This note explains the
following topics: Linear Algebra, Fourier series, Fourier transforms, Complex
integration, Distributions, Bounded Operators, Densely Defined Closed Operators,
Normal operators, Calculus of Variations, Perturbation theory.
This book explains the following topics:
Introduction to Modeling, Natural Numbers and Integers, Mathematical Induction,
Rational Numbers, Pythagoras and Euclid, Polynomial functions, Combinations of
functions, Lipschitz Continuity, Sequences and limits, The Square Root of Two,
Real numbers, Fixed Points and Contraction Mappings, Complex Numbers, The
Derivative, Differentiation Rules, Newton’s Method, Galileo, Newton, Hooke,
Malthus and Fourier.
Eriksson, Don Estep and Claes Johnson
This Handbook of Mathematics is designed to contain, in compact form,
accurate statements of those facts and formulas of pure mathematics which are
most likely to be useful to the worker in applied mathematics. Many topics of
an elementary character are presented in a form which permits of immediate
utilization even by readers who have had no previous acquaintance with the
subject; for example, the practical use of logarithms and logarithmic
cross-section paper, and the elementary parts of the modern method of
nomography (alignment charts), can be learned from this book without the
necessity of consulting separate treatises.
This lecture note covers the
following topics related to applied mathematics: Dimensional Analysis, Scaling,
and Similarity, Calculus of Variations, Sturm-Liouville Eigenvalue Problems and
This book covers the following topics in applied mathematics: Linear
Algebraic Systems, Vector Spaces and Bases, Inner Products and Norms,
Minimization and Least Squares Approximation, Orthogonality, Equilibrium,
Linearity, Eigenvalues, Linear Dynamical Systems, Iteration of Linear Systems,
Boundary Value Problems in One Dimension, Fourier Series, Fourier Analysis,
Vibration and Diffusion in One-Dimensional Media, The Laplace Equation, Complex
Analysis, Dynamics of Planar Media, Partial Differential Equations in Space,
Nonlinear Systems, Nonlinear Ordinary Differential Equations, The Calculus of
Variations and Nonlinear Partial Differential Equations.
This course note develops mathematical techniques which
are useful in solving `real-world' problems involving differential equations,
and is a development of ideas which arise in the second year differential
equations course. This note embraces the ethos of mathematical modelling, and
aims to show in a practical way how equations `work', and what kinds of
solution behaviours can occur.