Table of Contents

NOTE: Each chapter begins with an Introduction and concludes with a Summary.

1. Signals and Systems

• Continuous-Time and Discrete-Time Signals.
• Transformations of the Independent Variable.
• Exponential and Sinusoidal Signals.
• The Unit Impulse and Unit Step Functions.
• Continuous-Time and Discrete-Time Systems.
• Basic System Properties.

2. Linear Time-Invariant Systems

• Discrete-Time LTI Systems: The Convolution Sum.
• Continuous-Time LTI Systems: The Convolution Integral.
• Properties of Linear Time-Invariant Systems.
• Causal LTI Systems Described by Differential and Difference Equations.
• Singularity Functions.

3. Fourier Series Representation of Periodic Signals

• A Historical Perspective.
• The Response of LTI Systems to Complex Exponentials.
• Fourier Series Representation of Continuous-Time Periodic Signals.
• Convergence of the Fourier Series.
• Properties of Continuous-Time Fourier Series.
• Fourier Series Representation of Discrete-Time Periodic Signals.
• Properties of Discrete-Time Fourier Series.
• Fourier Series and LTI Systems.
• Filtering.
• Examples of Continuous-Time Filters Described by Differential Equations.
• Examples of Discrete-Time Filters Described by Difference Equations.

4. The Continuous-Time Fourier Transform

• Representation of Aperiodic Signals: The Continuous-Time Fourier Transform.
• The Fourier Transform for Periodic Signals.
• Properties of the Continuous-Time Fourier Transform.
• The Convolution Property.
• The Multiplication Property.
• Tables of Fourier Properties and Basic Fourier Transform Pairs.
• Systems Characterized by Linear Constant-Coefficient Differential Equations

5. The Discrete-Time Fourier Transform.

• Representation of Aperiodic Signals: The Discrete-Time Fourier Transform.
• The Fourier Transform for Periodic Signals.
• Properties of the Discrete-Time Fourier Transform.
• The Convolution Property.
• The Multiplication Property.
• Tables of Fourier Transform Properties and Basic Fourier Transform Pairs.
• Duality.
• Systems Characterized by Linear Constant-Coefficient Difference Equations.

6. Time- and Frequency Characterization of Signals and Systems

• The Magnitude-Phase Representation of the Fourier Transform.
• The Magnitude-Phase Representation of the Frequency Response of LTI Systems.
• Time-Domain Properties of Ideal Frequency-Selective Filters.
• Time- Domain and Frequency-Domain Aspects of Nonideal Filters.
• First-Order and Second-Order Continuous-Time Systems.
• First-Order and Second-Order Discrete-Time Systems.
• Examples of Time- and Frequency-Domain Analysis of Systems.

7. Sampling

• Representation of a Continuous-Time Signal by Its Samples: The Sampling Theorem.
• Reconstruction of a Signal from Its Samples Using Interpolation.
• The Effect of Undersampling: Aliasing.
• Discrete-Time Processing of Continuous-Time Signals.
• Sampling of Discrete-Time Signals.

8. Communication Systems

• Complex Exponential and Sinusoidal Amplitude Modulation.
• Demodulation for Sinusoidal AM. Frequency-Division Multiplexing.
• Single-Sideband Sinusoidal Amplitude Modulation.
• Amplitude Modulation with a Pulse-Train Carrier.
• Pulse-Amplitude Modulation.
• Sinusoidal Frequency Modulation.
• Discrete-Time Modulation.

9. The Laplace Transform

• The Laplace Transform.
• The Region of Convergence for Laplace Transforms.
• The Inverse Laplace Transform.
• Geometric Evaluation of the Fourier Transform from the Pole-Zero Plot.
• Properties of the Laplace Transform.
• Some Laplace Transform Pairs.
• Analysis and Characterization of LTI Systems Using the Laplace Transform.
• System Function Algebra and Block Diagram Representations.
• The Unilateral Laplace Transform.

10. The Z-Transform

• The z-Transform.
• The Region of Convergence for the z-Transform.
• The Inverse z-Transform.
• Geometric Evaluation of the Fourier Transform from the Pole-Zero Plot.
• Properties of the z-Transform.
• Some Common z-Transform Pairs.
• Analysis and Characterization of LTI Systems Using z-Transforms.
• System Function Algebra and Block Diagram Representations.
• The Unilateral z-Transforms.

11. Linear Feedback Systems

• Linear Feedback Systems.
• Some Applications and Consequences of Feedback.
• Root-Locus Analysis of Linear Feedback Systems.
• The Nyquist Stability Criterion.
• Gain and Phase Margins.

Appendix: Partial-Fraction Expansion Bibliography Answers Index