A Single-Chip CMOS-Based Parallel Optical Transceiver Capable of 240-Gb/s Bidirectional Data Rates

Clint
L. Schow; Fuad E. Doany; Christian
W. Baks; Young
H. Kwark; Daniel
M. Kuchta; Jeffrey
A. Kash

Journal of Lightwave Technology
Vol. 27,
Issue 7,
pp. 915-929
(2009)

A Single-Chip CMOS-Based Parallel Optical Transceiver Capable of 240-Gb/s Bidirectional Data Rates

Clint L. Schow, Fuad E. Doany, Christian W. Baks, Young H. Kwark, Daniel M. Kuchta, and Jeffrey A. Kash

Not Accessible

Your library or personal account may give you access

Get PDF
Email
Share
Get Citation
Copy Citation Text
Clint L. Schow, Fuad E. Doany, Christian W. Baks, Young H. Kwark, Daniel M. Kuchta, and Jeffrey A. Kash, "A Single-Chip CMOS-Based Parallel Optical Transceiver Capable of 240-Gb/s Bidirectional Data Rates," J. Lightwave Technol. 27, 915-929 (2009)

Export Citation
- BibTex
- Endnote (RIS)
- HTML
- Plain Text
Save article

Abstract

We report here on the design, fabrication, and high-speed performance of a parallel optical transceiver based on a single CMOS amplifier chip incorporating 16 transmitter and 16 receiver channels. The optical interfaces to the chip are provided by 16-channel photodiode (PD) and VCSEL arrays that are directly flip-chip soldered to the CMOS IC. The substrate emitting/illuminated VCSEL/PD arrays operate at 985 nm and include integrated lenses. The complete transceivers are low-cost, low-profile, highly integrated assemblies that are compatible with conventional chip packaging technology such as direct flip-chip soldering to organic circuit boards. In addition, the packaging approach, dense hybrid integration, readily scales to higher channel counts, supporting future massively parallel optical data buses. All transmitter and receiver channels operate at speeds up to 15 Gb/s for an aggregate bidirectional data rate of 240Gb/s. Interchannel crosstalk was extensively characterized and the dominant source was found to be between receiver channels, with a maximum sensitivity penalty of 1 dB measured at 10 Gb/s for a victim channel completely surrounded by active aggressor channels. The transceiver measures 3.25$\, \times\,$5.25 mm and consumes 2.15 W of power with all channels fully operational. The per-bit power consumption is as low as 9 mW/Gb/s, and this is the first single-chip optical transceiver capable of channel rates in excess of 10 Gb/s. The area efficiency of 14 Gb/s/mm$^{2}$ per link is the highest ever reported for any parallel optical transmitter, receiver, or transceiver reported to-date.

PDF Article

More Like This

Ultra-Low-Power 10 to 28.5 Gb/s CMOS-Driven VCSEL-Based Optical Links [Invited]

Jonathan E. Proesel, Benjamin G. Lee, Alexander V. Rylyakov, Christian W. Baks, and Clint L. Schow
J. Opt. Commun. Netw. 4(11) B114-B123 (2012)

100-Gbps CMOS transceiver for multilane optical backplane system with a 1.3 cm² footprint

Takashi Takemoto, Fumio Yuki, Hiroki Yamashita, Shinji Tsuji, Yong Lee, Koichiro Adachi, Kazunori Shinoda, Yasunobu Matsuoka, Kenji Kogo, Shinji Nishimura, Masaaki Nido, Masahiko Namiwaka, Taro Kaneko, Takara Sugimoto, and Kazuhiko Kurata
Opt. Express 19(26) B777-B783 (2011)

Power-efficient dual-rate optical transceiver

Yongrong Zuo, Fouad E. Kiamiley, Xiaoqing Wang, Ping Gui, Jeremy Ekman, Xingle Wang, Michael J. McFadden, and Michael W. Haney
Appl. Opt. 44(33) 7112-7124 (2005)

Previous Article Next Article

Cited By

You do not have subscription access to this journal. Cited by links are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Abstract

Cited By

Journal of Lightwave Technology