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Dynamical Systems in Population Biology Softcover Repri Edition
Contributor(s): Zhao, Xiao-Qiang (Author)
ISBN: 3319859110     ISBN-13: 9783319859118
Publisher: Springer
OUR PRICE:   $123.49  
Product Type: Paperback - Other Formats
Published: July 2018
Qty:
Temporarily out of stock - Will ship within 2 to 5 weeks
Additional Information
BISAC Categories:
- Mathematics | Mathematical Analysis
- Mathematics | Applied
- Mathematics | Differential Equations - General
Dewey: 515.39
Series: CMS Books in Mathematics
Physical Information: 0.88" H x 6.14" W x 9.21" (1.33 lbs) 413 pages
 
Descriptions, Reviews, Etc.
Publisher Description:
Population dynamics is an important subject in mathematical biology. A cen- tral problem is to study the long-term behavior of modeling systems. Most of these systems are governed by various evolutionary equations such as difference, ordinary, functional, and partial differential equations (see, e. g., [165, 142, 218, 119, 55]). As we know, interactive populations often live in a fluctuating environment. For example, physical environmental conditions such as temperature and humidity and the availability of food, water, and other resources usually vary in time with seasonal or daily variations. Therefore, more realistic models should be nonautonomous systems. In particular, if the data in a model are periodic functions of time with commensurate period, a periodic system arises; if these periodic functions have different (minimal) periods, we get an almost periodic system. The existing reference books, from the dynamical systems point of view, mainly focus on autonomous biological systems. The book of Hess [106J is an excellent reference for periodic parabolic boundary value problems with applications to population dynamics. Since the publication of this book there have been extensive investigations on periodic, asymptotically periodic, almost periodic, and even general nonautonomous biological systems, which in turn have motivated further development of the theory of dynamical systems. In order to explain the dynamical systems approach to periodic population problems, let us consider, as an illustration, two species periodic competitive systems dUI dt = !I(t, Ul, U2), (0.