Power consumption of VLSI (Very Large Scale Integrated) circuits has been growing at an alarmingly rapid rate. This increase in power consumption, coupled with the increasing demand for portable/hand-held electronics, has made power consumption a dominant concern in the design of VLSI circuits today. Traditionally, dynamic (switching) power has dominated the total power consumption of an IC. However, due to current scaling trends, leakage power has now become a major component of the total power consumption in VLSI circuits. Leakage power reduction is especially important in portable/hand-held electronics such as cell-phones and PDAs. This book presents two techniques aimed at reducing leakage power in digital VLSI ICs. The first technique reduces leakage through the selective use of high threshold voltage sleep transistors. The second technique reduces leakage by applying the optimal Reverse Body Bias (RBB) voltage. This book also shows readers how to turn the leakage problem into an opportunity, through the use of sub-threshold logic.
Power consumption of VLSI (Very Large Scale Integrated) circuits has been growing at an alarmingly rapid rate. This increase in power consumption, coupled with the increasing demand for portable/hand-held electronics, has made power consumption a dominant concern in the design of VLSI circuits today. Traditionally, dynamic (switching) power has dominated the total power consumption of an IC. However, due to current scaling trends, leakage power has now become a major component of the total power consumption in VLSI circuits. Leakage power reduction is especially important in portable/hand-held electronics such as cell-phones and PDAs. This book presents two techniques aimed at reducing leakage power in digital VLSI ICs. The first technique reduces leakage through the selective use of high threshold voltage sleep transistors. The second technique reduces leakage by applying the optimal Reverse Body Bias (RBB) voltage. This book also shows readers how to turn the leakage problem into an opportunity, through the use of sub-threshold logic.
This ground-breaking title presents an interdisciplinary introduction to the subject of Dependability and how it applies in medicine generally and in neurology in particular. Dependability is the term applied in engineering and industry to a service that is safe, reliable and trustworthy. Dependable systems use a variety of methods to deliver correct service in the face of uncertainty resulting from misleading, erroneous information, and system faults. Dependable systems result from the application of systematic methods in design, operation, and management to deliver their services. Dependability in Medicine and Neurology presents the philosophy and ideas behind the specific methods of dependability and discusses the principles in the context of medical care and neurologic treatment especially. Patient case vignettes are used widely to illustrate key points. A first-of-its-kind title and based on the author’s many years of teaching these principles to medical colleagues throughout the United States, Dependability in Medicine and Neurology will inspire readers to develop applications for their specific areas of clinical practice. Intended for physicians (especially neurologists), medical students, nurses, and health administrators, Dependability in Medicine and Neurology is an indispensable reference and important contribution to the literature.
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