MICROELECTRONICS: AN INTEGRATED APPROACH

Le Monde En Tique

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Ouvrage 0-13-271131-1 : MICROELECTRONICS: AN INTEGRATED APPROACH
Organizes coverage to be extremely flexible, allowing
professors to teach a broad range of courses and course
sequences.
Offers coverage of analog/digital/memory circuit design--in modular form--in a single source.
Provides flexibility in the level of device physics complexity, allowing professors to add to the depth or breadth of
coverage as they see fit.
Uses an integrated circuit context for introduction, examples and problems, using technology cross-sections and layouts
to help put abstract circuit and device concepts into actual physical structures.
Guides readers through examples of actual design processes
that parallel the design approach used by integrated circuit engineers--beginning with rough hand calculations and
following with computer simulations using SPICE to
optimize the design.
Supports discussions and examples with a wealth of
exercises, problems and design problems.
Features capstone chapters--chapters 12 and 13--which
unite the previously covered concepts of devices and
circuits in the design of an operational amplifier and
semiconductor memories.
Table of Contents
1. Introduction to Microelectronics. Introduction. The Digital Inverter. Microelectronic
Sensing Systems. Memories. 2. Semiconductor Physics and IC Technology.
Pure Semiconductors. Generation, Recombination,
and Thermal Equilibrium. Doping. Carrier Transport. Silicon Integrated Circuit Technology. C Resistors. 3. pn Junction and MOS Electrostatics. Applied Electrostatics. Carrier Concentration and
Potential in Thermal Equilibrium. The PN Junction in Thermal Equilibrium. The PN Junction Under
Reverse Bias. Depletion Capacitance. The MOS
Capacitor: A First Pass. The Electrostatics of the MOS Capacitor. Capacitance of the MOS Structure.
4. The MOS Field-Effect Transistor. Introduction. Device Physics of MOSFET: Drain
Current and Channel Charge. MOSFET Device
Physics: A First Pass. MOSFET Device Physics: the
Gradual Channel Approximation. MOSFET Circuit
Models. Level I DC Model 35. 5. Digital Circuits Using Mos Transistors.
Logic Concepts. Inverter Characteristics. MOS Inverter Circuits. CMOS Inverter Analysis. Static
CMOS Logic Gates. Dynamic Logic. Pass Transistor
Logic.
6. The pn Junction Diode. pn Diode Circuit Symbol and Terminal Characteristics. Integrated Circuit pn Diodes. The pn
Junction Diode: A First Pass. pn Junction Diode
Circuit Models. SPICE Model of the pn Junction
Diode. Device Physics of the pn Junction Diode:
Non-Equilibrium Minority Carrier Recombination.
The Continuity Equation. Minority Carrier
Distributions and Current Components: A Second Pass. Diode Applications. 7. The Bipolar Junction Transistor. Introduction. Bipolar Junction Transistor Physics: A First Pass. Reverse Active and Saturation Operating Regions. The Ebers-Moll Equations. Small-Signal
Model of the npn BJT. BJT Device Physics. Lateral
pnp Bipolar Transistor. SPICE Models for Bipolar
Junction Transistors. 8. Single-State Bipolar/MOS Transistor Amplifiers.
General Amplifier Concepts. Common-Emitter
Amplifier-Introduction. Common-Source
Amplifier-Introduction. Current Source Supplies.
Common-Source Amplifier with Current Source
Supply. Common-Emitter Amplifier with Current
Source Supply. Improved Transconductance
Amplifier with Emitter Degeneracy Resistor.
Common-Base/Gate Amplifier. 9. Multistage Amplifiers. MOS Multistage Amplifiers-Small Signal Description. BiCMOS Multistage Amplifiers-Small Signal
Description. BiCMOS Multistage Amplifiers-Small
Signal Description. Direct-coupled Amplifiers-Large
Signal Analysis. DC Voltage and Current Sources. A Two-Stage Transconductance Amplifier. Analysis of a BiCMOS Voltage Amplifier. Exercise and
Problems.
10. Frequency Response. Bode Plots. Device Models for Frequency Response Analysis. Short-Circuit Current Gain. Voltage Gain Amplifiers. Frequency Response of Common-Collector/Drain Voltage Buffer.
Common-Base/Gate Amplifier-Current Buffer.
Frequency Response of Multistage Amplifiers.
11. Differential Amplifiers. General Concepts for Differential Amplifiers. Small
Signal Analysis of Differential Amplifiers. Two-Port Model for the Differential Amplifier. Frequency Response of Differential Amplifiers. Differential
Amplifiers with Single-Ended Outputs. Large Signal Analysis of Differential Amplifiers. Exercises and
Problems.
12. Feedback and Operational Amplifiers. Introduction: Amplifier Models and the Feedback
Concept. Frequency Response of Feedback
Amplifiers. Large-Signal Benefits of Feedback.
Practical Feedback Amplifiers. Integrated
Operational Amplifiers. BiCOMS Operational
Amplifiers.
13. MOS Memories. Memory Classification. MOS Memory Architecture.
Memory Cells. Sense Amplifiers. Address Decoders
and Buffers. SRAM Design Example. Exercises and
Problems.

Auteur : HOWE
Editeur : PRENTICE HALL
Nombre de pages : 908
Date de publication : 06 1996

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