Power Management of Digital Circuits in Deep Sub-Micron CMOS Technologies / by Stephan Henzler.

Por:

Henzler, Stephan [autor]

Colaborador(es):

SpringerLink (Servicio en línea)

Tipo de material: Texto

TextoSeries Advanced Microelectronics ; 25Editor: Dordrecht : Springer Netherlands, 2007Descripción: xvI, 183 páginas 127 ilustraciones recurso en líneaTipo de contenido:

texto

Tipo de medio:

computadora

Tipo de portador:

recurso en línea

ISBN:

9781402050817

Formatos físicos adicionales: Edición impresa:: Sin títuloClasificación LoC:

TK7888.4

Recursos en línea:

Conectar a Springer E-Books (Para consulta externa se requiere previa autentificaciÃ³n en Biblioteca Digital UANL)

Contenidos:

TO LOW-POWER DIGITAL INTEGRATED CIRCUIT DESIGN -- LOGIC WITH MULTIPLE SUPPLY VOLTAGES -- LOGIC WITH MULTIPLE THRESHOLD VOLTAGES -- FORCING OF TRANSISTOR STACKS -- POWER GATING -- CONCLUSION.

Resumen: In the deep sub-micron regime, the power consumption has become one of the most important issues for competitive design of digital circuits. Due to dramatically increasing leakage currents, the power consumption does not take advantage of technology scaling as before. State-of-art power reduction techniques like the use of multiple supply and threshold voltages, transistor stack forcing and power gating are discussed with respect to implementation and power saving capability. Focus is given especially on technology dependencies, process variations and technology scaling. Design and implementation issues are discussed with respect to the trade-off between power reduction, performance degradation, and system level constraints. A complete top-down design flow is demonstrated for power gating techniques introducing new design methodologies for the switch sizing task and circuit blocks for data-retention and block activation. The leakage reduction ratio and the minimum power-down time are introduced as figures of merit to describe the power gating technique on system level and give a relation to physical circuit parameters. Power Management of Digital Circuits in Deep Sub-Micron CMOS Technologies mainly deals with circuit design but also addresses the interface between circuit and system level design on the one side and between circuit and physical design on the other side.

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Springer eBooks

TO LOW-POWER DIGITAL INTEGRATED CIRCUIT DESIGN -- LOGIC WITH MULTIPLE SUPPLY VOLTAGES -- LOGIC WITH MULTIPLE THRESHOLD VOLTAGES -- FORCING OF TRANSISTOR STACKS -- POWER GATING -- CONCLUSION.

In the deep sub-micron regime, the power consumption has become one of the most important issues for competitive design of digital circuits. Due to dramatically increasing leakage currents, the power consumption does not take advantage of technology scaling as before. State-of-art power reduction techniques like the use of multiple supply and threshold voltages, transistor stack forcing and power gating are discussed with respect to implementation and power saving capability. Focus is given especially on technology dependencies, process variations and technology scaling. Design and implementation issues are discussed with respect to the trade-off between power reduction, performance degradation, and system level constraints. A complete top-down design flow is demonstrated for power gating techniques introducing new design methodologies for the switch sizing task and circuit blocks for data-retention and block activation. The leakage reduction ratio and the minimum power-down time are introduced as figures of merit to describe the power gating technique on system level and give a relation to physical circuit parameters. Power Management of Digital Circuits in Deep Sub-Micron CMOS Technologies mainly deals with circuit design but also addresses the interface between circuit and system level design on the one side and between circuit and physical design on the other side.

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