Chaotic Fractional-Order Model for Muscular Blood Vessel and its Control via Fractional Control Scheme

This article studies the chaotic and complex behavior in a fractional-order biomathematical model of a muscular blood vessel (MBV). It is shown that the fractional-order MBV (FOMBV) model exhibits very complex and rich dynamics such as chaos. We show that the corresponding maximal Lyapunov exponent of the FOMBV system is positive which implies the existence of chaos. Strange attractors of the FOMBV model are depicted to validate the chaotic behavior of the system. We change the fractional order of the model and investigate the dynamics of the system. To suppress the chaotic behavior of the model, we propose a single input fractional finite-time controller and prove its stability using the fractional Lyapunov theory. In addition, the effects of the model uncertainties and external disturbances are taken into account and a robust fractional finite-time controller is constructed. The upper bound of the chaos suppression time is also given. Some computer simulations are presented to illustrate the findings of this article. (C) 2014 Wiley Periodicals, Inc.