Sadiku, Matthew N. O.

Signals and Systems : A Primer with MATLAB. - 2nd ed. - 1 online resource (469 pages)

Cover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Contents -- Preface -- Author Biographies -- Notes to Students -- Chapter 1: Basic Concepts -- Global Positioning System -- 1.1. Introduction -- 1.2. Basic Definitions -- 1.3. Classification of Signals -- 1.3.1. Continuous-Time and Discrete-Time Signals -- 1.3.2. Periodic and Nonperiodic Signals -- 1.3.3. Analog and Digital Signals -- 1.3.4. Energy and Power Signals -- 1.3.5. Even and Odd Symmetry -- 1.4. Basic Continous-Time Signals -- 1.4.1. Unit Step Function -- 1.4.2. Unit Impulse Function -- 1.4.3. Unit Ramp Function -- 1.4.4. Rectangular Pulse Function -- 1.4.5. Triangular Pulse Function -- 1.4.6. Sinusoidal Signal -- 1.4.7. Exponential Signal -- 1.5. Basic Discrete-Time Signals -- 1.5.1. The Unit Step Sequence -- 1.5.2. The Unit Impulse Sequence -- 1.5.3. Unit Ramp Sequence -- 1.5.4. Sinusoidal Sequence -- 1.5.5. Exponential Sequence -- 1.6. Basic Operations on Continous Signals -- 1.6.1. Time Reversal -- 1.6.2. Time Scaling -- 1.6.3. Time Shifting -- 1.6.4. Amplitude Transformations -- 1.7. Basic Operations on Discrete Signals -- 1.7.1. Time Shifting -- 1.7.2. Time Reversal -- 1.7.3. Expansion -- 1.8. Classification of Systems -- 1.8.1. Continuous-Time and Discrete-Time Systems -- 1.8.2. Causal and Noncausal Systems -- 1.8.3. Linear and Nonlinear Systems -- 1.8.4. Time-Varying and Time-Invariant Systems -- 1.8.5. Systems With and Without Memory -- 1.9. Applications -- 1.9.1. Electric Circuits -- 1.9.2. Square-Law Devices -- 1.9.3. DSP Systems -- 1.10. Computing With MATLAB� -- Summary -- Review Questions -- Problems -- Chapter 2: Convolution -- Enhancing Your Communication Skills -- 2.1. Introduction -- 2.2. Impulse Response -- 2.3. The Convolution Integral -- 2.4. Graphical Convolution -- 2.5. Block Diagram Representation -- 2.6. Discrete-Time Convolution. 2.7. Block Diagram Realization -- 2.8. Deconvolution -- 2.9. Computing With MATLAB� -- 2.10. Applications -- 2.10.1. BIBO Stability of Continuous-Time Systems -- 2.10.2. BIBO Stability of Discrete-Time Systems -- 2.10.3. Circuit Analysis -- Summary -- Review Questions -- Problems -- Chapter 3: The Laplace Transform -- Historical Profile -- 3.1. Introduction -- 3.2. Definition of the Laplace Transform -- 3.3. Properties of the Laplace Transform -- 3.3.1. Linearity -- 3.3.2. Scaling -- 3.3.3. Time Shifting -- 3.3.4. Frequency Shifting -- 3.3.5. Time Differentiation -- 3.3.6. Time Convolution -- 3.3.7. Time Integration -- 3.3.8. Frequency Differentiation -- 3.3.9. Time Periodicity -- 3.3.10. Modulation -- 3.3.11. Initial and Final Values -- 3.4. The Inverse Laplace Transform -- 3.4.1. Simple Poles -- 3.4.2. Repeated Poles -- 3.4.3. Complex Poles -- 3.5. Transfer Function -- 3.6. Applications -- 3.6.1. Integrodifferential Equations -- 3.6.2. Circuit Analysis -- 3.6.3. Control Systems -- 3.7. Computing With MATLAB� -- Summary -- Review Questions -- Problems -- Chapter 4: The Fourier Series -- Historical Profile -- 4.1. Introduction -- 4.2. Trigonometric Fourier Series -- 4.3. Exponential Fourier Series -- 4.4. Properties of Fourier Series -- 4.4.1. Linearity -- 4.4.2. Time Shifting -- 4.4.3. Time Reversal -- 4.4.4. Time Scaling -- 4.4.5. Even and Odd Symmetries -- 4.4.6. Parseval's Theorem -- 4.5. Truncated Complex Fourier Series -- 4.6. Applications -- 4.6.1. Circuit Analysis -- 4.6.2. Spectrum Analyzers -- 4.6.3. Filters -- 4.7. Computing With MATLAB� -- Summary -- Review Questions -- Problems -- Chapter 5: The Fourier Transform -- 5.1. Introduction -- 5.2. Definition of the Fourier Transform -- 5.3. Properties of Fourier Transform -- 5.3.1. Linearity -- 5.3.2. Time Scaling -- 5.3.3. Time Shifting -- 5.3.4. Frequency Shifting. 5.3.5. Time Differentiation -- 5.3.6. Frequency Differentiation -- 5.3.7. Time Integration -- 5.3.8. Duality -- 5.3.9. Convolution -- 5.4. Inverse Fourier Transform -- 5.5. Applications -- 5.5.1. Circuit Analysis -- 5.5.2. Amplitude Modulation -- 5.5.3. Sampling -- 5.6. Parseval's Theorem -- 5.7. Comparing the Fourier and Laplace Transforms -- 5.8. Computing With MATLAB� -- Summary -- Review Questions -- Problems -- Chapter 6: Discrete Fourier Transform -- Campus Communication Network -- 6.1. Introduction -- 6.2. Discrete-Time Fourier Transform -- 6.3. Properties of DTFT -- 6.3.1. Linearity -- 6.3.2. Time Shifting and Frequency Shifting -- 6.3.3. Time Reversal and Conjugation -- 6.3.4. Time Scaling -- 6.3.5. Frequency Differentiation -- 6.3.6. Time and Frequency Convolution -- 6.3.7. Accumulation -- 6.3.8. Parseval's Relation -- 6.4. Discrete Fourier Transform -- 6.5. Fast Fourier Transform -- 6.6. Computing With MATLAB� -- 6.7. Applications -- 6.7.1. Touch-Tone Telephone -- 6.7.2. Windowing -- Summary -- Review Questions -- Problems -- Chapter 7: z-Transform -- Codes of Ethics -- 7.1. Introduction -- 7.2. Definition of the z-Transform -- 7.3. Region of Convergence -- 7.4. Properties of the z-Transform -- 7.4.1. Linearity -- 7.4.2. Time Shifting -- 7.4.3. Frequency Scaling -- 7.4.4. Time Reversal -- 7.4.5. Modulation -- 7.4.6. Accumulation -- 7.4.7. Convolution -- 7.4.8. Initial and Final Values -- 7.5. Inverse z-Transform -- 7.5.1. Long Division Expansion -- 7.5.2. Partial Fraction Expansion -- 7.6. Applications -- 7.6.1. Linear Difference Equation -- 7.6.2. Transfer Function -- 7.7. Computing With MATLAB� -- Summary -- Review Questions -- Problems -- Appendix A: Mathematical Formulas -- Appendix B: Complex Numbers -- Appendix C: MATLAB� -- Appendix D: Answers to Odd-Numbered Problems -- Index.

The idea of signals and systems arises in different disciplines such as science, engineering, economics, politics and medicine.

9781040045879


System analysis.


Electronic books.

TK5102.9

621.3/028