Specific study objectives for part 1
- 1. PT1.3.2 Goals and Objectives Study Objectives. Upon completing Part One, you should be adequately prepared to embark on your studies of numerical methods. In general, you should have gained a fun- damental understanding of the importance of computers and the role of approximations and errors in the implementation and development of numerical methods. In addition to these general goals, you should have mastered each of the specific study objectives listed in Table PT1.1. Computer Objectives. Upon completing Part One, you should have mastered sufficient computer skills to develop your own software for the numerical methods in this text. You should be able to develop well-structured and reliable computer programs on the basis of pseudocode, flowcharts, or other forms of algorithms. You should have developed the ca- pability to document your programs so that they may be effectively employed by users. Finally, in addition to your own programs, you may be using software packages along with this book. Packages like Excel or The MathWorks, Inc. MATLAB® program are examples of such software. You should become familiar with these packages, so that you will be comfortable using them to solve numerical problems later in the text. 10 MODELING, COMPUTERS, AND ERROR ANALYSIS TABLE PT1.1 Specific study objectives for Part One. 1. Recognize the difference between analytical and numerical solutions. 2. Understand how conservation laws are employed to develop mathematical models of physical systems. 3. Define top-down and modular design. 4. Delineate the rules that underlie structured programming. 5. Be capable of composing structured and modular programs in a high-level computer language. 6. Know how to translate structured flowcharts and pseudocode into code in a high-level language. 7. Start to familiarize yourself with any software packages that you will be using in conjunction with this text. 8. Recognize the distinction between truncation and round-off errors. 9. Understand the concepts of significant figures, accuracy, and precision. 10. Recognize the difference between true relative error t, approximate relative error a, and acceptable error s, and understand how a and s are used to terminate an iterative computation. 11. Understand how numbers are represented in digital computers and how this representation induces round-off error. In particular, know the difference between single and extended precision. 12. Recognize how computer arithmetic can introduce and amplify round-off errors in calculations. In particular, appreciate the problem of subtractive cancellation. 13. Understand how the Taylor series and its remainder are employed to represent continuous functions. 14. Know the relationship between finite divided differences and derivatives. 15. Be able to analyze how errors are propagated through functional relationships. 16. Be familiar with the concepts of stability and condition. 17. Familiarize yourself with the trade-offs outlined in the Epilogue of Part One. cha1873X_p01.qxd 3/8/05 10:00 AM Page 10