by Stefan Heinz (Author)
Mathematical modelling had become such an integral tool modern science and technology that practically all students take a course or otherwise need to master it. This textbook for undergraduate and graduate students of engineering, biology, chemistry, physics and even economics derives from the author's decade of teaching university courses It features systematic development of deterministic and stochastic modeling approaches; systematic discussions of single problems: the analysis of observations, characteristic properties and changes of one variable, and the laws that govern the evolution of one and several variables; and hierarchical development of models such as discussion of statistically most-likely probability density functions, the relations between difference and differential equations, the Brownian motion model and diffusion models, the delay logistic model, non-Markovian and Markovian velocity models, etc. Comprehensive in scope, it includes the derivations with all required details (exercises are used to provide additional details), complete discussions of problems, and practice in application of the developed concepts via 570 exercise questions organized in 220 problems. Detailed solutions given in the Instructor's Solutions Manual, which is available to instructors via springer.com. Prerequisites include 2-3 semesters of college-level calculus and familiarity with computer-algebra software (e.g. Matlab, Maple, or Mathematica). The author explains how the ten chapters can be combined to provide material for an undergraduate course Introduction to Mathematical Modeling or graduate-level courses Deterministic Mathematical Modeling and Stochastic Mathematical Modeling.
Back Jacket
The whole picture of Mathematical Modeling is systematically and thoroughly explained in this text for undergraduate and graduate students of mathematics, engineering, economics, finance, biology, chemistry, and physics. This textbook gives an overview of the spectrum of modeling techniques, deterministic and stochastic methods, and first-principle and empirical solutions.
Complete range: The text continuously covers the complete range of basic modeling techniques: it provides a consistent transition from simple algebraic analysis methods to simulation methods used for research. Such an overview of the spectrum of modeling techniques is very helpful for the understanding of how a research problem considered can be appropriately addressed.
Complete methods: Real-world processes always involve uncertainty, and the consideration of randomness is often relevant. Many students know deterministic methods, but they do hardly have access to stochastic methods, which are described in advanced textbooks on probability theory. The book develops consistently both deterministic and stochastic methods. In particular, it shows how deterministic methods are generalized by stochastic methods.
Complete solutions: A variety of empirical approximations is often available for the modeling of processes. The question of which assumption is valid under certain conditions is clearly relevant. The book provides a bridge between empirical modeling and first-principle methods: it explains how the principles of modeling can be used to explain the validity of empirical assumptions. The basic features of micro-scale and macro-scale modeling are discussed - which is an important problem of current research.
Author Biography
Dr. Stefan Heinz is a Professor of Mathematics at the University of Wyoming. He holds a Ph.D. in Physics from the Heinrich-Hertz Institute, Berlin. His research interests are in mathematical modeling, multiscale processes, stochastic analysis, Monte Carlo simulations, computational fluid dynamics, turbulence, combustion, and multiphase flows. He has authored more than seventy refereed publications and the textbook Statistical Mechanics of Turbulent Flows (Springer, 2003). For more than ten years he has taught a variety of courses: calculus, probability, ordinary, partial, and stochastic differential equations, applied mathematics, and deterministic and stochastic mathematical modeling. His exceptional teaching was awarded in 2007 by the College of Arts and Sciences Extraordinary Merit in Teaching Award. In 2008 he was honored as Adjunct Professor of Mechanical Engineering. He has held visiting professor appointments at ETH Zurich, Delft Technical University, and the National Center for Atmospheric Research (NCAR) at Boulder.