Produktbild: Mathematica for Physicists and Engineers
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Mathematica for Physicists and Engineers

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Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

12.07.2023

Abbildungen

schwarz-weiss Illustrationen

Verlag

Wiley-VCH

Seitenzahl

416

Maße (L/B/H)

24,4/3/5,3 cm

Gewicht

798 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-3-527-41424-6

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

12.07.2023

Abbildungen

schwarz-weiss Illustrationen

Verlag

Wiley-VCH

Seitenzahl

416

Maße (L/B/H)

24,4/3/5,3 cm

Gewicht

798 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-3-527-41424-6

Herstelleradresse

Wiley-VCH GmbH
Boschstraße 12
69469 Weinheim
DE

Email: GPSR Kontakt

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  • Produktbild: Mathematica for Physicists and Engineers
  • Preface xiii

    Foreword xvii

    About the Authors xix

    1 Preliminary Notions 1

    1.1 Introduction 1

    1.2 Versions of Mathematica 1

    1.3 Getting Started 2

    1.4 Simple Calculations 2

    1.4.1 Arithmetic Operations 2

    1.4.2 Approximate Numerical Results 3

    1.4.3 Algebraic Calculations 3

    1.4.4 Defining Variables 4

    1.4.5 Using the Previous Results 5

    1.4.6 Suppressing the Output 6

    1.4.7 Sequences of Operations 6

    1.5 Built-in Functions 7

    1.6 Additional Features 9

    1.6.1 Arbitrary-Precision Calculations 9

    1.6.2 Value for Symbols 10

    1.6.3 Defining Naming and Evaluating Functions 10

    1.6.4 Composition of Functions 11

    1.6.5 Conditional Assignment 12

    1.6.6 Warnings and Messages 13

    1.6.7 Interrupting Calculations 13

    1.6.8 Using Symbols to Tag Objects 13

    2 Basic Mathematical Operations 15

    2.1 Introduction 15

    2.2 Basic Algebraic Operations 15

    2.3 Basic Trigonometric Operations 20

    2.4 Basic Operations with Complex Numbers 21

    3 Lists and Tables 25

    3.1 Introduction 25

    3.2 Lists 25

    3.3 Arrays 26

    3.4 Tables 26

    3.5 Extracting the Elements from the Arrays/Tables 29

    4 Two-Dimensional Graphics 31

    4.1 Introduction 31

    4.2 Plotting Functions of a Single Variable 31

    4.3 Additional Commands 34

    4.4 Plot Styles 44

    4.5 Probability Distribution 58

    4.5.1 Binomial Distribution 58

    4.5.2 Poisson Distribution 58

    4.5.3 Normal or Gaussian Distribution 59

    4.6 Some More Useful Commands 61

    5 Parametric, Polar, Contour, Density, and List Plots 65

    5.1 Introduction 65

    5.2 Parametric Plotting 65

    5.3 Polar Plots 72

    5.3.1 Polar Plots of Circles 72

    5.3.2 Polar Plots of Ellipse, Parabola, and Hyperbola 72

    5.4 Implicit Plot 80

    5.5 Contour Plots 81

    5.6 Density Plot 85

    5.7 ListPlot and ListLinePlot 85

    5.8 LogPlot, LogLogPlot, ErrorListPlot 88

    5.9 Least Square Fit 89

    5.10 Plotting of Complex Numbers 92

    6 Three-Dimensional Graphics 97

    6.1 Introduction 97

    6.2 Plotting Function of Two Variables 97

    6.3 Parametric Plots 101

    6.4 3D Plots in Cylindrical and Spherical Coordinates 102

    6.5 ContourPlot3D 105

    6.6 ListContourPlot3D 108

    6.7 ListSurfacePlot3D 110

    6.8 Surface of Revolution 112

    6.9 Conicoids 114

    7 Matrices 123

    7.1 Introduction 123

    7.2 Properties of Matrices 123

    7.2.1 Matrix Multiplication 123

    7.3 Types of Matrices 123

    7.4 The Rank of the Matrix 124

    7.5 Special Matrices 124

    7.6 Creation of a Matrix and Matrix Operations 125

    7.6.1 Extraction of the Submatrices or the Elements of the Matrices 126

    7.7 Properties of the Special Matrices 133

    7.8 Direct Sum of Matrices 137

    7.9 Direct Product of Matrices 137

    7.10 Examples from Group Theory 138

    7.10.1 SO(3) Group 138

    7.10.2 SU(n)Group 139

    7.10.3 SU(2) Group 140

    7.10.4 SU(3) Group 141

    8 Solving Algebraic and Transcendental Equations 143

    8.1 Introduction 143

    8.2 Solving System of Linear Equations 143

    8.2.1 Number of Equations Equal to Number of Unknowns 144

    8.2.2 Number of Equations Less than the Number of Unknowns 146

    8.2.3 Number of Equations More than Number of Unknowns 146

    8.3 Nonlinear Algebraic Equations 147

    8.4 Solving Complex Equations 149

    8.5 Solving Transcendental Equations 153

    9 Eigenvalues and Eigenvectors of a Matrix 161

    9.1 Introduction 161

    9.2 Eigenvalues and Eigenvectors 161

    9.2.1 Distinct Eigenvalues Having Independent Eigenvectors 162

    9.2.2 Multiple Eigenvalues Having Independent Eigenvectors 163

    9.2.3 Multiple Eigenvalues Not Having Independent Eigenvectors 165

    9.3 Cayley-Hamilton Theorem 166

    9.4 Diagonalization of a Matrix 167

    9.4.1 Gram-Schmidt Orthogonalization Method 167

    9.4.2 Diagonalizability of a Matrix 169

    9.4.3 Case of a Non-diagonalizable Matrix 170

    9.5 Some More Properties of the Special Matrices 172

    9.6 Power of a Matrix 173

    9.6.1 Roots of a Matrix 174

    9.6.2 Exponential of a Matrix 174

    9.6.3 Logarithm of a Matrix 174

    9.6.4 Matrix Power Series 174

    9.7 Power of a Matrix by Diagonalization 174

    9.8 Bilinear, Quadratic, and Hermitian Forms 177

    9.9 Principal Axes Transformation 178

    10 Differential Calculus 183

    10.1 Introduction 183

    10.2 Limits 183

    10.2.1 Evaluation of the Limits Using L'Hospital's Rule 184

    10.2.2 Application of L'Hospital's Rule for the "Indeterminate Form" ¿ 185 ¿

    10.2.3 Evaluation of the Limit Using Taylor's Theorem of Mean 186

    10.3 Differentiation 188

    10.3.1 Computation of Partial Derivatives 191

    10.3.2 Total Derivative 193

    10.4 Derivatives of Functions in Parametric Forms 195

    10.4.1 Chain Rule for a Function of Two Independent Variables 196

    10.4.2 Chain Rule for a Function of Three Independent Variables 196

    10.5 Rolle's Theorem 198

    10.6 Mean Value Theorem 198

    10.7 Series 200

    10.8 Maxima and Minima 209

    10.8.1 First Derivative Test 210

    10.8.2 Second Derivative Test 211

    10.8.3 Maximum and Minimum Values of a Function in a Closed Interval 213

    10.8.4 Maxima and Minima of Two Variables 218

    10.9 Differential Equations 222

    10.9.1 Simple Harmonic Oscillator 225

    10.9.2 LCR Circuit - Discharging of a Condenser Through an LR Circuit 227

    11 Integral Calculus 235

    11.1 Introduction 235

    11.1.1 Indefinite Integral 235

    11.1.2 Definite Integral 235

    11.1.3 Numerical Value of the Integral 235

    11.1.4 Assumptions While Evaluating the Integral 236

    11.1.5 Multiple Integrals 236

    11.1.6 Triple Integral 236

    11.2 Evaluation of Indefinite Integrals 236

    11.3 Evaluation of Definite Integrals 238

    11.3.1 Numerical Value of the Integral 238

    11.3.2 Options for Integration 239

    11.4 Two and Three-Dimensional Integrals 240

    11.5 Evaluation of the Integral in Polar Coordinates 242

    11.6 Evaluation of Special Integrals 242

    11.7 Orthogonal Polynomials 248

    11.8 Area Between Curves 252

    11.9 Application of Green's Theorem in a Plane 256

    11.10 Area of Surfaces of Revolution 257

    12 Dirac Delta Function 263

    12.1 Introduction 263

    12.2 The Limiting Form of the Dirac Delta Function 263

    12.3 Integral Representation of the Dirac Delta Function 265

    12.4 Some Important Properties of the Dirac Delta Function 267

    12.5 The Three-Dimensional Dirac Delta Function 270

    13 Fourier Transforms 273

    13.1 Introduction 273

    13.2 Fourier Transforms 273

    13.3 Scaling Property 280

    13.4 Shifting Property 280

    13.5 Fourier Sine and Cosine Transforms 281

    13.6 Fourier Transform of the Derivative 282

    13.7 Inverse Fourier Transform 282

    13.8 Convolution 283

    13.9 Convolution Theorem for Fourier Transforms 291

    13.10 Parseval's Theorem 293

    14 Laplace Transforms 295

    14.1 Introduction 295

    14.2 Some Simple Examples 296

    14.3 Properties of the Laplace Transforms 297

    14.3.1 Linearity 297

    14.3.2 Shifting Property 297

    14.3.3 Scaling Property 297

    14.4 Laplace Transform of the Derivative 298

    14.5 Laplace Transform of Certain Special Functions 299

    14.6 The Laplace Transform of Error and Complementary Error Functions 300

    14.7 The Evaluation of a Certain Class of Definite Integrals Using Laplace Transforms 300

    14.8 The Inverse Laplace Transform 302

    14.8.1 Inverse Laplace Transform of Standard Functions 303

    14.8.2 Shifting Properties 303

    14.8.3 Inverse Laplace Transforms of Derivatives 305

    14.9 Solving the Differential Equation by Laplace Transform 306

    14.10 Convolution Theorem 307

    14.11 Graphical Treatment of the Convolution 308

    15 Vectors 315

    15.1 Introduction 315

    15.2 Properties 315

    15.3 Vector Differentiation 319

    15.4 Directional Derivative 320

    15.5 Unit Vector Normal to the Surface 320

    15.6 Gradient, Divergence, and Curl in the Cartesian Coordinate System 320

    15.6.1 Gradient 320

    15.6.2 Divergence 321

    15.6.3 Curl 321

    15.6.4 Laplacian Operator (¿ 2) 321

    15.6.5 Examples 322

    15.7 Expressing the Gradient, Divergence, and Curl in Other Coordinate Systems 326

    15.7.1 Spherical Coordinate System 326

    15.7.2 Cylindrical Coordinate System 330

    15.8 Vector Plots 337

    16 Linear Vector Spaces and Quantum Mechanics 343

    16.1 Introduction 343

    16.2 Linear Independence, Basis, and Dimension 343

    16.3 Dimension of the Vector Space 343

    16.4 Basis of the Vector Space 343

    16.5 Completeness 344

    16.6 Scalar Product in a Linear Vector Space 344

    16.7 Norm of the Vector 344

    16.8 Orthonormal Basis 344

    16.9 Linear Independence of Functions 348

    16.10 Hilbert Space 349

    16.11 Completeness in Functional Space 350

    16.12 The Dirac Ket and Bra Notation 351

    16.12.1 The Scalar Product of Kets and Bras 351

    16.12.2 Schwartz Inequality 352

    16.12.3 The Orthonormal States 352

    16.12.4 Basis 352

    16.12.5 Probability Density 352

    16.13 The Hermitian and Skew-Hermitian Operators in Dirac Ket and Bra Notation 352

    16.14 Expectation Values 353

    16.15 Matrix Representation of the Linear Operator 359

    17 Application of Mathematica to Quantum Mechanics 361

    17.1 Introduction 361

    17.2 A Particle in a One-Dimensional Box 361

    17.3 A Particle in a Two-Dimensional Box 365

    17.4 The Hydrogen Atom Problem 368

    17.4.1 The Orthonormal Property of the Hydrogen Atom Wave Functions 371

    17.5 The One-Dimensional Linear Harmonic Oscillator Atom Problem 373

    17.6 Three-Dimensional Harmonic Oscillator 377

    17.7 Miscellaneous Problems 382

    References 385

    Index 387