United States
£ GBP
The conjoining of nonlinear dynamics and biology has brought about significant advances in both areas, with nonlinear dynamics providing a tool for understanding biological phenomena and biology stimulating developments in the theory of dynamical systems. This research monograph provides an introduction to the theory of nonautonomous semiflows with applications to population dynamics.
Introduction.- Discrete Dynamical Systems.- Monotone Dynamics.- Nonautonomous Semiflows.- A Discrete-time Chemostat Model.- N-species Competition in a Periodic Chemostat.- Almost Periodic Competitive Systems.- Competitor-Competitor-Mutualist Systems.- A Periodically Pulsed Bioreactor Model.- A Nonlocal and Delayed Predator-Prey Model.- Traveling Waves in Bistable Nonlinearities.- Bibliography.- Index.
Dr. Xiao-Qiang Zhao is a professor in applied mathematics at Memorial University of Newfoundland, Canada. His main research interests involve applied dynamical systems, nonlinear differential equations, and mathematical biology. He is the author of more than 40 papers and his research has played an important role in the development of the theory of periodic and almost periodic semiflows and their applications.
From the reviews: "This is a highly technical research monograph which will be mainly of interest to those working in the field of mathematical population dynamics. ! The book provides a comprehensive coverage of the latest theoretical developments, particularly in the purely mathematical sophistications of the field ! ." (Tony Crilly, The Mathematical Gazette, March, 2005) "This book provides an introduction to the theory of periodic semiflows on metric spaces and their applications to population dynamics. ! This book will be most useful to mathematicians working on nonlinear dynamical models and their applications to biology." (R.Burger, Monatshefte fur Mathematik, Vol. 143 (4), 2004) "The main purpose of the book, in the author's words, 'is to provide an introduction to the theory of periodic semiflows on metric spaces' and to apply this theory to a collection of mathematical equations from population dynamics. ! The book presents its mathematical theory in a coherent and readable fashion. It should prove to be a valuable resource for mathematicians who are interested in non-autonomous dynamical systems and in their applications to biologically inspired models." (J. M. Cushing, Mathematical Reviews, 2004 f)
