for a DC-DC Boost Power Converter

Huynh,

Duong,

Nguyen

2023

Journal of Robotics and Control

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“…Introduction DC-DC converters, which are the most applied circuit among the four major converter circuits in power electronics, have been widely used in new energy photovoltaic power generation, electric vehicle drive control, and switching power supplies [1] . The DC-DC converter is regarded as a power electronic nonlinear control system, to improve the static characteristics and dynamic indicators of the system so that the system has a good response speed and anti-interference ability, and the control policy has become one of the hot spots of research [2] . DC-DC converter commonly used voltage single-loop control, the structure is simple and easy to implement, but the response speed to the load jump is slow.…”

mentioning

confidence: 99%

Study of Fractional Order PI DC-DC Converter Based on Dual Closed-loop Control

Wei

et al. 2023

J. Phys.: Conf. Ser.

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In this paper, the dual closed-loop control strategy with fractional-order PI is applied to the field of the DC-DC converter, which effectively improves the dynamic performance and static performance of the output voltage of the power electronic DC chopper converter. The open-loop transfer function of the Boost converter is obtained by modeling and analyzing the operating principle and small-signal model of the Boost converter, and the fractional-order PI parameters of the double closed-loop control are obtained by combining the frequency-domain analysis design method of control theory. The Simulink simulation model is built, and the fractional-order PI control model is compared and analyzed with the single-voltage loop control and the integer-order PI control model. The results show that the fractional-order PI-controlled Boost converter has a faster response and stronger anti-interference capability, which effectively improves the dynamic performance and static performance index of the DC-DC converter and provides a theoretical basis for the research of dual closed-loop control strategy of the DC-DC converter.

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Modified direct torque control algorithm for regeneration capability of IM driven electric vehicle by using hybrid energy storage system

Tiwari,

Ghosh,

Sain

et al. 2024

Renewable Energy Focus

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Comparison of Quantitative Feedback Theory Dependent Controller with Conventional PID and Sliding Mode Controllers on DC-DC Boost Converter for Microgrid Applications

Cited by 9 publications

References 27 publications

A Passivity-based Control Combined with Sliding Mode Control for a DC-DC Boost Power Converter

A Passivity-based Control Combined with Sliding Mode Control for a DC-DC Boost Power Converter

Study of Fractional Order PI DC-DC Converter Based on Dual Closed-loop Control

Modified direct torque control algorithm for regeneration capability of IM driven electric vehicle by using hybrid energy storage system

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