D.S. Jones, Michael Plank, B.D. Sleeman

November 9, 2009
by Chapman and Hall/CRC

Textbook
- 462 Pages
- 100 B/W Illustrations

ISBN 9781420083576 - CAT# C8357

Series: Chapman & Hall/CRC Mathematical and Computational Biology

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- Uses various differential equations to model biological behavior
- Discusses the modeling of biological phenomena, including the heartbeat cycle, chemical reactions, electrochemical pulses in the nerve, predator–prey models, tumor growth, and epidemics
- Explains how bifurcation and chaotic behavior play key roles in fundamental problems of biological modeling
- Presents a unique treatment of pattern formation in developmental biology based on Turing’s famous idea of diffusion-driven instabilities
- Provides answers to selected exercises at the back of the book
- Offers downloadable MATLAB files on www.crcpress.com

*Deepen students’ understanding of biological phenomena*

Suitable for courses on differential equations with applications to mathematical biology or as an introduction to mathematical biology, **Differential Equations and Mathematical Biology, Second Edition** introduces students in the physical, mathematical, and biological sciences to fundamental modeling and analytical techniques used to understand biological phenomena. In this edition, many of the chapters have been expanded to include new and topical material.

**New to the Second Edition**

- A section on spiral waves
- Recent developments in tumor biology
- More on the numerical solution of differential equations and numerical bifurcation analysis
- MATLAB
^{®}files available for download online - Many additional examples and exercises

This textbook shows how first-order ordinary differential equations (ODEs) are used to model the growth of a population, the administration of drugs, and the mechanism by which living cells divide. The authors present linear ODEs with constant coefficients, extend the theory to systems of equations, model biological phenomena, and offer solutions to first-order autonomous systems of nonlinear differential equations using the Poincaré phase plane. They also analyze the heartbeat, nerve impulse transmission, chemical reactions, and predator–prey problems. After covering partial differential equations and evolutionary equations, the book discusses diffusion processes, the theory of bifurcation, and chaotic behavior. It concludes with problems of tumor growth and the spread of infectious diseases.

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