• DocumentCode
    751417
  • Title

    CMOS scaling for high performance and low power-the next ten years

  • Author

    Davari, Bijan ; Dennard, Robert H. ; Shahidi, Ghavam G.

  • Author_Institution
    SRDC, IBM Thomas J. Watson Res. Center, Yorktown Heights, NY, USA
  • Volume
    83
  • Issue
    4
  • fYear
    1995
  • fDate
    4/1/1995 12:00:00 AM
  • Firstpage
    595
  • Lastpage
    606
  • Abstract
    A guideline for scaling of CMOS technology for logic applications such as microprocessors is presented covering the next ten years, assuming that the lithography and base process development driven by DRAM continues on the same three-year cycle as in the past. This paper emphasizes the importance of optimizing the choice of power-supply voltage. Two CMOS device and voltage scaling scenarios are described. One optimized for highest speed and the other trading off speed improvement for much lower power. It is shown that the low power scenario is quite close to the original constant electric-field scaling theory. CMOS technologies ranging from 0.25 μm channel length at 2.5 V down to sub-0.1 μm at 1 V are presented and power density is compared for the two scenarios. Scaling of the threshold voltage along with the power supply voltage will lead to a substantial rise in standby power compared to active power and some tradeoffs of performance and/or changes in design methods must be made. Key technology elements and their impact on scaling are discussed. It is shown that a speed improvement of about 7× and over two orders of magnitude improvement in power-delay product (mW/MIPS) are expected by scaling of bulk CMOS down to the sub-0.1 μm regime as compared with today´s high performance 0.6 μm devices at 5 V. However, the power density rises by a factor of 4× for the high-speed scenario. The status of the silicon-on-insulator (SOI) approach to scaled CMOS is also reviewed, showing the potential for about 3× savings in power compared to the bulk case at the same speed
  • Keywords
    CMOS digital integrated circuits; integrated circuit reliability; integrated circuit technology; silicon-on-insulator; technological forecasting; 0.1 to 0.25 micron; 1 to 2.5 V; CMOS scaling; SOI; base process development; constant electric-field scaling theory; lithography; logic applications; low-power design; power density; power-delay product; power-supply voltage; speed improvement; threshold voltage; voltage scaling; CMOS logic circuits; CMOS process; CMOS technology; Emergency power supplies; Guidelines; Lithography; Logic devices; Microprocessors; Random access memory; Threshold voltage;
  • fLanguage
    English
  • Journal_Title
    Proceedings of the IEEE
  • Publisher
    ieee
  • ISSN
    0018-9219
  • Type

    jour

  • DOI
    10.1109/5.371968
  • Filename
    371968