This paper presents an extension of the trapezoidal integration rule, that in the present work is applied to devise a pseudo-recursive numerical algorithm for the numerical evaluation of fractional-order integrals. The main benefit of pseudo recursive implementation arises in terms of higher accuracy when the algorithm is run in the "short memory" version. The rule is suitably generalized in order to build a numerical solver for a class of fractional differential equations. The algorithm is also specialized to derive an efficient numerical algorithm for the on-line implementation of linear fractional order controllers. The accuracy of the method is theoretically analyzed and its effectiveness is illustrated by simulation examples
We present an extrapolation type algorithm for the numerical solution of fractional order differenti...
Multi-term fractional differential equations have been used to simulate fractional-order control sys...
Today, many systems are characterized by a non-integer order model based on fractional calculus. Fra...
This paper presents an extension of the trapezoidal integration rule, that in the present work is ap...
This paper presents an extension of the well-known trapezoidal (bilinear) integration rule, that in ...
The paper describes different approaches to generalize the trapezoidal method to fractional differen...
This paper deals with the numerical solution of Fractional Differential Equations by means of m-step...
This paper deals with the numerical solution of Fractional Differential Equations by means of m-step...
This paper presents a numerical technique for solving fractional integrals of functions by employing...
This work is concerned with a comparison of some explicit methods for differential equations of frac...
This paper presents a numerical algorithm for solving a class of nonlinear optimal control problems ...
In the recent decades, fractional order systems have been found to be useful in many areas of physic...
The main objective of this paper is to investigate a new fractional mathematical model that includes...
Real objects in general are fractional-order systems, although in some types of systems the order is...
We present an extrapolation type algorithm for the numerical solution of fractional order differenti...
Multi-term fractional differential equations have been used to simulate fractional-order control sys...
Today, many systems are characterized by a non-integer order model based on fractional calculus. Fra...
This paper presents an extension of the trapezoidal integration rule, that in the present work is ap...
This paper presents an extension of the well-known trapezoidal (bilinear) integration rule, that in ...
The paper describes different approaches to generalize the trapezoidal method to fractional differen...
This paper deals with the numerical solution of Fractional Differential Equations by means of m-step...
This paper deals with the numerical solution of Fractional Differential Equations by means of m-step...
This paper presents a numerical technique for solving fractional integrals of functions by employing...
This work is concerned with a comparison of some explicit methods for differential equations of frac...
This paper presents a numerical algorithm for solving a class of nonlinear optimal control problems ...
In the recent decades, fractional order systems have been found to be useful in many areas of physic...
The main objective of this paper is to investigate a new fractional mathematical model that includes...
Real objects in general are fractional-order systems, although in some types of systems the order is...
We present an extrapolation type algorithm for the numerical solution of fractional order differenti...
Multi-term fractional differential equations have been used to simulate fractional-order control sys...
Today, many systems are characterized by a non-integer order model based on fractional calculus. Fra...