59-dBOmega 68-GHz Variable Gain-Bandwidth Differential Linear TIA in 0.7-µm InP DHBT for 400-Gb/s Optical Communication Systems | IEEE Conference Publication | IEEE Xplore
Subscribe
ADVANCED SEARCH
Conferences >2015 IEEE Compound Semiconduc...

59-dBOmega 68-GHz Variable Gain-Bandwidth Differential Linear TIA in 0.7-µm InP DHBT for 400-Gb/s Optical Communication Systems

PDF
Jean-Yves Dupuy; Filipe Jorge; Muriel Riet; Virginie Nodjiadjim; Herve Aubry; Agnieszka Konczykowska
All Authors

Abstract:

We report a variable-gain and variable-bandwidth differential linear transimpedance amplifier (TIA-VGA) realised in a 0.7-μm indium phosphide (InP) double heterojunction ...Show More

Metadata

Abstract:

We report a variable-gain and variable-bandwidth differential linear transimpedance amplifier (TIA-VGA) realised in a 0.7-μm indium phosphide (InP) double heterojunction bipolar transistor (DHBT) technology. The circuits yields 59-dBΩ / 900-Ω differential transimpedance gain with 20-dB control and 68-GHz -3-dB bandwidth with 30-GHz control. Output-referred 1-dB-compression single-ended amplitude is larger than -4-dBm (400mVpp) up to 60GHz. High quality On-Off-Keying (OOK) eye diagrams are measured at 64 GBd. Consuming less than 475 mW, this circuit exhibits the largest bandwidth for a linear TIA-VGA, to our knowledge, along with wide-range gain and bandwidth controls. This makes it a particularly suitable and flexible candidate for high-symbol-rate photoreceivers dedicated to next generation 400-Gb/s and 1-Tb/s optical communication systems.
Published in: 2015 IEEE Compound Semiconductor Integrated Circuit Symposium (CSICS)
Date of Conference: 11-14 October 2015
Date Added to IEEE Xplore: 02 November 2015
ISBN Information:

ISSN Information:

DOI: 10.1109/CSICS.2015.7314463
Conference Location: New Orleans, LA, USA
References is not available for this document.
Contents

I. Introduction

The fast development of optical digital coherent systems over the past 10 years, initially for 40 Gb/s, then 100 Gb/s and nowadays for up to 400 Gb/s

http://www.alcatel-lucent.com/press/2013/002786.

, has set a new standard symbol rate typically around 28–32 GBd, depending on the overhead from the forward error correction (FEC) codes. Despite the great capacity growth enabled by the improvement of spectral efficiency, as allowed by coherent technologies, further increase is needed, such that pushing the symbol rate to ever higher levels remains a prime challenge [1]. In this field, most of the work has been carried out on signal generation with high speed digital to analog converters [2] and signal detection [3] with off-line or quasi-real-time digital signal processing. In this context, low-noise amplification of received signals is not needed, due to the use of digital storage oscilloscopes with sensitive front-end heads

http://teledynelecroy.com/100ghz/.

. However, such an analog function will be needed as soon as ADC-based true-real-time implementations will be sought, as already happened for the 28-32-GBd generation. In practice, a transimpedance amplifier with gain control is required to provide a low-noise linearly-amplified and constant-amplitude signal to drive the following ADC in its full dynamic range. Leading edge implementations, targeting 28-32-GBd applications, have been reported in InP [4] and SiGe

Inphi IN3250TA 32 Gb/s Dual Differential Input Linear Amplifier.

. In this paper, we report the first TIA-VGA (Fig. 1) compatible with 60-GHz-class applications, with a - 3-dB bandwidth and differential transimpedance gain reaching respectively 68 GHz and 59 dBΩ, along with wide gain and bandwidth controls.

TIA-VGA microphotograph (chip size: .

Select All
1.
G. Raybon, "High Symbol Rate Transmission Systems for Data Rates from 400 Gb/s to 1 Tb/s", Optical Fiber Communications Conference and Exhibition (OFC) OSA, pp. M3G.1, 2015.
View Article
Google Scholar
2.
S. Randel, D. Pilori, S. Corteselli, G. Raybon, A. Adamiecki, A. Gnauck, et al., "All-Electronic Flexibly Programmable 864-Gb/s Single-Carrier PDM-64-QAM", Optical Fiber Communications Conference and Exhibition (OFC) OSA, pp. Th5C.8, March 2014.
View Article
Google Scholar
3.
G. Raybon, B. Guan, A. Adamiecki, P.J. Winzer, N.K. Fontaine, S. Chen, et al., "160-Gbaud Coherent Receiver Based on 100-GHz Bandwidth 240-GS/s Analog-to-Digital Conversion", Optical Fiber Communication Conference (OFC) OSA, pp. M2G.1, March 2015.
View Article
Google Scholar
4.
K. Murata, T. Saida, I. Ogawa, R. Kasahara, Y. Muramoto, H. Fukuyama, et al., "100-Gbit/s PDM-QPSK Integrated Coherent Receiver Front-End for Optical Communications", Compound Semiconductor Integrated Circuit Symposium (CSICS) IEEE, pp. 1-4, Oct. 2011.
View Article
Google Scholar
5.
E. Sackinger, "The Transimpedance Limit", Transactions on Circuits and Systems I: Regular Papers IEEE, vol. 57, no. 8, pp. 1848-1856, Aug. 2010.
View Article
Google Scholar
6.
J.- Y. Dupuy, F. Jorge, M. Riet, A. Konczykowska and J. Godin, "InP DHBT Transimpedance Amplifiers with Automatic Offset Compensation for 100 Gbit/s Optical Communications", European Microwave Integrated Circuits Conference (EuMIC) IEEE, pp. 341-344, Sept 2010.
Google Scholar
7.
C.D. Holdenried, J.W. Haslett and M.W. Lynch, "Analysis and Design of HBT Cherry-Hooper Amplifiers with Emitter-Follower Feedback for Optical Communications", Journal of Solid-State Circuits IEEE, vol. 39, no. 11, pp. 1959-1967, Nov. 2004.
View Article
Google Scholar
8.
K. Ohhata, F. Arakawa, T. Masuda, N. Shiramizu and K. Washio, "40 Gb/s Analog IC Chipset for Optical Receivers-AGC Amplifier Fullwave Rectifier and Decision Circuit Implemented Using Self-aligned SiGe HBTs", International Microwave Symposium Digest IEEE MTT-S, vol. 3, no. 3, pp. 1701-1704, May 2001.
Google Scholar
9.
J. Godin, V. Nodjiadjim, M. Riet, P. Berdaguer, O. Drisse, E. Derouin, et al., "Submicron InP DHBT Technology for High-Speed High-Swing Mixed-Signal ICs", Compound Semiconductor Integrated Circuits Symposium (CSICS) IEEE, pp. 1-4, Oct. 2008.
View Article
Google Scholar
10.
E. Sackinger, "On the Noise Optimum of FET Broadband Transimpedance Amplifiers", Transactions on Circuits and Systems I: Regular Papers IEEE, vol. 59, no. 12, pp. 2881-2889, Dec. 2012.
View Article
Google Scholar
11.
J.S. Weiner, J.S. Lee, A. Leven, Y. Baeyens, V. Houtsma, G. Georgiou, et al., "An InGaAs-InP HBT Differential Transimpedance Amplifier with 47-GHz Bandwidth", Journal of Solid-State Circuits IEEE, vol. 39, no. 10, pp. 1720-1723, Oct. 2004.
View Article
Google Scholar
12.
C.H. Fields, T. Tsen, C. McGuire, Y. Yeong, D. Zehnder, S. Thomas, et al., "110+ GHz Transimpedance Amplifier in InP-HBT Technology for 100 Gbit Ethernet", Microwave and Wireless Components Letters IEEE, vol. 20, no. 8, pp. 465-467, Aug. 2010.
View Article
Google Scholar
13.
C. Knochenhauer, S. Hauptmann, J.C. Scheytt and F. Ellinger, "A Jitter-Optimized Differential 40-Gbit/s Transimpedance Amplifier in SiGe BiCMOS", Transactions on Microwave Theory and Techniques IEEE, vol. 58, no. 10, pp. 2538-2548, Oct. 2010.
View Article
Google Scholar
14.
K.W. Kobayashi, "State-of-the-art 60 GHz 3.6 k-Ohm Transimpedance Amplifier for 40 Gb/s and Beyond", Radio Frequency Integrated Circuits (RFIC) Symposium IEEE, pp. 55-58, June 2003.
View Article
Google Scholar
15.
C.-F. Liao and S.-I. Liu, "A 40Gb/s Transimpedance-AGC Amplifier with 19dB DR in 90nm CMOS", Digest of Technical Papers of International Solid-State Circuits Conference (ISSCC) IEEE, pp. 54-586, Feb. 2007.
View Article
Google Scholar
16.
S.G. Kim, S.H. Jung, Y.S. Eo, S.H. Kim, X. Ying, H. Choi, et al., "A 50-Gb/s Differential Transimpedance Amplifier in 65nm CMOS Technology", Asian Solid-State Circuits Conference (A-SSCC) IEEE, pp. 357-360, Nov. 2014.
View Article
Google Scholar

Contact IEEE to Subscribe
More Like This
Nonbinary LDPC-Coded Modulation for Rate-Adaptive Optical Fiber Communication Without Bandwidth Expansion

IEEE Photonics Technology Letters

Published: 2012

Beyond the Bandwidth Limit: A Tutorial on Low-Noise Amplifier Circuits for Advanced Systems Based on III–V Process

IEEE Transactions on Circuits and Systems II: Express Briefs

Published: 2024

Show More

References

References is not available for this document.

IEEE Account

Purchase Details

Profile Information

Need Help?

A not-for-profit organization, IEEE is the world's largest technical professional organization dedicated to advancing technology for the benefit of humanity.
© Copyright 2025 IEEE - All rights reserved. Use of this web site signifies your agreement to the terms and conditions.