Blas M. Vinagre scite author profile

This paper deals with the design of fractional order PI l D m controllers, in which the orders of the integral and derivative parts, l and m, respectively, are fractional. The purpose is to take advantage of the introduction of these two parameters and fulfill additional specifications of design, ensuring a robust performance of the controlled system with respect to gain variations and noise. A method for tuning the PI l D m controller is proposed in this paper to fulfill five different design specifications. Experimental results show that the requirements are totally met for the platform to be controlled. Besides, this paper proposes an auto-tuning method for this kind of controller. Specifications of gain crossover frequency and phase margin are fulfilled, together with the iso-damping property of the time response of the system. Experimental results are given to illustrate the effectiveness of this method. r

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Matrix approach to discrete fractional calculus II: Partial fractional differential equations

Podlubný

Chechkin

Škovránek

et al. 2009

Journal of Computational Physics

392

204

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a b s t r a c tA new method that enables easy and convenient discretization of partial differential equations with derivatives of arbitrary real order (so-called fractional derivatives) and delays is presented and illustrated on numerical solution of various types of fractional diffusion equation. The suggested method is the development of Podlubny's matrix approach [I. Podlubny, Matrix approach to discrete fractional calculus, Fractional Calculus and Applied Analysis 3 (4) (2000) . Four examples of numerical solution of fractional diffusion equation with various combinations of time-/space-fractional derivatives (integer/integer, fractional/integer, integer/fractional, and fractional/fractional) with respect to time and to the spatial variable are provided in order to illustrate how simple and general is the suggested approach. The fifth example illustrates that the method can be equally simply used for fractional differential equations with delays. A set of MATLAB routines for the implementation of the method as well as sample code used to solve the examples have been developed.

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Fractional order control strategies for power electronic buck converters

2006

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Two direct Tustin discretization methods for fractional-order differentiator/integrator

Vinagre

Chen

Petráš

2003

Journal of the Franklin Institute

327

141

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Continued Fraction Expansion Approaches to Discretizing Fractional Order Derivatives?an Expository Review

2004

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This paper attempts to present an expository review of continued fraction expansion (CFE) based discretization schemes for fractional order differentiators defined in continuous time domain. The schemes reviewed are limited to infinite impulse response (IIR) type generating functions of first and second orders, although high-order IIR type generating functions are possible. For the first-order IIR case, the widely used Tustin operator and Al-Alaoui operator are considered. For the second order IIR case, the generating function is obtained by the stable inversion of the weighted sum of Simpson integration formula and the trapezoidal integration formula, which includes many previous discretization schemes as special cases. Numerical examples and sample codes are included for illustrations.

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A new IIR-type digital fractional order differentiator

2003

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On Fractional PI? Controllers: Some Tuning Rules for Robustness to Plant Uncertainties

et al. 2004

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The objective of this work is to find out optimum settings for a fractional PI λ controller in order to fulfill three different robustness specifications of design for the compensated system, taking advantage of the fractional order, λ. Since this fractional controller has one parameter more than the conventional PI controller, one more specification can be fulfilled, improving the performance of the system and making it more robust to plant uncertainties, such as gain and time constant changes. For the tuning of the controller an iterative optimization method has been used, based on a nonlinear function minimization. Two real examples of application are presented and simulation results are shown to illustrate the effectiveness of this kind of unconventional controllers.

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Blas M. Vinagre

Fractional-order Systems and Controls

Tuning and auto-tuning of fractional order controllers for industry applications

Matrix approach to discrete fractional calculus II: Partial fractional differential equations

Fractional order control strategies for power electronic buck converters

Two direct Tustin discretization methods for fractional-order differentiator/integrator

Continued Fraction Expansion Approaches to Discretizing Fractional Order Derivatives?an Expository Review

A new IIR-type digital fractional order differentiator

On Fractional PI? Controllers: Some Tuning Rules for Robustness to Plant Uncertainties

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