Limit to the Bit-Rate Capacity of Electrical Interconnects from the Aspect Ratio of the System Architecture

We show that there is a limit to the total number of bits per second,B, of information that can flow in a simple digital electrical interconnection that is set only by the ratio of the lengthlof the interconnection to the total cross-sectional dimensionAof the interconnect wiring?the “aspect ratio” of the interconnection. This limit is largely independent of the details of the design of the electrical lines. The limit is approximatelyB~BoA/l2bits/s, withBo~ 1015(bit/s) for high-performance strip lines and cables, ~1016for small on-chip lines, and ~1017?1018for equalized lines. Because the limit is scale-invariant, neither growing nor shrinking the system substantially changes the limit. Exceeding this limit requires techniques such as repeatering, coding, and multilevel modulation. Such a limit will become a problem as machines approach Tb/s information bandwidths. The limit will particularly affect architectures in which one processor must talk reasonably directly with many others. We argue that optical interconnects can solve this problem since they avoid the resistive loss physics that gives this limit.

[1]  Alain C. Diebold,et al.  Overview of metrology requirements based on the 1994 National Technology Roadmap for semiconductors , 1995, Proceedings of SEMI Advanced Semiconductor Manufacturing Conference and Workshop.

[2]  B. J. Smith Interconnection networks for shared memory parallel computers , 1995, Proceedings of Second International Workshop on Massively Parallel Processing Using Optical Interconnections.

[3]  B. K. Gilbert,et al.  High-frequency performance of GE high-density interconnect modules , 1992 .

[4]  L.-T. Hwang,et al.  A review of the skin effect as applied to thin film interconnections , 1992 .

[5]  A. Masaki Electrical resistance as a limiting factor for high performance computer packaging , 1989, IEEE Circuits and Devices Magazine.

[6]  N. Yamanaka,et al.  320 Gb/s high-speed ATM switching system hardware technologies based on copper-polyimide MCM , 1994 .

[7]  D. Kossives,et al.  3-D integration of MQW modulators over active submicron CMOS circuits: 375 Mb/s transimpedance receiver-transmitter circuit , 1995, IEEE Photonics Technology Letters.

[8]  B. K. Gilbert,et al.  Performance of TI high density interconnect for 1 GHz digital MCM applications , 1995, 1995 Proceedings. 45th Electronic Components and Technology Conference.

[9]  Joseph W. Goodman,et al.  The Limitations of Interconnections in Providing Communication Between an Array of Points , 1991 .

[10]  T J Cloonan,et al.  Five-stage free-space optical switching network with field-effect transistor self-electro-optic-effect-device smart-pixel arrays. , 1994, Applied optics.

[11]  R. L. Wigington,et al.  Transient Analysis of Coaxial Cables Considering Skin Effect , 1957, Proceedings of the IRE.

[12]  D. Miller Optics for low-energy communication inside digital processors: quantum detectors, sources, and modulators as efficient impedance converters. , 1989, Optics letters.

[13]  Haldun M. Ozaktas A physical approach to communication limits in computation , 1992 .

[14]  Edward C. Jordan,et al.  Reference data for engineers : radio, electronics, computer, and communications , 1985 .

[15]  D.A.B. Miller Hybrid SEED-massively parallel optical interconnections for silicon ICs , 1995, Proceedings of Second International Workshop on Massively Parallel Processing Using Optical Interconnections.

[16]  H. B. Bakoglu,et al.  Circuits, interconnections, and packaging for VLSI , 1990 .

[17]  D. Kossives,et al.  GaAs MQW modulators integrated with silicon CMOS , 1995, IEEE Photonics Technology Letters.

[18]  C. Foster,et al.  EXTENDING THE RANGE OF COPPER FOR FIBER CHANNEL INTERCONNECTS , 1996 .

[19]  A.R. Chraplyvy,et al.  Transmission of eight 20-Gb/s channels over 232 km of conventional single-mode fiber , 1995, IEEE Photonics Technology Letters.

[20]  Ashok V. Krishnamoorthy,et al.  Scaling optoelectronic-VLSI circuits into the 21st century: a technology roadmap , 1996 .

[21]  Donald Christiansen,et al.  Electronics Engineers' Handbook , 1975 .

[22]  A. M. Clogston Reduction of Skin-Effect Losses by the Use of Laminated Conductors , 1951, Proceedings of the IRE.

[23]  T. Egawa,et al.  Recent research trends ande issues in photonic switching technologies , 1993 .