| Description |
1 online resource (xxxviii, 788 pages) |
| Contents |
A. Dedication -- B. About the author -- C. Preface -- D. Acknowledgments -- E. Acronyms -- F. Notation -- 1. Opportunities and challenges of nanoscale technology and systems -- Introduction -- Mixed-signal circuits and systems -- Nanoscale cmos circuit technology -- Power consumption and leakage dissipation issues in ams-socs -- Parasitics issue -- Nanoscale circuit process variation issues -- The temperature variation issue -- Challenges in nanoscale cmos ams-soc design -- Tools for mixed-signal circuit design -- Questions -- References -- 2. Emerging systems designed as analog/mixed-signal system-on-chips -- Introduction -- Atomic force microscope -- Biosensor systems -- Blu-ray player -- Drug-delivery nano-electro-mechanical systems -- Digital video recorder -- Electroencephalogram system -- Gps navigation device -- Gpu-cpu hybrid system -- Networked media tank -- Net-centric multimedia processor -- Radiation detection system -- Radio frequency identification chip -- Secure digital camera -- Set-top box -- Slate personal computer -- Smart mobile phone -- Software-defined radio -- Tv tuner card for pcs -- Universal remote control -- Questions -- References -- 3. Nanoelectronics issues in design for excellence -- Introduction -- Design for excellence -- Different types of nanoelectronic devices -- Nanomanufacturing: the origin and source of process variations -- The issue of process variation -- The yield issue -- The power issue in nanoelectronic circuits -- The issue of parasitics in nanoelectronic circuits -- The thermal issue -- The reliability issue -- The trust issue -- Questions -- References -- 4. Phase-locked loop component circuits -- Introduction -- Phase-locked loop system types -- Phase-locked loop system: a broad overview -- Oscillator circuits -- Ring oscillators -- Current-starved voltage controlled oscillators -- Lc-tank voltage-controlled oscillator -- Relaxation oscillators -- Phase-frequency detectors -- Charge pumps -- Loop filters -- Frequency dividers -- Design and characterization of a 180-nm cmos pll -- All digital phase-locked loop -- Delay-locked loop -- Questions -- References -- 5. Electronic signal converter circuits -- Introduction -- Types of electronic signal converters -- Selected adc architectures: brief overview -- Selected dac architectures: brief overview -- Characteristics for data converters -- A 90-nm cmos-based flash adc -- A 45-nm cmos-based flash adc -- Single-electron-based adc -- Organic thin-film transistor-based adcs -- Sigma-delta modulator-based adc -- Sigma-delta modulator-based digital-to-analog converter -- Single electron transistor-based digital-to-analog converter -- Questions -- References -- 6. Sensor circuits and systems -- Introduction -- Nanoelectronics-based biosensors -- Thermal sensors for mixed-signal circuits and systems -- Solar cells -- Piezoelectric sensors -- Image sensors -- Nanoelectronics-based gas sensors -- Body sensors -- Epileptic seizure sensors -- Humidity sensors -- Motion sensors -- Sense amplifiers -- Questions -- References |
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7. Memory in the ams-socs -- Introduction -- Static random-access memory -- Dynamic random-access memory -- Twin-transistor random-access memory -- Thyristor random-access memory -- Read-only memory -- Flash memory -- Resistive random-access memory -- Magnetic or magnetoresistive random-access memory -- Phase-change ram -- Questions -- References -- 8. Mixed-signal circuit and system design flow -- Introduction -- Ams-soc: a complete design perspective -- Integrated circuit design flow: top-down versus bottom-up -- Analog circuit design flow -- Digital circuit design flow -- Analog and mixed-signal circuit design flow -- Design flow using commercial electronic design automation tools -- Design flow using free or open-source eda tools -- Comprehensive design flows -- Process design kit and libraries -- Eda tool installation -- Questions -- References -- 9. Mixed-signal circuit and system simulation -- Introduction -- Simulation types and languages for circuits and systems -- Behavioral simulation using matlabĀ® -- SimulinkĀ®-or simscapeĀ®-based simulations -- Circuit-level and/or device-level analog simulations -- Verilog-a-based analog simulation -- Simulations of digital circuits or systems -- Mixed-signal hdl-based simulation -- Mixed-mode circuit-level simulations -- Questions -- References -- 10. Power-, parasitic-, and thermal-aware ams-soc design methodologies -- Introduction -- Power dissipation: key design constraint -- Different energy or power reduction techniques for ams-soc -- Presilicon power reduction techniques -- Hardware-based postsilicon power reduction techniques -- Dynamic power reduction techniques -- Subthreshold leakage reduction techniques -- Gate-oxide leakage reduction techniques -- Parasitics: brief overview -- The effects of parasitics on integrated circuits -- Modeling and extraction of parasitics -- Design flows for parasitic-aware circuit optimization -- Temperature or thermal issue: an overview -- Thermal modeling -- Thermal analysis or simulation techniques -- Temperature monitoring or sensing -- Temperature control or management -- Thermal-aware circuit optimization -- Thermal-aware digital design flows -- Thermal-aware register-transfer-level optimization -- Thermal-aware system-level design -- Questions -- References -- 11. Variability-aware ams-soc design methodologies -- Introduction -- Methods for variability analysis -- Tool setup for statistical analysis -- Methods for variability-aware design optimization -- Variability-aware design of active pixel sensor -- Variability-aware design of nanoscale vco circuits -- Variability-aware design of the sram -- Register-transfer-level methods for variability-aware digital circuits -- System-level methods for variability-aware digital design -- An adaptive body bias method for dynamic process variation compensation -- Parametric variation effect mitigation in clock networks -- Statistical methods for yield analysis -- Questions -- References -- 12. Metamodel-based fast ams-soc design methodologies -- Introduction -- Metamodel: an overview -- Metamodel-based ultrafast design flow -- Polynomial-based metamodeling -- Kriging-based metamodeling -- Neural network-based metamodeling -- Ultrafast process variations analysis using metamodels -- Polynomial-metamodel-based ultrafast design optimization -- Neural network metamodel-based ultrafast design optimization -- Kriging metamodel-based ultrafast design optimization -- Questions -- References |
| Summary |
The only single-volume text to cover both the classical and emerging nanoelectronic technologies being used in mixed-signal design addresses digital, analog, and memory components. Winner of the Association of American Publishers' 2016 PROSE Award in the Textbook/Physical Sciences and Mathematics category |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Print version record and CIP data provided by publisher; resource not viewed |
| Subject |
Nanoelectronics.
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Mixed signal circuits.
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Mixed signal circuits
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Nanoelectronics
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| Form |
Electronic book
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| LC no. |
2021693178 |
| ISBN |
9780071823036 |
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0071823034 |
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0071825711 |
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9780071825719 |
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