Low-Power Cmos Design

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Informationen zum Autor Anantha P. Chandrakasan received the B.S, M.S. and Ph.D. degrees in Electrical Engineering and Computer Sciences from the University of California, Berkeley, in 1989, 1990, and 1994 respectively. Since September 1994, he has been with the Massachusetts Institute of Technology, Cambridge.                                                 Chandrakasan leads the MIT Energy-Efficient Circuits and Systems Group, whose research projects have addressed security hardware, energy harvesting, and wireless charging for the internet of things; energy-efficient circuits and systems for multimedia processing; and platforms for ultra-low-power biomedical electronics.  Klappentext This collection of important papers provides a comprehensive overview of low-power system design, from component technologies and circuits to architecture, system design, and CAD techniques. LOW POWER CMOS DESIGN summarizes the key low-power contributions through papers written by experts in this evolving field. Zusammenfassung This collection of papers provides an overview of low-power system design! from component technologies and circuits to architecture! system design! and CAD techniques. Inhaltsverzeichnis Preface. OVERVIEW. Low Power Microelectronics: Retrospect and Prospect (J. Meindl). Micropower IC (E. Vittoz). Low-Power CMOS Digital Design (A. Chandrakasan, et al. ). CMOS Scaling for High Performance and Low-Power-The Next Ten Years (B. Davari, et al. ). LOW VOLTAGE TECHNOLOGIES AND CIRCUITS. Low-Voltage Technologies and Circuits (T. Kuroda & T. Sakurai). Threshold Voltage Scaling and Control. Ion-Implanted Complementary MOS Transistors in Low-Voltage Circuits (R. Swanson & J. Meindl). Trading Speed for Low Power by Choice of Supply and Threshold Voltages (D. Liu & C. Svensson). Limitation of CMOS Supply-Voltage Scaling by MOSFET Threshold-Voltage Variation (S. Sun & P. Tsui). Multiple Threshold CMOS (MTCMOS). 1-V Power Supply High-Speed Digital Circuit Technology with Multithreshold Voltage CMOS (S. Mutoh, et al. ). A 1-V Multi-Threshold Voltage CMOS DSP with an Efficient Power Management Technique for Mobile Phone Application (S. Mutoh, et al. ). Substrate Bias Controlled Variable Threshold CMOS. 50% Active-Power Saving Without Speed Degradation Using Standby Power Reduction (SPR) Circuit (K. Seta, et al. ). A 0.9V, 150MHz 10mW 4mm2, 2-D Discrete Cosine Transform Core Processor with Variable Threshold-Voltage (VT) Scheme (T. Kuroda, et al. ). Silicon-on-Insulator Based Technologies. SOI CMOS for Low Power Systems (D. Antoniadis). Back Gated CMOS on SOIAS for Dynamic Threshold Voltage Control (I. Yang, et al. ). Design of Low Power CMOS/SOI Devices and Circuits for Memory and Signal Processing Applications (L. Thon & G. Shahidi). A Dynamic Threshold Voltage MOSFET (DTMOS) for Very Low Voltage Operation (F. Assaderaghi, et al. ). A 0.5V SIMOX-MTCMOS Circuit with 200ps Logic Gate (T. Douseki, et al. ). EFFICIENT DC-DC CONVERSION AND ADAPTIVE POWER SUPPLY SYSTEMS. Efficient Low Voltage DC-DC Converter Design. A Low-Voltage CMOS DC-DC Converter for a Portable Battery-Operated System (A. Stratakos, et al. ). Ultra Low-Power Control Circuits for PWM Converters (A. Dancy & A. Chandrakasan). Adaptive Power Supply Systems. A Voltage Reduction Technique for Battery Operated Systems (V. von Kaenel, et al. ). Automatic Adjustment of Threshold and Supply Voltage for Minimum Power Consumption in CMOS Digital Circuits (V. von Kaenel, et al. ). Low-Power Operation Using Self-Timed Circuits and Adaptive Scaling of the Supply Voltage (L. Nielsen, et al. ). A Low-Pow...