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by E. Ward Cheney and David R. Kincaid

Edition: 6TH 08Copyright: 2008

Publisher: Brooks/Cole Publishing Co.

Published: 2008

International: No

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Authors Ward Cheney and David Kincaid show students of science and engineering the potential computers have for solving numerical problems and give them ample opportunities to hone their skills in programming and problem solving. The text also helps students learn about errors that inevitably accompany scientific computations and arms them with methods for detecting, predicting, and controlling these errors. A more theoretical text with a different menu of topics is the authors' highly regarded NUMERICAL ANALYSIS: MATHEMATICS OF SCIENTIFIC COMPUTING, THIRD EDITION.

1. INTRODUCTION. 1.1 Preliminary Remarks. 1.2 Review of Taylor Series.

2. FLOATING-POINT REPRESENTATION AND ERRORS. 2.1 Floating-Point Representation. 2.2 Loss of Significance.

3. LOCATING ROOTS OF EQUATIONS. 3.1 Bisection Method. 3.2 Newtonï¿½s Method. 3.3 Secant Method.

4. INTERPOLATION AND NUMERICAL DIFFERENTIATION. 4.1 Polynomial Interpolation. 4.2 Errors in Polynomial Interpolation. 4.3 Estimating Derivatives and Richardson Extrapolation.

5. NUMERICAL INTEGRATION. 5.1 Lower and Upper Sums. 5.2 Trapezoid Rule. 5.3 Romberg Algorithm.

6. ADDITIONAL TOPICS ON NUMERICAL INTEGRATION. 6.1 Simpsonï¿½s Rule and Adaptive Simpsonï¿½s Rule. 6.2 Gaussian Quadrature Formulas.

7. SYSTEMS OF LINEAR EQUATIONS. 7.1 Naive Gaussian Elimination. 7.2 Gaussian Elimination with Scaled Partial Pivoting. 7.3 Tridiagonal and Banded Systems.

8. ADDITIONAL TOPICS CONCERNING SYSTEMS OF LINEAR EQUATIONS. 8.1 Matrix Factorizations. 8.2 Iterative Solutions of Linear Systems. 8.3 Eigenvalues and Eigenvectors. 8.4 Power Method.

9. APPROXIMATION BY SPLINE FUNCTIONS. 9.1 First-Degree and Second-Degree Splines. 9.2 Natural Cubic Splines. 9.3 B Splines: Interpolation and Approximation.

10. ORDINARY DIFFERENTIAL EQUATIONS. 10.1 Taylor Series Methods. 10.2 Runge-Kutta Methods. 10.3 Stability and Adaptive Runge-Kutta and Multistep Methods.

11. SYSTEMS OF ORDINARY DIFFERENTIAL EQUATIONS. 11.1 Methods for First-Order Systems. 11.2 Higher-Order Equations and Systems. 11.3 Adams-Bashforth-Moulton Methods.

12. SMOOTHING OF DATA AND THE METHOD OF LEAST SQUARES. 12.1 Method of Least Squares. 12.2 Orthogonal Systems and Chebyshev Polynomials. 12.3 Other Examples of the Least-Squares Principle.

13. MONTE CARLO METHODS AND SIMULATION. 13.1 Random Numbers. 13.2 Estimation of Areas and Volumes by Monte Carlo Techniques. 13.3 Simulation.

14. BOUNDARY-VALUE PROBLEMS FOR ORDINARY DIFFERENTIAL EQUATIONS. 14.1 Shooting Method Shooting Method Algorithm. 14.2 A Discretization Method.

15. PARTIAL DIFFERENTIAL EQUATIONS. 15.1 Parabolic Problems. 15.2 Hyperbolic Problems. 15.3 Elliptic Problems.

16. MINIMIZATION OF FUNCTIONS. 16.1 One-Variable Case. 16.2 Multivariate Case.

17. LINEAR PROGRAMMING. 17.1 Standard Forms and Duality. 17.2 Simplex Method. 17.3 Approximate Solution of Inconsistent Linear Systems.

APPENDIX A. ADVICE ON GOOD PROGRAMMING PRACTICES. A.1 Programming Suggestions. APPENDIX B. REPRESENTATION OF NUMBERS IN DIFFERENT BASES. B.1 Representation of Numbers in Different Bases. APPENDIX C. ADDITIONAL DETAILS ON IEEE FLOATING-POINT ARITHMETIC. C.1 More on IEEE Standard Floating-Point Arithmetic. APPENDIX D. LINEAR ALGEBRA CONCEPTS AND NOTATION. D.1 Elementary Concepts. D.2 Abstract Vector Spaces. ANSWERS FOR SELECTED PROBLEMS. BIBLIOGRAPHY. INDEX.

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Summary

Authors Ward Cheney and David Kincaid show students of science and engineering the potential computers have for solving numerical problems and give them ample opportunities to hone their skills in programming and problem solving. The text also helps students learn about errors that inevitably accompany scientific computations and arms them with methods for detecting, predicting, and controlling these errors. A more theoretical text with a different menu of topics is the authors' highly regarded NUMERICAL ANALYSIS: MATHEMATICS OF SCIENTIFIC COMPUTING, THIRD EDITION.

Table of Contents

1. INTRODUCTION. 1.1 Preliminary Remarks. 1.2 Review of Taylor Series.

2. FLOATING-POINT REPRESENTATION AND ERRORS. 2.1 Floating-Point Representation. 2.2 Loss of Significance.

3. LOCATING ROOTS OF EQUATIONS. 3.1 Bisection Method. 3.2 Newtonï¿½s Method. 3.3 Secant Method.

4. INTERPOLATION AND NUMERICAL DIFFERENTIATION. 4.1 Polynomial Interpolation. 4.2 Errors in Polynomial Interpolation. 4.3 Estimating Derivatives and Richardson Extrapolation.

5. NUMERICAL INTEGRATION. 5.1 Lower and Upper Sums. 5.2 Trapezoid Rule. 5.3 Romberg Algorithm.

6. ADDITIONAL TOPICS ON NUMERICAL INTEGRATION. 6.1 Simpsonï¿½s Rule and Adaptive Simpsonï¿½s Rule. 6.2 Gaussian Quadrature Formulas.

7. SYSTEMS OF LINEAR EQUATIONS. 7.1 Naive Gaussian Elimination. 7.2 Gaussian Elimination with Scaled Partial Pivoting. 7.3 Tridiagonal and Banded Systems.

8. ADDITIONAL TOPICS CONCERNING SYSTEMS OF LINEAR EQUATIONS. 8.1 Matrix Factorizations. 8.2 Iterative Solutions of Linear Systems. 8.3 Eigenvalues and Eigenvectors. 8.4 Power Method.

9. APPROXIMATION BY SPLINE FUNCTIONS. 9.1 First-Degree and Second-Degree Splines. 9.2 Natural Cubic Splines. 9.3 B Splines: Interpolation and Approximation.

10. ORDINARY DIFFERENTIAL EQUATIONS. 10.1 Taylor Series Methods. 10.2 Runge-Kutta Methods. 10.3 Stability and Adaptive Runge-Kutta and Multistep Methods.

11. SYSTEMS OF ORDINARY DIFFERENTIAL EQUATIONS. 11.1 Methods for First-Order Systems. 11.2 Higher-Order Equations and Systems. 11.3 Adams-Bashforth-Moulton Methods.

12. SMOOTHING OF DATA AND THE METHOD OF LEAST SQUARES. 12.1 Method of Least Squares. 12.2 Orthogonal Systems and Chebyshev Polynomials. 12.3 Other Examples of the Least-Squares Principle.

13. MONTE CARLO METHODS AND SIMULATION. 13.1 Random Numbers. 13.2 Estimation of Areas and Volumes by Monte Carlo Techniques. 13.3 Simulation.

14. BOUNDARY-VALUE PROBLEMS FOR ORDINARY DIFFERENTIAL EQUATIONS. 14.1 Shooting Method Shooting Method Algorithm. 14.2 A Discretization Method.

15. PARTIAL DIFFERENTIAL EQUATIONS. 15.1 Parabolic Problems. 15.2 Hyperbolic Problems. 15.3 Elliptic Problems.

16. MINIMIZATION OF FUNCTIONS. 16.1 One-Variable Case. 16.2 Multivariate Case.

17. LINEAR PROGRAMMING. 17.1 Standard Forms and Duality. 17.2 Simplex Method. 17.3 Approximate Solution of Inconsistent Linear Systems.

APPENDIX A. ADVICE ON GOOD PROGRAMMING PRACTICES. A.1 Programming Suggestions. APPENDIX B. REPRESENTATION OF NUMBERS IN DIFFERENT BASES. B.1 Representation of Numbers in Different Bases. APPENDIX C. ADDITIONAL DETAILS ON IEEE FLOATING-POINT ARITHMETIC. C.1 More on IEEE Standard Floating-Point Arithmetic. APPENDIX D. LINEAR ALGEBRA CONCEPTS AND NOTATION. D.1 Elementary Concepts. D.2 Abstract Vector Spaces. ANSWERS FOR SELECTED PROBLEMS. BIBLIOGRAPHY. INDEX.

Publisher Info

Publisher: Brooks/Cole Publishing Co.

Published: 2008

International: No

Published: 2008

International: No

1. INTRODUCTION. 1.1 Preliminary Remarks. 1.2 Review of Taylor Series.

2. FLOATING-POINT REPRESENTATION AND ERRORS. 2.1 Floating-Point Representation. 2.2 Loss of Significance.

3. LOCATING ROOTS OF EQUATIONS. 3.1 Bisection Method. 3.2 Newtonï¿½s Method. 3.3 Secant Method.

4. INTERPOLATION AND NUMERICAL DIFFERENTIATION. 4.1 Polynomial Interpolation. 4.2 Errors in Polynomial Interpolation. 4.3 Estimating Derivatives and Richardson Extrapolation.

5. NUMERICAL INTEGRATION. 5.1 Lower and Upper Sums. 5.2 Trapezoid Rule. 5.3 Romberg Algorithm.

6. ADDITIONAL TOPICS ON NUMERICAL INTEGRATION. 6.1 Simpsonï¿½s Rule and Adaptive Simpsonï¿½s Rule. 6.2 Gaussian Quadrature Formulas.

7. SYSTEMS OF LINEAR EQUATIONS. 7.1 Naive Gaussian Elimination. 7.2 Gaussian Elimination with Scaled Partial Pivoting. 7.3 Tridiagonal and Banded Systems.

8. ADDITIONAL TOPICS CONCERNING SYSTEMS OF LINEAR EQUATIONS. 8.1 Matrix Factorizations. 8.2 Iterative Solutions of Linear Systems. 8.3 Eigenvalues and Eigenvectors. 8.4 Power Method.

9. APPROXIMATION BY SPLINE FUNCTIONS. 9.1 First-Degree and Second-Degree Splines. 9.2 Natural Cubic Splines. 9.3 B Splines: Interpolation and Approximation.

10. ORDINARY DIFFERENTIAL EQUATIONS. 10.1 Taylor Series Methods. 10.2 Runge-Kutta Methods. 10.3 Stability and Adaptive Runge-Kutta and Multistep Methods.

11. SYSTEMS OF ORDINARY DIFFERENTIAL EQUATIONS. 11.1 Methods for First-Order Systems. 11.2 Higher-Order Equations and Systems. 11.3 Adams-Bashforth-Moulton Methods.

12. SMOOTHING OF DATA AND THE METHOD OF LEAST SQUARES. 12.1 Method of Least Squares. 12.2 Orthogonal Systems and Chebyshev Polynomials. 12.3 Other Examples of the Least-Squares Principle.

13. MONTE CARLO METHODS AND SIMULATION. 13.1 Random Numbers. 13.2 Estimation of Areas and Volumes by Monte Carlo Techniques. 13.3 Simulation.

14. BOUNDARY-VALUE PROBLEMS FOR ORDINARY DIFFERENTIAL EQUATIONS. 14.1 Shooting Method Shooting Method Algorithm. 14.2 A Discretization Method.

15. PARTIAL DIFFERENTIAL EQUATIONS. 15.1 Parabolic Problems. 15.2 Hyperbolic Problems. 15.3 Elliptic Problems.

16. MINIMIZATION OF FUNCTIONS. 16.1 One-Variable Case. 16.2 Multivariate Case.

17. LINEAR PROGRAMMING. 17.1 Standard Forms and Duality. 17.2 Simplex Method. 17.3 Approximate Solution of Inconsistent Linear Systems.

APPENDIX A. ADVICE ON GOOD PROGRAMMING PRACTICES. A.1 Programming Suggestions. APPENDIX B. REPRESENTATION OF NUMBERS IN DIFFERENT BASES. B.1 Representation of Numbers in Different Bases. APPENDIX C. ADDITIONAL DETAILS ON IEEE FLOATING-POINT ARITHMETIC. C.1 More on IEEE Standard Floating-Point Arithmetic. APPENDIX D. LINEAR ALGEBRA CONCEPTS AND NOTATION. D.1 Elementary Concepts. D.2 Abstract Vector Spaces. ANSWERS FOR SELECTED PROBLEMS. BIBLIOGRAPHY. INDEX.