1 / 27

LOW POWER DESIGN METHODS

LOW POWER DESIGN METHODS. V.ANANDI ASST.PROF,E&C MSRIT,BANGALORE. Course Objective. Low-power is a current need in VLSI design. Learn basic ideas, concepts and methods. Gain hands-on experience. Contents. Introduction Dynamic power Short circuit power Reduced supply voltage operation

gmundy
Télécharger la présentation

LOW POWER DESIGN METHODS

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. LOW POWER DESIGN METHODS V.ANANDI ASST.PROF,E&C MSRIT,BANGALORE

  2. Course Objective • Low-power is a current need in VLSI design. • Learn basic ideas, concepts and methods. • Gain hands-on experience.

  3. Contents • Introduction • Dynamic power • Short circuit power • Reduced supply voltage operation • Glitch elimination • Static (leakage) power reduction • Low power systems • State encoding • Processor and multi-core design • Books on low-power design

  4. Introduction Power Consumption of VLSI Chips Why is it a concern? Business & technical needs Semiconductor processing technology

  5. NEED FOR LOW POWER • More transistors are packed into the chip. • Increased market demand for portable devices. • Environmental concerns

  6. Meaning of Low-Power Design • Design practices that reduce power consumption at least by one order of magnitude; in practice 50% reduction is often acceptable. • General considerations in low-power design • Algorithms and architectures • High-level and software techniques • Gate and circuit-level methods • Power estimation techniques • Test power

  7. Topics in Low-Power • Power dissipation in CMOS circuits • Device technology • Low-power CMOS technologies • Energy recovery methods • Circuit and gate level methods • Logic synthesis • Dynamic power reduction techniques • Leakage power reduction • System level methods • Microprocessors • Arithmetic circuits • Low power memory technology • Test power • Power estimation methods and tools

  8. Low-Power Design Techniques • Circuit and gate level methods • Reduced supply voltage • Adiabatic switching and charge recovery • Logic design for reduced activity • Reduced Glitches • Transistor sizing • Pass-transistor logic • Pseudo-nMOS logic • Multi-threshold gates

  9. Low-Power Design Techniques • Functional and architectural methods • Clock suppression • Clock frequency reduction • Supply voltage reduction • Power down • Algorithmic and Software methods

  10. Power Dissipation in CMOS Logic (0.25µ) Ptotal (0→1) = CL VDD2 + tscVDD Ipeak+VDDIleakage VDD VDD CL %75 %20 %5

  11. Degrees of Freedom • The three degrees of freedom are: • Supply Voltage • Switching Activity • Physical capacitance

  12. Components of Power • Dynamic • Signal transitions • Logic activity • Glitches • Short-circuit • Static • Leakage Ptotal = Pdyn + Pstat = Ptran + Psc + Pstat

  13. CMOS Dynamic Power Dynamic Power = Σ 0.5 αifclk CLiVDD2 All gates i ≈ 0.5 αfclk CLVDD2 ≈ α01fclk CLVDD2 where α average gate activity factor α01 = 0.5α, average 0→1 trans. fclk clock frequency CL total load capacitance VDD supply voltage

  14. Dynamic Power isc VDD Dynamic Power = CLVDD2/2 + Psc R Vo Vi CL R Ground

  15. Summary: Short-Circuit Power • Short-circuit power is consumed by each transition (increases with input transition time). • Reduction requires that gate output transition should not be faster than the input transition (faster gates can consume more short-circuit power). • Increasing the output load capacitance reduces short-circuit power. • Scaling down of supply voltage with respect to threshold voltages reduces short-circuit power.

  16. Dynamic Power Reduction • Reduce power per transition • Reduced voltage operation – voltage scaling • Capacitance minimization – device sizing • Reduce number of transitions • Glitch elimination

  17. Glitch Power Reduction • Design a digital circuit for minimum transient energy consumption by eliminating hazards

  18. Static (Leakage) Power • Dynamic • Signal transitions • Logic activity • Glitches • Short-circuit • Static • Leakage

  19. Leakage Power VDD IG Ground R n+ n+ Isub IPT ID IGIDL

  20. Leakage Current Components • Subthreshold conduction, Isub • Reverse bias pn junction conduction, ID • Gate induced drain leakage, IGIDL due to tunneling at the gate-drain overlap • Drain source punchthrough, IPT due to short channel and high drain-source voltage • Gate tunneling, IGthrough thin oxide

  21. Reducing Leakage Power • Leakage power as a fraction of the total power increases as clock frequency drops. Turning supply off in unused parts can save power. • For a gate it is a small fraction of the total power; it can be significant for very large circuits. • Scaling down features requires lowering the threshold voltage, which increases leakage power; roughly doubles with each shrinking. • Multiple-threshold devices are used to reduce leakage power.

  22. Low-Power System Design • State encoding • Bus encoding • Finite state machine • Clock gating • Flip-flop • Shift register • Microprocessors • Single processor • Multi-core processor

  23. Clock-Gating in Low-Power Flip-Flop D D Q CK

  24. Power Reduction in Processors • Hardware methods: • Voltage reduction for dynamic power • Dual-threshold devices for leakage reduction • Clock gating, frequency reduction • Sleep mode • Architecture: • Instruction set • hardware organization • Software methods

  25. A Multicore Design Multiplier Core 1 Reg 40MHz Multiplier Core 2 Output Reg 5 to 1 mux Reg Input 40MHz 200MHz Multiplier Core 5 Multiphase Clock gen. and mux control Reg 40MHz 200MHz CK Core clock frequency = 200/N, N should divide 200.

  26. Challenges • Development of low Vt, supply voltage and design technique • Low power interconnect and reduced activity approaches • Low-power system synchronization • Dynamic power-management techniques • Development of application-specific processing • Self-adjusting and adaptive circuits • Integrated design methodology • Power-conscious techniques and tools development • Severe supply fluctuations or current spikes

  27. REFERENCES on Low-Power Design • A. Chandrakasan and R. Brodersen, Low-Power Digital CMOS Design, Boston: Springer, 1995. • A. Chandrakasan and R. Brodersen, Low-Power CMOS Design, New York: IEEE Press, 1998. • J. M. Rabaey and M. Pedram, Low Power Design Methodologies, Boston: Springer, 1996. • K. Roy and S. C. Prasad, Low-Power CMOS VLSI Circuit Design, New York: Wiley-Interscience, 2000. • G. K. Yeap, Practical Low Power Digital VLSI Design, Boston:Springer, 1998. • Tutorial on low power by Vishwani.D.Aggarwal VDAT’06 Symposium on low power design methodologies.

More Related