• DocumentCode
    1543084
  • Title

    Numerical studies of interchip pulse transmission for complex RSFQ systems

  • Author

    Toepfer, H. ; Lingel, T. ; Uhlmann, F.H. ; Aoyagi, M.

  • Author_Institution
    Dept. of Electr. Eng. & Inf. Technol., Tech. Univ. Ilmenau, Germany
  • Volume
    9
  • Issue
    2
  • fYear
    1999
  • fDate
    6/1/1999 12:00:00 AM
  • Firstpage
    3725
  • Lastpage
    3728
  • Abstract
    As the complexity of superconducting digital systems increases, the necessity of a careful design of interconnecting structures becomes more and more evident. Especially in the communication between chips, discontinuities are inevitable. Deriving a high frequency characterization of critical regions is therefore a crucial step for a design-oriented microwave modeling. We employed the finite-difference time-domain technique based on the discretization of Maxwell´s equations for the numerical analysis of typical interconnect components, e.g. flip chip connection pads, vias, and transmission line discontinuities. The peculiar properties of superconductors are taken into account by incorporation of the London equations and the two-fluid model into the numerical scheme. Computer simulations have been carried out for various arrangements. Their results show in the time-domain how the shape of a rapid single flux quantum (RSFQ) pulse is affected by passing a discontinuity in the interchip signal path. Furthermore, frequency domain characterizations are obtained in terms of scattering parameters providing information about the bandwidth of the structure under investigation.
  • Keywords
    Maxwell equations; S-parameters; finite difference time-domain analysis; flip-chip devices; frequency-domain analysis; integrated circuit interconnections; superconducting integrated circuits; London equations; Maxwell´s equations; bandwidth; complex RSFQ systems; design-oriented microwave modeling; finite-difference time-domain technique; flip chip connection pads; frequency domain characterizations; high frequency characterization; interchip pulse transmission; interconnecting structures; rapid single flux quantum; scattering parameters; superconducting digital systems; transmission line discontinuities; two-fluid model; vias; Digital systems; Finite difference methods; Frequency; Maxwell equations; Microwave communication; Numerical analysis; Superconducting microwave devices; Superconducting transmission lines; Time domain analysis; Transmission line discontinuities;
  • fLanguage
    English
  • Journal_Title
    Applied Superconductivity, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1051-8223
  • Type

    jour

  • DOI
    10.1109/77.783837
  • Filename
    783837