Signals and Systems with MATLAB Computing and Simulink ModelingOrchard Publications, 2007 - 650 σελίδες This text contains a comprehensive discussion on continuous and discrete time signals and systems with many MATLAB? and several Simulink? examples. It is written for junior and senior electrical and computer engineering students, and for self-study by working professionals. The prerequisites are a basic course in differential and integral calculus, and basic electric circuit theory.To get the most out of this text, it is highly recommended that Appendix A is thoroughly reviewed. This appendix serves as an introduction to MATLAB, and is intended for those who are not familiar with it. The Student Edition of MATLAB is an inexpensive, and yet a very powerful software package; it can be found in many college bookstores, or can be obtained directly from The MathWorks? Inc., 3 Apple Hill Drive, Natick, MA 01760-2098Phone: 508 647-7000, Fax: 508 647-7001http://www.mathworks.come-mail: info@mathworks.comThe elementary signals are reviewed in Chapter 1, and several examples are given. The purpose of this chapter is to enable the reader to express any waveform in terms of the unit step function, and subsequently the derivation of the Laplace transform of it. Chapters 2 through 4 are devoted to Laplace transformation and circuit analysis using this transform. Chapter 5 is an introduction to state-space and contains many illustrative examples. Chapter 6 discusses the impulse response. Chapters 7 and 8 are devoted to Fourier series and transform respectively. Chapter 9 introduces discrete-time signals and the Z transform. Considerable time was spent on Chapter 10 to present the Discrete Fourier transform and FFT with the simplest possible explanations. Chapter 11 contains a thorough discussion to analog and digital filters analysis and design procedures. As mentioned above, Appendix A is an introduction to MATLAB. Appendix B is an introduction to Simulink, Appendix C contains a review of complex numbers, and Appendix D is an introduction to matrix theory.New to the Second EditionThis is an extensive revision of the first edition. The most notable change is the inclusion of the solutions to all exercises at the end of each chapter. It is in response to many readers who expressed a desire to obtain the solutions in order to check their solutions to those of the author and thereby enhancing their knowledge. Another reason is that this text is written also for self-study by practicing engineers who need a review before taking more advanced courses such as digital image processing.Another major change is the addition of a rather comprehensive summary at the end of each chapter. Hopefully, this will be a valuable aid to instructors for preparation of view foils for presenting the material to their class.New to the Third EditionThe most notable change is the inclusion of Simulink modeling examples. The pages where they appear can be found in the Table of Contents section of this text. Another change is the improvement of the plots generated by the latest revisions of the MATLAB? Student Version, Release 14. |
Περιεχόμενα
Chapter 01 pBookpdf | xi |
Chapter 02 pBookpdf | xxxvii |
Chapter 03 pBookpdf | lxxv |
Chapter 04 eBookpdf | xcix |
Chapter 05 pBookpdf | 1 |
Chapter 06 pBookpdf | 53 |
Chapter 07 pBookpdf | 83 |
Chapter 08 pBookpdf | 1 |
Chapter 10 pBookpdf | 125 |
Chapter 11 pBookpdf | 1 |
Appendix A Introduction to MATLAB pBookpdf | 107 |
Appendix B Introduction to Simulink pBookpdf | 139 |
Appendix C Review of Complex Numbers pBookps | 159 |
Appendix D Matrices and Determinants eBookpdf | 169 |
Signals and Systems Bibliographypdf | 200 |
202 | |
Συχνά εμφανιζόμενοι όροι και φράσεις
analog application block Butterworth Chapter circuit coefficients column command complex components Computing and Simulink constant convolution cutoff frequency defined denominator denoted derive Design differential digital filter discrete discrete−time display equal equations evaluate Example exponential express format Fourier series Fourier transform frequency given grid imaginary initial input integral Inverse Laplace transform linear low−pass filter magnitude MATLAB script matrix method Modeling multiplication observe obtain odd function output pair period phase plot poles polynomial Proof referred relation represents respectively result roots sampling scale shifting shown in Figure side Signals and Systems Solution square substitution symmetry Systems with MATLAB Table theorem Third Edition transfer function Type unit step function values variable vector Vins voltage Vouts waveform zero