• DocumentCode
    310217
  • Title

    Delay insensitive logic for RSFQ superconductor technology

  • Author

    Patra, Priyadarsan ; Polonsky, Stanislav ; Fussell, Donald S.

  • Author_Institution
    Intel Corp., Hillsboro, OR, USA
  • fYear
    1997
  • fDate
    7-10 Apr 1997
  • Firstpage
    42
  • Lastpage
    53
  • Abstract
    Asynchronous designs have been touted as having potential advantages in average performance, power consumption, modularity and tolerance of metastability as compared to traditional synchronous logic. While delay-insensitive (DI) asynchronous circuits are theoretically the most desirable type of asynchronous logic because they make the weakest timing assumptions, the complexity of implementing DI circuits in CMOS or similar technologies may make them impractical to use. The fact that event-based DI circuits are ill matched to CMOS does not necessarily mean that they are inherently inefficient, however. In this paper we show that using Rapid Single Flux Quantum (RSFQ) superconducting circuits, in which information is represented as discrete voltage pulses or magnetic flux quanta, many powerful DI circuit primitives can be implemented at least as efficiently as Boolean logic gates. Since DI logic also alleviates the severe clock skew problems that can be expected at the switching speeds approaching a terahertz in this technology, it may well be a more practical basis for digital circuit design than alternatives traditionally used for CMOS
  • Keywords
    asynchronous circuits; computational complexity; delays; logic design; magnetic flux; superconducting processor circuits; Boolean logic gates; CMOS; RSFQ superconductor technology; asynchronous designs; average performance; complexity; delay insensitive logic; delay-insensitive asynchronous circuits; digital circuit design; discrete voltage pulses; magnetic flux quanta; metastability tolerance; modularity; power consumption; rapid single flux quantum superconducting circuits; weakest timing assumptions; Asynchronous circuits; CMOS logic circuits; CMOS technology; Delay; Energy consumption; Logic design; Logic gates; Magnetic circuits; Metastasis; Superconducting logic circuits;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Advanced Research in Asynchronous Circuits and Systems, 1997. Proceedings., Third International Symposium on
  • Conference_Location
    Eindhoven
  • Print_ISBN
    0-8186-7922-0
  • Type

    conf

  • DOI
    10.1109/ASYNC.1997.587144
  • Filename
    587144