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FaridehShiran Department of Electronics Carleton University, Ottawa, ON, Canada fshiran@doe.carleton.ca SmartReflex Power and Performance Management Technologies for 90 nm, 65 nm, and 45 nm Mobile Application Processors
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Outline Introduction First Generation 90 nm Second Generation 65 nm Third Generation 45 nm Design Methodology and Automation Low Power Standard: IEEE-1801 Conclusion
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Outline Introduction First Generation 90 nm Second Generation 65 nm Third Generation 45 nm Design Methodology and Automation Low Power Standard: IEEE-1801 Conclusion
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Introduction Demand for increasing features of handheld devices Processors speeds reaching 1 GHz and above Bottleneck: battery technology Trade-off: battery life versus higher speeds Technology Scaling Advantages Disadvantagrs
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Demand for Increased Mobile Product Features and Performance
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Leakage Power in different technologies Extend battery life Co-optimization: Process and circuit Texas Instruments (TI) for 90 nm, 65 nm, 45 nm SmartReflex
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Outline Introduction First Generation 90 nm Second Generation 65 nm Third Generation 45 nm Design Methodology and Automation Low Power Standard: IEEE-1801 Conclusion
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90 nm Leakage Power Management Exponential increase in leakage : Power gating uses high Vt sleep transistors which cut off VDD from a circuit block SRAM retention Losing data stored in SRAM, retention needed Multiple channel length Reducing leakage power both in active and idle modes OMAP2 Mobile Application Process Integrate above techniques in a 90 nm technology
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Power gating Global/local power grid methodology
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Outline Introduction First Generation 90 nm Second Generation 65 nm Third Generation 45 nm Design Methodology and Automation Low Power Standard: IEEE-1801 Conclusion
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65nm Power and Performance Larger increase in device leakage Improving SmartReflex power management toolbox: Leakage power management aggressive dynamic voltage frequency scaling Process and temperature adaptive voltage scaling 65 nm technology OMAP3430 application processor
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Outline Introduction First Generation 90 nm Second Generation 65 nm Third Generation 45 nm Design Methodology and Automation Low Power Standard: IEEE-1801 Conclusion
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45 nm Power and Performance Further reduction of active leakage power and performance increase Adaptive body bias (ABB): FBB RBB Retention Til Access (RTA) Full power state Low power state Single Chip 3.5 Baseband and Applications Processor Integrate above techniques in a 45 nm technology
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Outline Introduction First Generation 90 nm Second Generation 65 nm Third Generation 45 nm Design Methodology and Automation Low Power Standard: IEEE-1801 Conclusion
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Design methodology and automation SmartReflex-PriMer (SmartPriMer): Chip-level leakage management design methodology Power Managed (PM) modules Power-Aware Verification PM integrity check Power-aware simulations at RTL and gate levels Not power-aware Power-aware
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Outline Introduction First Generation 90 nm Second Generation 65 nm Third Generation 45 nm Design Methodology and Automation Low Power Standard: IEEE-1801 Conclusion and Future Work
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Low Power Standard: IEEE-1801 Unified Power Format (UPF): Why UPF? PM intent information UPF1.0: power design intent in verification and implementation Power states Power domain specifications Retention, Isolation and level shifting UPF2.0-IEEE1801 Command layering Supply set handles
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Conclusions For higher performance (power management) Three generation technologies 90nm, 65nm, 40nm design methodology SmartReflex-PriMer Power-Aware Verification Standard UPF 1.0 UPF 2.0
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Thank You
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