Time‐optimal control of DC‐DC buck converter using single‐input fuzzy augmented fractional‐order PI controller

Saleem, Omer; Shami, Umar Tabrez; Mahmood-ul-Hasan, Khalid

doi:10.1002/2050-7038.12064

Cited by 18 publications

(18 citation statements)

References 43 publications

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“…where b 1 , b 2 are the cognitive‐coefficients, r 1 , r 2 are random real numbers between 0 and 1, and w is the inertia weight. The cognitive coefficients are selected such that their sum is slightly greater than 4 . After initialization, the algorithm iteratively computes and records the fitness of the particles using the quadratic cost function given in Equation 37.

J_{fitness} = t_{s}^{2} + {M_{p}}^{2} + \int_{0}^{\infty} e^{2} ((), t) italicdt,

…”

Section: Particle Swarm Optimizationmentioning

confidence: 99%

“…Reasonable value of N and j max are empirically selected to prevent excessive computational burden on embedded processor. The parameters associated with the optimizer are clearly identified in Table . The controller parameters are optimized offline by applying a step input.…”

Section: Particle Swarm Optimizationmentioning

confidence: 99%

“…The cognitive coefficients are selected such that their sum is slightly greater than 4. 44 After initialization, the algorithm iteratively computes and records the fitness of the particles using the quadratic cost function given in Equation 37.…”

Section: Particle Swarm Optimizationmentioning

confidence: 99%

See 2 more Smart Citations

Self‐adaptive fractional‐order LQ‐PID voltage controller for robust disturbance compensation in DC‐DC buck converters

Saleem

Awan

Mahmood-ul-Hasan

et al. 2019

Int J Numerical Modelling

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This paper presents a state‐dependent self‐tuning fractional control strategy for a DC‐DC buck converter in order to enhance its output voltage regulation and disturbance attenuation capability. The proposed control scheme primarily employs a ubiquitous proportional‐integral‐derivative (PID) controller, where gains are optimally selected using a linear‐quadratic state‐space tuning approach. The optimal PID controller is then augmented with fractional‐order integral and derivative operators in order to improve the controller's degrees‐of‐freedom as well as the system's overall time‐domain performance. The fractional controller's robustness against bounded exogenous disturbances, contributed by the input fluctuations and load‐step transients, is further enhanced by adaptively modulating the fractional‐orders of the integro‐differential operators as a smooth nonlinear function of controlled‐variable's error‐dynamics. An online dynamic adjustment law, comprising of a zero‐mean Gaussian function of error and its derivative, is used to individually update the two fractional orders after every sampling interval. The error derivative is evaluated by measuring the output capacitor's current in order to compensate the noise injected by parasitic impedance. The other controller parameters are tuned via particle‐swarm‐optimization algorithm. The proposed self‐adaptive control strategy renders rapid transits, minimum transient recovery time, and minimal fluctuations around steady state in the response. Its efficacy is validated through hardware in‐the‐loop experiments conducted on a buck converter prototype.

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J_{fitness} = t_{s}^{2} + {M_{p}}^{2} + \int_{0}^{\infty} e^{2} ((), t) italicdt,

…”

Section: Particle Swarm Optimizationmentioning

confidence: 99%

Section: Particle Swarm Optimizationmentioning

confidence: 99%

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Self‐adaptive fractional‐order LQ‐PID voltage controller for robust disturbance compensation in DC‐DC buck converters

Saleem

Awan

Mahmood-ul-Hasan

et al. 2019

Int J Numerical Modelling

Self Cite

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“…Robustness in presences of uncertainties, unmodeled dynamics and non-linear loads, steady-state error reduction and perturbation rejection were the improvements. In (Saleem et al, 2019) and (Farsizadeh et al, 2019) fractional-order PI/PID controllers in combination with fuzzy-logic approach were suggested. The control strategy achieved voltage regulation via capacitor current to improve tracking performance, disturbance rejection and stability.…”

Section: Introductionmentioning

confidence: 99%

Experimental Validation of Voltage Regulation in Buck Converters through Fractional-Order PID Approximation

Soto-Vega

Soriano-Sánchez

2021

IJONEST

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Viability of a fractional-order PID approximation regulating voltage in buck converters through a single control loop is investigated. Fractional calculus approach is suggested due to it exhibits good robustness against parameter variations. The non-integer approach is integrated in the control strategy through a Laplacian operator biquadratic approximation to generate a flat phase curve in the system closed-loop frequency response, which results in the generation of the iso-damping characteristic. The synthesis and tuning process consider both robustness and closed-loop requirements to ensure a fast and stable regulation characteristic. Experimental data obtained with the resulting controller, which was easy implemented through RC circuits and OPAMPs in adder configuration, confirmed its effectiveness. Superiority of proposed approach, which is determined through a comparison with typical PID controllers, confirms its viability to be used in highly efficient converters, such as Silicon-Carbide ones.

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“…The fractional-order controller improved the steady state performance. In [19], a fractional-order PI controller is combined with fuzzy-logic precompensators to control a Buck converter via capacitor current. The combination improved the system disturbance-rejection capability and reference tracking performance.…”

mentioning

confidence: 99%

Fractional-Order Approximation and Synthesis of a PID Controller for a Buck Converter

et al. 2020

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In this paper, the approximation of a fractional-order PIDcontroller is proposed to control a DC–DC converter. The synthesis and tuning process of the non-integer PID controller is described step by step. A biquadratic approximation is used to produce a flat phase response in a band-limited frequency spectrum. The proposed method takes into consideration both robustness and desired closed-loop characteristics, keeping the tuning process simple. The transfer function of the fractional-order PID controller and its time domain representation are described and analyzed. The step response of the fractional-order PID approximation shows a faster and stable regulation capacity. The comparison between typical PID controllers and the non-integer PID controller is provided to quantify the regulation speed introduced by the fractional-order PID approximation. Numerical simulations are provided to corroborate the effectiveness of the non-integer PID controller.

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Time‐optimal control of DC‐DC buck converter using single‐input fuzzy augmented fractional‐order PI controller

Cited by 18 publications

References 43 publications

Self‐adaptive fractional‐order LQ‐PID voltage controller for robust disturbance compensation in DC‐DC buck converters

Self‐adaptive fractional‐order LQ‐PID voltage controller for robust disturbance compensation in DC‐DC buck converters

Experimental Validation of Voltage Regulation in Buck Converters through Fractional-Order PID Approximation

Fractional-Order Approximation and Synthesis of a PID Controller for a Buck Converter

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