Interconnect opportunities for gigascale integration

Throughout the past four decades, semiconductor technology has advanced at exponential rates in both productivity and performance. In recent years, multilevel interconnect networks have become the primary limit on the productivity, performance, energy dissipation, and signal integrity of gigascale integration. Consequently, a broad spectrum of novel solutions to the multifaceted interconnect problem must be explored. Here we review recent salient results of this exploration. Based upon prediction of the complete stochastic signal interconnect length distribution of a megacell, optimal reverse scaling of each pair of wiring levels provides a prime opportunity to minimize cell area, clock period, power dissipation, or number of wiring levels. Using a heterogeneous version of Rent's rule, a design methodology for the global signal, clock, and power/ground distribution networks for a system-on-a-chip has been derived. Wiring area, bandwidth, and signal integrity are the prime constraints on the design of the networks. Three-dimensional integration offers the opportunity to reduce the length of the longest global interconnects in a distribution by as much as 75%. Wafer-level batch fabrication of chip input/output interconnects and chip scale packages provides new benefits such as I/O bandwidth enhancement, simultaneous switching-noise reduction, and lower cost of packaging and testing. Microphotonic interconnects have long-term potential to reduce latency, power dissipation, and crosstalk while increasing bandwidth.

[1]  Qiang Chen,et al.  A compact physical via blockage model , 2000, IEEE Trans. Very Large Scale Integr. Syst..

[2]  K. Saraswat,et al.  Interconnect performance modeling for 3D integrated circuits with multiple Si layers , 1999, Proceedings of the IEEE 1999 International Interconnect Technology Conference (Cat. No.99EX247).

[3]  Jurgen Michel,et al.  Materials For Monolithic Silicon Microphotonics , 1997 .

[4]  J.A. Davis,et al.  A three-dimensional stochastic wire-length distribution for variable separation of strata , 2000, Proceedings of the IEEE 2000 International Interconnect Technology Conference (Cat. No.00EX407).

[5]  J.D. Meindl,et al.  Performance improvement using on-board wires for on-chip interconnects , 2000, IEEE 9th Topical Meeting on Electrical Performance of Electronic Packaging (Cat. No.00TH8524).

[6]  Keith A. Bowman,et al.  Minimum power and area n-tier multilevel interconnect architectures using optimal repeater insertion , 2000, ISLPED'00: Proceedings of the 2000 International Symposium on Low Power Electronics and Design (Cat. No.00TH8514).

[7]  Lionel C. Kimerling,et al.  Silicon-Based Microphotonics and Integrated Optoelectronics , 1998 .

[8]  A. Nahman,et al.  Wire-length distribution of three-dimensional integrated circuits , 1999, Proceedings of the IEEE 1999 International Interconnect Technology Conference (Cat. No.99EX247).

[9]  J. Meindl,et al.  Optimal interconnect circuits for VLSI , 1984, 1984 IEEE International Solid-State Circuits Conference. Digest of Technical Papers.

[10]  James D. Meindl,et al.  Low cost high density Compliant Wafer Level Package , 2000 .

[11]  James D. Meindl,et al.  Cost analysis of compliant wafer level package , 2000, 2000 Proceedings. 50th Electronic Components and Technology Conference (Cat. No.00CH37070).

[12]  K. Warner,et al.  Three-dimensional integrated circuits for low-power, high-bandwidth systems on a chip , 2001, 2001 IEEE International Solid-State Circuits Conference. Digest of Technical Papers. ISSCC (Cat. No.01CH37177).

[13]  J.D. Meindl,et al.  Sea of leads: a disruptive paradigm for a system-on-a-chip (SoC) , 2001, 2001 IEEE International Solid-State Circuits Conference. Digest of Technical Papers. ISSCC (Cat. No.01CH37177).

[14]  G. A. Sai-Halasz,et al.  Performance trends in high-end processors , 1995, Proc. IEEE.

[15]  James D. Meindl,et al.  Compact distributed RLC interconnect models. I. Single line transient, time delay, and overshoot expressions , 2000 .

[16]  Payman Zarkesh-Ha,et al.  Prediction of net-length distribution for global interconnects in a heterogeneous system-on-a-chip , 2000, IEEE Trans. Very Large Scale Integr. Syst..

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

[18]  James D. Meindl,et al.  Low power microelectronics: retrospect and prospect , 1995, Proc. IEEE.

[19]  P. Zarkesh-Ha,et al.  Stochastic net length distributions for global interconnects in a heterogeneous system-on-a-chip , 1998, 1998 Symposium on VLSI Technology Digest of Technical Papers (Cat. No.98CH36216).

[20]  V. Milutinovic,et al.  Special Issue On Distributed Shared Memory Systems , 1999, Proc. IEEE.

[21]  P. A. Totta,et al.  SLT device metallurgy and its monolithic extension , 1969 .

[22]  F.J. Leonberger,et al.  Optical interconnections for VLSI systems , 1984, Proceedings of the IEEE.

[23]  J. Meindl,et al.  Compliant wafer level package (CWLP) with embedded air-gaps for sea of leads (SoL) interconnections , 2001, Proceedings of the IEEE 2001 International Interconnect Technology Conference (Cat. No.01EX461).

[24]  Roy L. Russo,et al.  On a Pin Versus Block Relationship For Partitions of Logic Graphs , 1971, IEEE Transactions on Computers.

[25]  P. Zarkesh-Ha,et al.  An integrated architecture for global interconnects in a gigascale system-on-a-chip (GSoC) , 2000, 2000 Symposium on VLSI Technology. Digest of Technical Papers (Cat. No.00CH37104).

[26]  J.D. Meindl,et al.  Optimal interconnection circuits for VLSI , 1985, IEEE Transactions on Electron Devices.

[27]  Hongjie Dai,et al.  Electrical measurements of individual semiconducting single-walled carbon nanotubes of various diameters , 2000 .

[28]  B. Gehman,et al.  Bonding Wire Microelectronic Interconnections , 1980 .

[29]  J.A. Davis,et al.  Analytical models for coupled distributed RLC lines with ideal and nonideal return paths , 2001, International Electron Devices Meeting. Technical Digest (Cat. No.01CH37224).

[30]  Thomas N. Theis,et al.  The future of interconnection technology , 2000, IBM J. Res. Dev..

[31]  William J. Dally,et al.  Digital systems engineering , 1998 .

[32]  Robert S. Schwartz,et al.  Solid Logic Technology: Versatile, high-performance microelectronics , 1964, IBM J. Res. Dev..

[33]  G. Shao,et al.  An efficient room-temperature silicon-based light-emitting diode , 2001, Nature.

[34]  Anoop Gupta,et al.  Cache-coherent distributed shared memory: perspectives on its development and future challenges , 1999, Proc. IEEE.

[35]  James D. Meindl,et al.  Compact distributed RLC interconnect models-Part II: Coupled line transient expressions and peak crosstalk in multilevel networks , 2000 .

[36]  Stuart K. Tewksbury,et al.  Optical Clock Distribution in Electronic Systems , 1997, J. VLSI Signal Process..

[37]  D.A.B. Miller,et al.  Rationale and challenges for optical interconnects to electronic chips , 2000, Proceedings of the IEEE.

[38]  Takayasu Sakurai,et al.  Closed-form expressions for interconnection delay, coupling, and crosstalk in VLSIs , 1993 .

[39]  James D. Meindl,et al.  Input coupling and guided-wave distribution schemes for board-level intra-chip guided-wave optical clock distribution network using volume grating coupler technology , 2001, Proceedings of the IEEE 2001 International Interconnect Technology Conference (Cat. No.01EX461).