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11 - High-speed digital logic

Published online by Cambridge University Press:  05 March 2013

Sorin Voinigescu
Sorin Voinigescu
Affiliation:
University of Toronto
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Summary

Broadband serial “wireline” links today routinely reach data rates of at least 10Gb/s with the highest capacity networks, based on the OC-768 standard, running at serial data rates of 43Gb/s. At the time of writing, summer 2011, 110Gb/s links, typically achieved by aggregating four 28Gb/s serial data streams onto a single fiber, are being introduced. Even in microprocessors or ASICs, I/Os with data rates of 10Gb/s and (soon) 25Gb/s are becoming common. Despite the continued progress in CMOS I/Os, these output data rates exceed the speed capabilities of conventional static CMOS logic I/Os even in the advanced 45nm and 32nm nodes, raising the question of how such high speeds can be realized in digital networks. Instead, current-mode logic (CML), or variations thereof, is most often used in the design of very high-speed serial transmitters and receivers.

So, if CML logic is so fast, why is it only used in these high-speed applications? Why isn't this logic family used in microprocessor designs? In fact at one point it was! However, there are two main drawbacks of CML which make it unsuitable for large-scale integration. First, a CML logic gate occupies more area than its CMOS counterpart, due to the use of resistors as well as non-minimum-size transistors. The second, and more costly, drawback is the static power consumption. Even if each logic gate had a tail current of 100μA (a fairly low value for a very high-speed gate), a microprocessor with 10million gates would draw more than 1000 A. In a CMOS technology with a 1V supply, the power could exceed 1000W! Since static CMOS does not consume static current, it is much better suited for highly integrated digital ICs. Instead, CML finds use only in high-speed applications where conventional CMOS logic cannot meet the performance requirements.

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High-Frequency Integrated Circuits , pp. 698 - 755
Publisher: Cambridge University Press
Print publication year: 2013

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References

Voinigescu, S.P., Popescu, P, Banens, P, Copeland, M, Fortier, G, Howlett, K, Herod, M, Marchesan, D, Showell, J, Szilagyi, S, Tran, H, and Weng, J, “Circuits and technologies for highly integrated optical networking ICs at 10Gb/s to 40Gb/s,” Proc. of the IEEE CICC, pp. 331–338, May 2001.
Razavi, Behzad, Design of Integrated Circuits for Optical Communications, Chapter 11, McGraw-Hill, 2003.
Cao, J, Green, M, Momtaz, A, Vakilian, K, Chung, D, Jen, K-C, Caresosa, M, Wang, X, Tan, W-G, Cai, Y, Fujimori, I, and Hairapetian, A, “OC-192 transmitter and receiver in standard 0.18μm CMOS,” IEEE JSSC, 37(12):1768–1780, December 2002.Google Scholar
Rhein, H.-M. “Si and SiGe Bipolar ICs for 10 and 40Gb/s optical-fiber TDM links,” in Int.J. Of High-Speed Electron.Syst., 9):1–37, 1998.Google Scholar
Johns, D and Martin, K, Analog Integrated Circuit Design, John Wiley & Sons, 1997.
Laskin, E, Nicolson, S. T., Chevalier, P, Chantre, A, Sautreuil, B, and Voinigescu, S. P.. “Low-power, low-phase noise SiGe HBT static frequency divider topologies up to 100GHz,” IEEE BCTM Digest, pp. 235–238, October 2006.
Dickson, T. O., Yau, K. H. K., Chalvatzis, T, Mangan, A, Beerkens, R, Westergaard, P, Tazlauanu, M, Yang, M. T., and Voinigescu, S. P., “The invariance of characteristic current densities in nanoscale MOSFETs and its impact on algorithmic design methodologies and design porting of Si(Ge) (Bi)CMOS high-speed building blocks,” IEEE JSSC, 41(8): 1830–1845, August 2006.Google Scholar
Dickson, T. O. and Voinigescu, S. P., “Low-power circuits for a 10.7-to-86 Gb/s serial transmitter in 130nm SiGe BiCMOS,” IEEE JSSC, 42(10): 2077–2085, October 2007.Google Scholar
Suzuki, T, Nakasha, Y, Takahashi, T, Makiyama, K, Imanishi, K, Hirose, T, and Watanabe, Y, “A 90Gb/s 2:1 Multiplexer IC in InP-based HEMT technology,” IEEE ISSCC Digest, pp. 192–193, February 2002.Google Scholar
Dickson, T. O., Beerkens, R, and Voinigescu, S.P., “A 2.5-V, 45Gb/s decision circuit using SiGe BiCMOS logic,” IEEE JSSC, 40(4): 994–1003, 2005.Google Scholar
Laskin, E and Voinigescu, S.P., “A 60mW per Lane, 4 × 23Gb/s 27–1 PRBS generator,” IEEE JSSC, 41(10): 2198–2208, October 2006.Google Scholar
Popescu, P, Dobson, D, Fortier, G, and Weng, J, “High speed logic circuits,” US Patent 6,774,721 B1 granted August 10, 2004.Google Scholar
Chalvatzis, T, Yau, K.H.K., Schvan, P, Yang, M.T., and Voinigescu, S. P., “Low-voltage topologies for 40+ Gb/s circuits in nanoscale CMOS,” IEEE JSSC, 42(7): 1564–1573, July 2007.Google Scholar
Kehrer, D and Wohmuth, H.-D., “A 60Gb/s 0.7V 10-mW monolithic transformer-coupled 2:1multiplexer in 90nm CMOS,” in IEEE CSICS Digest, pp. 105–108, October 2004.Google Scholar
Knapp, H et al., “Static frequency dividers up to 125GHz in SiGe:C bipolar technology,” IEEE BCTM Digest October 2010.
Griffith, Z, Urteaga, M, Pierson, R, Rowell, P, Rodwell, M, and Brar, B, “A 204.8GHz static divide-by-8 frequency divider in 250nm InP HBT,” IEEE CSICS Digest, pp. 53–56, October 2010.
Kim, J., and Plouchart, J.O., “Wideband mm Wave CML static divider in 65nm S01 CMOS technology,” ISSCC Digest, February 2008.
Voinigescu, S.P., Aroca, R, Dickson, T.O., Nicolson, S.T., Chalvatzis, T, Chevalier, P, Garcia, P, Garnier, C, and Sautreuil, B, “Towards a sub-2.5V, 100Gb/s serial transceiver,” IEEE CICC, pp. 471–478, San Jose, CA, Sept. 2007.
Dickson, T.O. and Voinigescu, S.P., “SiGe BiCMOS topologies for low-voltage millimeter-wave voltage-controlled oscillators and frequency dividers,” Si Monolithic Integrated Circuits in RF Systems, Technical Digest, pp. 273–276, Jan. 2006.
Knapp, H, Meister, T. F., Liebl, W, Aufinger, K, Schäfer, H, Böck, Josef, Boguth, S, and Lachner, R, “168GHz dynamic frequency divider in SiGe:C bipolar technology,” IEEE BCTM Digest, pp 190–193, October 2008.
Tomkins, A, Aroca, R.A., Yamamoto, T, Nicolson, S.T., Doi, Y, and Voinigescu, S.P., “A Zero-IF 60GHz 65nm CMOS Transceiver with direct BPSK modulation demonstrating up to 6Gb/s data rates over a 2m wireless link,” IEEE JSSC, 44(8): 2085–2099, August 2009.Google Scholar
Laskin, E, Khanpour, M, Aroca, R, Tang, K.W., Garcia, P., Voinigescu, S.P., “95GHz receiver with fundamental frequency VCO and static frequency divider in 65nm digital CMOS,” IEEE ISSCC Digest, pp. 180–181, February 2008.
Miller, R.L., “Fractional-frequency generators utilizing regenerative modulation,” Proc. IRE, 27: 446–457, July 1939.Google Scholar
Sarkas, I, Hasch, J, Balteanu, A, and Voinigescu, S, “A fundamental frequency, single-chip 120GHz SiGe BiCMOS precision distance sensor with above IC antenna operating over several meters,” submitted to the special mm-wave circuits and systems issue of IEEE MTT, 60(3): 735–812, March 2012.
Seo, M, Urteaga, M, Young, A, and Rodwell, M, “A 305–330+ GHz 2:1 dynamic frequency divider using InP HBTs,” IEEE Microwave and Wireless Component Letters, pp. 468–470, June 2010.
Verma, Shwetabh, Rategh, Hamid R., and Lee, Thomas H., “A unified model for injection-locked frequency dividers,” IEEE JSSC, 36(6):1015–1027, June 2003.Google Scholar
Dickson, T. O., Laskin, E, Khalid, I, Beerkens, R, Xie, J, Karajica, B, and Voinigescu, S.P., “An 80Gb/s 231–1 Pseudo-random binary sequence generator in SiGe BiCMOS technology,” IEEE JSSC, 40(12): 2735–2745, December 2005.Google Scholar
Shahramian, S, Carusone, A. C., Schvan, P, and Voinigescu, S.P., “An 81Gb/s, 1.2V TIALA-retimer in Standard 65nm CMOS,” IEEE CSICS Digest, pp. 215–218, Monetery, CA, October 2008.

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