Login
Search manual

Details

Title De Gruyter textbook. — Elements of partial differential equations. — Second, revised and extended edition.
Creators Drábek Pavel
Other creators Holubová Gabriela
Collection Электронные книги зарубежных издательств ; Общая коллекция
Subjects Differential equations, Partial — Textbooks. ; Differential equations, Partial. ; MATHEMATICS / Calculus ; MATHEMATICS / Mathematical Analysis ; EBSCO eBooks
Document type Other
File type PDF
Language English
Rights Доступ по паролю из сети Интернет (чтение, печать, копирование)
Record key ocn903960828
Record create date 2/12/2015

Allowed Actions

pdf/809494.pdf
Action 'Read' will be available if you login or access site from another network Action 'Download' will be available if you login or access site from another network
epub/809494.epub
Action 'Download' will be available if you login or access site from another network
Group Anonymous
Network Internet
Network User group Action
ILC SPbPU Local Network All
Read Print Download
Internet Authorized users SPbPU
Read Print Download
Internet Anonymous
  • Preface
  • Contents
  • 1 Motivation, Derivation of Basic Mathematical Models
    • 1.1 Conservation Laws
      • 1.1.1 Evolution Conservation Law
      • 1.1.2 Stationary Conservation Law
      • 1.1.3 Conservation Law in One Dimension
    • 1.2 Constitutive Laws
    • 1.3 Basic Models
      • 1.3.1 Convection and Transport Equation
      • 1.3.2 Diffusion in One Dimension
      • 1.3.3 Heat Equation in One Dimension
      • 1.3.4 Heat Equation in Three Dimensions
      • 1.3.5 String Vibrations and Wave Equation in One Dimension
      • 1.3.6 Wave Equation in Two Dimensions – Vibrating Membrane
      • 1.3.7 Laplace and Poisson Equations – Steady States
    • 1.4 Exercises
  • 2 Classification, Types of Equations, Boundary and Initial Conditions
    • 2.1 Basic Types of Equations
    • 2.2 Classical, General, Generic and Particular Solutions
    • 2.3 Boundary and Initial Conditions
    • 2.4 Well-Posed and Ill-Posed Problems
    • 2.5 Classification of Linear Equations of the Second Order
    • 2.6 Exercises
  • 3 Linear Partial Differential Equations of the First Order
    • 3.1 Equations with Constant Coefficients
      • 3.1.1 Geometric Interpretation – Method of Characteristics
      • 3.1.2 Coordinate Method
      • 3.1.3 Method of Characteristic Coordinates
    • 3.2 Equations with Non-Constant Coefficients
      • 3.2.1 Method of Characteristics
      • 3.2.2 Method of Characteristic Coordinates
    • 3.3 Problems with Side Conditions
    • 3.4 Solution in Parametric Form
    • 3.5 Exercises
  • 4 Wave Equation in One Spatial Variable – Cauchy Problem in R
    • 4.1 General Solution of the Wave Equation
      • 4.1.1 Transformation to System of Two First Order Equations
      • 4.1.2 Method of Characteristics
    • 4.2 Cauchy Problem on the Real Line
    • 4.3 Principle of Causality
    • 4.4 Wave Equation with Sources
      • 4.4.1 Use of Green’s Theorem
      • 4.4.2 Operator Method
    • 4.5 Exercises
  • 5 Diffusion Equation in One Spatial Variable – Cauchy Problem in R
    • 5.1 Cauchy Problem on the Real Line
    • 5.2 Diffusion Equation with Sources
    • 5.3 Exercises
  • 6 Laplace and Poisson Equations in Two Dimensions
    • 6.1 Invariance of the Laplace Operator
    • 6.2 Transformation of the Laplace Operator into Polar Coordinates
    • 6.3 Solutions of Laplace and Poisson Equations in R2
      • 6.3.1 Laplace Equation
      • 6.3.2 Poisson Equation
    • 6.4 Exercises
  • 7 Solutions of Initial Boundary Value Problems for Evolution Equations
    • 7.1 Initial Boundary Value Problems on Half-Line
      • 7.1.1 Diffusion and Heat Flow on Half-Line
      • 7.1.2 Wave on the Half-Line
      • 7.1.3 Problems with Nonhomogeneous Boundary Condition
    • 7.2 Initial Boundary Value Problem on Finite Interval, Fourier Method
      • 7.2.1 Dirichlet Boundary Conditions, Wave Equation
      • 7.2.2 Dirichlet Boundary Conditions, Diffusion Equation
      • 7.2.3 Neumann Boundary Conditions
      • 7.2.4 Robin Boundary Conditions
      • 7.2.5 Principle of the Fourier Method
    • 7.3 Fourier Method for Nonhomogeneous Problems
      • 7.3.1 Nonhomogeneous Equation
      • 7.3.2 Nonhomogeneous Boundary Conditions and Their Transformation
    • 7.4 Transformation to Simpler Problems
      • 7.4.1 Lateral Heat Transfer in Bar
      • 7.4.2 Problem with Convective Term
    • 7.5 Exercises
  • 8 Solutions of Boundary Value Problems for Stationary Equations
    • 8.1 Laplace Equation on Rectangle
    • 8.2 Laplace Equation on Disc
    • 8.3 Poisson Formula
    • 8.4 Exercises
  • 9 Methods of Integral Transforms
    • 9.1 Laplace Transform
    • 9.2 Fourier Transform
    • 9.3 Exercises
  • 10 General Principles
    • 10.1 Principle of Causality (Wave Equation)
    • 10.2 Energy Conservation Law (Wave Equation)
    • 10.3 Ill-Posed Problem (Diffusion Equation for Negative t)
    • 10.4 Maximum Principle (Heat Equation)
    • 10.5 Energy Method (Diffusion Equation)
    • 10.6 Maximum Principle (Laplace Equation)
    • 10.7 Consequences of Poisson Formula (Laplace Equation)
    • 10.8 Comparison of Wave, Diffusion and Laplace Equations
    • 10.9 Exercises
  • 11 Laplace and Poisson equations in Higher Dimensions
    • 11.1 Invariance of the Laplace Operator and its Transformation into Spherical Coordinates
    • 11.2 Green’s First Identity
    • 11.3 Properties of Harmonic Functions
      • 11.3.1 Mean Value Property and Strong Maximum Principle
      • 11.3.2 Dirichlet Principle
      • 11.3.3 Uniqueness of Solution of Dirichlet Problem
      • 11.3.4 Necessary Condition for the Solvability of Neumann Problem
    • 11.4 Green’s Second Identity and Representation Formula
    • 11.5 Boundary Value Problems and Green’s Function
    • 11.6 Dirichlet Problem on Half-Space and on Ball
      • 11.6.1 Dirichlet Problem on Half-Space
      • 11.6.2 Dirichlet Problem on a Ball
    • 11.7 Exercises
  • 12 Diffusion Equation in Higher Dimensions
    • 12.1 Cauchy Problem in R3
      • 12.1.1 Homogeneous Problem
      • 12.1.2 Nonhomogeneous Problem
    • 12.2 Diffusion on Bounded Domains, Fourier Method
      • 12.2.1 Fourier Method
      • 12.2.2 Nonhomogeneous Problems
    • 12.3 General Principles for Diffusion Equation
    • 12.4 Exercises
  • 13 Wave Equation in Higher Dimensions
    • 13.1 Cauchy Problem in R3 – Kirchhoff’s Formula
    • 13.2 Cauchy Problem in R2
    • 13.3 Wave with Sources in R3
    • 13.4 Characteristics, Singularities, Energy and Principle of Causality
      • 13.4.1 Characteristics
      • 13.4.2 Energy
      • 13.4.3 Principle of Causality
    • 13.5 Wave on Bounded Domains, Fourier Method
    • 13.6 Exercises
  • A Sturm-Liouville Problem
  • B Bessel Functions
  • Some Typical Problems Considered in this Book
  • Notation
  • Bibliography
  • Index
pdf/809494.pdf

Access count: 0 
Last 30 days: 0

Detailed usage statistics

epub/809494.epub

Access count: 0 
Last 30 days: 0

Detailed usage statistics