Emerging multigigahertz digital and mixed-signal integrated circuits targeted for military applications: dependence on advanced electronic packaging to achieve full performance

A revolution is occurring in several device and integrated circuit technologies (silicon CMOS and its extensions such as silicon germanium and silicon on insulator [SOI] and the so-called III-V compound semiconductors including indium phosphide and gallium arsenide), as well as in solid-state sensors such as infrared detectors enabled by the new materials and devices. These new components are being used to enhance the performance of many systems, and even to create systems never before available, of present interest to the U.S. Department of Defense and of likely near-term interest to parts of the commercial electronics industry such as the landline, wireless, and satellite telecommunications industry. These new components require advanced electronic packaging that does not restrict or degrade their performance. Unfortunately largely due to commercial cost pressures, research in and small-lot manufacture of high-performance packaging though still feasible and not lacking for good ideas for possible enhancement, are no longer being actively pursued either by the principal U.S. government agencies (e.g., DARPA, Air Force), by the commercial electronic packaging industry, or by commercial consortia such as the Microelectronics and Computer Technology Corporation (defunct as of June 2000), Semiconductor Research Corporation (SRC), or Sematech Inc. This paper discusses recent examples of high-performance components and integrated circuit technologies and describes how they are being exploited in new or upgraded systems. Advances in packaging technology that will be required to support the new integrated circuits are also described. In conclusion, several possible approaches are reviewed by which the United States can regain momentum in the development of performance-driven packaging technologies.

[1]  Barry K. Gilbert,et al.  Low-cost, multi-GHz electrical packaging for serial optoelectronic links utilizing vertical cavity surface emitting lasers , 2000 .

[2]  Peter W. Wyatt,et al.  Thin silicide development for fully-depleted SOI CMOS technology , 1998 .

[3]  B.A. Randall,et al.  High-speed, low-power digital and analog circuits implemented in IBM SiGe BiCMOS technology , 1999, GaAs IC Symposium. IEEE Gallium Arsenide Integrated Circuit Symposium. 21st Annual. Technical Digest 1999 (Cat. No.99CH36369).

[4]  B. Oyama,et al.  Fully functional high speed 4-bit A/D converters using InAlAs/InGaAs HBTs , 1993, 15th Annual GaAs IC Symposium.

[5]  B.A. Randall,et al.  Implementation of digital circuits in an InP scaled HBT technology , 1999, GaAs IC Symposium. IEEE Gallium Arsenide Integrated Circuit Symposium. 21st Annual. Technical Digest 1999 (Cat. No.99CH36369).

[6]  B. K. Gilbert,et al.  Implementation of a gallium arsenide multichip digital circuit operating at 500-1000 MHz clock rates using a Si/Cu/SiO/sub 2/ MCM-D technology , 1997 .

[7]  R. Berger,et al.  A 1.3 GHz SOI CMOS test chip for low-power high-speed pulse processing , 1998 .

[8]  Barry Kent Gilbert,et al.  High-frequency characterization of power/ground-plane structures , 1999 .

[9]  John D. Cressler,et al.  Si/SiGe epitaxial-base transistors. II. Process integration and analog applications , 1995 .

[10]  B. K. Gilbert,et al.  Design and test methodology for an analog-to-digital converter multichip module for experimental all-digital radar receiver operating at 2 gigasamples/s , 1999, ECTC 1999.

[11]  J.M. Knecht,et al.  High-frequency characterization of sub-0.25-/spl mu/m fully depleted silicon-on-insulator MOSFETs , 2000, IEEE Electron Device Letters.

[12]  R. H. Walden,et al.  A 3.2-GHz second-order delta-sigma modulator implemented in InP HBT technology , 1995, IEEE J. Solid State Circuits.

[13]  B. K. Gilbert,et al.  MCM packaging for present- and next-generation high clock-rate digital- and mixed-signal electronic systems: areas for development , 1997 .

[14]  G. A. Dove Cooperative research at MCC: a focus on semiconductor-related efforts , 1989 .

[15]  Barry K. Gilbert,et al.  An 8-Bit 2-gigasample/second A/D converter multichip module for digital receiver demonstration on Navy AN/APS-145 E2-C Airborne Early Warning Aircraft radar , 1998 .

[16]  D.L. Miller,et al.  Nonthreshold logic ring oscillators implemented with GaAs/(GaAl)As heterojunction bipolar transistors , 1984, IEEE Electron Device Letters.

[17]  J.F. Jensen,et al.  A bandpass /spl Sigma//spl Delta/ modulator with 92 dB SNR and center frequency continuously programmable from 0 to 70 MHz , 1997, 1997 IEEE International Solids-State Circuits Conference. Digest of Technical Papers.

[18]  D. C. Streit,et al.  A miniaturized W-band monolithic dual-gate InAlAs/InGaAs HEMT mixer , 1993, 15th Annual GaAs IC Symposium.

[19]  Adele E. Schmitz,et al.  An InP-based HBT fab for high-speed digital, analog, mixed-signal, and optoelectronic ICs , 1995, GaAs IC Symposium IEEE Gallium Arsenide Integrated Circuit Symposium 17th Annual Technical Digest 1995.

[20]  Barry K. Gilbert,et al.  VCSEL electrical packaging analysis and design guidelines for multi-GHz applications , 1997 .

[21]  G. Raghavan,et al.  Bandpass delta-sigma modulators for direct IF and RF sampling digital receivers implemented in InP HBT IC technology , 1999 .

[22]  P. Asbeck,et al.  A high-speed LSI GaAs 8x8 bit parallel multiplier , 1982, IEEE Journal of Solid-State Circuits.

[23]  K. Runge,et al.  High speed AlGaAs/GaAs HBT circuits for up to 40 Gb/s optical communication , 1997, GaAs IC Symposium. IEEE Gallium Arsenide Integrated Circuit Symposium. 19th Annual Technical Digest 1997.

[24]  Linda P. B. Katehi,et al.  Silicon-based micromachined packages for high-frequency applications , 1999 .