Logic Design 12.1 Combinatorial Logic 12.2 MSI and LSI Design 12.3 Sequential Logic 13. Digital Logic 11.1 Binary Numbers 11.2 Binary Arithmetic 11.3 Digital Logic Circuits 11.4 Boolean Algebra 11.5 Standard Forms of Boolean Functions 11.6 Simplification of Boolean Functions 12. Electronic Circuits and Amplifiers 10.1 IC Amplifiers 10.2 Operational Amplifiers 10.3 Feedback 10.4 Sinusoidal Oscillators 10.5 Comparators 10.6 Introduction to Communication PART III: DIGITAL SYSTEMS 11.
Transistor Amplifiers 9.1 BJT Amplifiers 9.2 FET Amplifiers 9.3 Frequency Response 9.4 Power Amplifiers 10. Field-Effect Transistors (FETs) 8.1 The Junction Field-Effect Transistor (JFET) 8.2 Metal-Oxide-Semiconductor Field-Effect Transistors (MOSFETs) 8.3 MOSFET Logic Gates 8,4 Complementary MOSFETs (CMOS) 9. Bipolar Junction Transistors (BJTs) 7,1 The pnp Transistor 7.2 The npn Transistor 7.3 Cutoff and Saturation 7.4 Applications to Digitial Logic Circuits 7.5 DTL Integrated-Circuit (IC) Logic 7.6 Transistor-Transistor Logic (TTL) 7.7 Other IC Logic Families 8. Diodes 6.1 Semiconductors 6.2 Doped Semiconductors 6.3 The Junction Diode 6.4 The Ideal Diode 6.5 Nonideal-Diode Models 6.6 Zener Diodes 6.7 Effects of Capacitance 7. Important Circuit and System Concepts 5.1 Frequency Response 5.2 Resonance 5.3 Complex Frequency 5.4 Introduction to Systems 5.5 The Laplace Transform 5.6 Inverse Laplace Transforms 5.7 Application of the Laplace Transform PART II: ELECTRONICS 6.
AC Analysis 4.1 Time-Domain Analysis 4.2 Complex Numbers 4.3 Frequency-Domain Analysis 4.4 Power 4.5 Important Power Concepts 4.6 Polyphase Circuits 4.7 Three-Phase Loads 5. Time-Domain Circuit Analysis 3.1 Inductors and Capacitors 3.2 Integral Relationships for Inductors and Capacitors 3.3 First-Order Circuits - The Natural Response 3.4 First-Order Circuits - The Complete Response 3.5 Second-Order Circuits - The Natural Response 3.6 Second-Order Circuits - The Complete Response 4. Circuit Analysis Principles 2.1 Nodal Analysis 2.2 Determinants and Cramer's Rule 2.3 Mesh Analysis 2.4 Ideal Amplifiers 2.5 Thevevnin's and Norton's Theorems 2.6 Linearity and Superposition 3. Basic Elements and Laws 1.1 Voltage Sources, Current Sources, and Resistors 1.2 Kirchhoff's Current Law (KCL) 1.3 Kirchhoff's Voltage Law (KVL) 1.4 Independent and Dependent Souces 1.5 Instantaneous Power 2. The text is suitable for an introduction to electrical engineering for both majors and non-majors or both, or can be split and the various chapters utilized for an introduction to circuits course, a first electronics course, or for a course on digital electronics and logic design. The text contains 1182 end-of-chapter problemsģ46 more than the first edition. Numerous drill exercises have been added to this new edition, reinforcing ideas presented in the examples.
This edition includes a chapter on circuit analysis software SPICE, with an in detail discussion of the PC version known as Spice (from MicroSim Corp.). Although it delves in depth into each of these topics, the text represents more than your basic survey of the basics of engineering, providing a solid understanding of the fundamental principles on which modern electrical engineering is based. The text is divided into four parts: circuits, electronics, digital systems, and electromagnetics. This second edition of the highly sucessful Fundamentals of Electrical Engineering is thoroughly expanded and updated.