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Microelectronic Circuits : Analysis and Design 3rd edition [Kõva köide]

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  • Formaat: Hardback, 1360 pages, kõrgus x laius x paksus: 279x224x51 mm, kaal: 2518 g, Illustrations, unspecified
  • Ilmumisaeg: 01-Jan-2016
  • Kirjastus: CENGAGE Learning Custom Publishing
  • ISBN-10: 1305635167
  • ISBN-13: 9781305635166
Teised raamatud teemal:
Microelectronic Circuits : Analysis and Design 3rd editionSuurem pilt
  • Formaat: Hardback, 1360 pages, kõrgus x laius x paksus: 279x224x51 mm, kaal: 2518 g, Illustrations, unspecified
  • Ilmumisaeg: 01-Jan-2016
  • Kirjastus: CENGAGE Learning Custom Publishing
  • ISBN-10: 1305635167
  • ISBN-13: 9781305635166
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781305635166.html
Märksõnad:
Take a "breadth-first" approach to teaching electronics with a strong emphasis on design and simulation in Rashid's MICROELECTRONIC CIRCUITS: ANALYSIS AND DESIGN, 3E. This book introduces general characteristics of circuits (ICs) to prepare students for circuit design and analysis techniques. More than half of the problems and examples concentrate on design and use software tools extensively. Important circuits are analyzed in worked-out examples that introduce basic techniques and emphasize the effects of parameter variations. The book then offers a more detailed study of devices and circuits and how they operate within ICs. The book's proven sequence of introducing electronic devices and circuits, then electronic circuits and applications, and finally, digital and analog integrated circuits is easily adaptable for one or two-term courses. Students apply theory to real-world design problems as they master computer simulations for testing and verifying designs.
1. INTRODUCTION TO ELECTRONICS AND DESIGN. Introduction. Review of What
We Know. History of Electronics. Electronic Systems. Electronic Signals and
Notation. Classifications of Electronic Systems. Amplifier Characteristics.
Amplifier Models. Classifications of Amplifiers. Cascaded Amplifiers.
Frequency Specifications. PSpice/SPICE Amplifier Models. Design of Electronic
Systems. Design of Electronic Circuits. Emerging Electronics. Summary of What
We Have Learned. References. Review Questions and Answers. Problems.
2.
INTRODUCTION TO OPERATIONAL AMPLIFIERS AND APPLICATIONS. Introduction. Review
of What We Know. Characteristics of Ideal Op-Amps. Noninverting Amplifiers.
Inverting Amplifiers. Difference Amplifiers. Instrumentation Amplifiers.
Integrators. Differentiators. Addition'Subtraction Amplifiers. Large-Signal
Operations of Op-Amps. Input Offset Voltage. Input Offset Current. Op-Amp
Circuit Design. Summary of What We Have Learned. References. Review Questions
and Answers. Problems.
3. SEMICONDUCTORS AND pn JUNCTION CHARACTERISTICS.
Introduction. Review of What We Know. Semiconductor Materials. Doped
Semiconductor Materials. Zero-Biased pn Junction. Reverse-Biased pn Junction.
Forward-Biased pn Junction. Semiconductor Current Density and Conductivity.
High-Frequency AC Model. Summary of What We Have Learned. References. Review
Questions and Answers. Problems.
4. SEMICONDUCTOR DIODES AND RECTIFIERS.
Introduction. Review of What We Know. Ideal Diodes. Practical Diodes.
Modeling of Practical Diodes. Analysis of Practical Diode Circuits. Zener
Diodes. Diode Rectifiers. C Filters. Diode Peak Detectors and Demodulators.
Diode Clippers. Diode Clamping Circuits. Diode Voltage Multipliers. Special
Types of Diodes. Power Rating. Summary of What We Have Learned. References.
Review Questions and Answers. Problems.
5. BIPOLAR JUNCTION TRANSISTORS AND
AMPLIFIERS. Introduction. Review of What We Know. Performance Parameters.
Bipolar Junction Transistors. Modes of BJT Operation. Forward Mode of
Operation. Base Narrowing. Physical Parameters of Saturation Current IS and
Current Gain ßF. Input and Output Characteristics. BJT Circuit Models.
Small-Signal Analysis. The BJT Switch. DC Biasing of Bipolar Junction
Transistors. Common-Emitter Amplifiers. Resistive-Biased Common-Emitter
Amplifier. Active-Biased Common-Emitter Amplifier. Resistive-Biased Emitter
Follower. Common-Base Amplifiers. Multistage Amplifiers. The Darlington Pair
Transistor. Summary of What We Have Learned. References. Review Questions and
Answers. Problems.
6. METAL OXIDE SEMICONDUCTOR FIELD-EFFECT TRANSISTORS.
Introduction. Review of What We Know. Performance Parameters. Metal Oxide
Field-Effect Transistors. Enhancement MOSFETs. Output Characteristics of
Enhancement MOSFETs. Complementary MOS (CMOS). Depletion MOSFETs. MOSFET
Amplifier. DC Models. Small-Signal Analysis. A MOSFET Switch. DC Biasing of
MOSFETs. Common Source (CS) Amplifiers with Resistive Load. Common Source
(CS) Amplifiers with Active Loads. Common-Drain Amplifiers. Common-Gate
Amplifiers. Multistage Amplifiers. Design of MOSFET Amplifiers. Summary of
What We Have Learned. References. Review Questions and Answers. Problems.
7.
BIPOLAR VERSUS MOS TRANSISTORS AND AMPLIFIERS. Introduction. Frequency Model
and Response of Bipolar Junction Transistors. Models and Frequency Response
of MOSFETs. Comparisons of BJI and MOS Parameters. Bi-MOS Amplifiers. DC
Level Shifting. DC Level Shifting Amplifiers. Summary of What We Have
Learned. References. Review Questions and Answers. Problems.
8. FREQUENCY
RESPONSE OF BJT AND MOSFET AMPLIFIERS. Introduction. Review of What We Know.
Performance Parameters. Bode Plots. Frequency Response Methods. Low Frequency
Methods. High Frequency Methods. Multistage Amplifiers. Frequency Responses
of Common-Emitter BJT Amplifiers. Frequency Response of Common-Collector BJT
Amplifiers. Frequency Response of Common-Base BJT Amplifiers. Multistage BJT
Amplifiers. Frequency Response of Common-Source MOSFET Amplifiers. Frequency