Microelectronics, Volume. 52, Issue 6, 936(2022)
A Front-End Amplifying Circuit of Monolithic Integrated Optical Receiver Based on SiGe BiCMOS Process
References(16)
[1] [1] AHN B G, PARK Y. A symmetric-structure CDMA-PON system and its implementation [J]. IEEE Photonic Technol Lett, 2002, 14(9): 1381- 1383.
[2] [2] PAN Q, WANG Y P, YUE C P. A 42-dBΩ 25-Gb/s CMOS transimpedance amplifier with multiple-peaking scheme for optical communications [J]. IEEE Trans Circ Syst II: Expr Brie, 2020, 61(1): 72-76.
[3] [3] CABR M B, DJEKIC D, ROMANO T, et al. Microscale electrochemical cell on a custom CMOS transimpedance amplifier for high temporal resolution single entity electrochemistry [J]. Chemelectrochem, 2020, 7(23): 4724-4729.
[4] [4] WANG C, LUO X L, ATEF M, et al. A 32 GHz 68 dBΩ, low-noise and balance operation transimpedance amplifier in 130 nm SiGe BiCMOS for optical receivers [J]. IEICE Trans Fundamen Elec Commun Comput Sci, 2020, E103A(12): 1408-1416.
[5] [5] COSTANZO R, GAO J Y, SHEN X C, et al. Low-noise balanced photoreceiver with InP-on-Si photodiodes and SiGe BiCMOS transimpedance amplifier [J]. J Lightw Technol, 2021, 39(14): 4837-4846.
[6] [6] SEIFOURI M, AMIRI P, RAKIDE M. Design of broadband transimpedance amplifier for optical communication systems [J]. Microelec J, 2015, 46(8): 679-684.
[7] [7] LOPEZ I, AWNY A, RITO P, et al. A 60 GHz bandwidth differential linear TIA in 130 nm SiGe:C BiCMOS with < 5.5 pA/root Hz[C]// IEEE Bipolar/BiCMOS Circ Technol Meet (BCTM). Miami, FL, USA. 2017: 19-21.
[8] [8] GIANNAKOPOULOS S, HE Z S, DARWAZEH I, et al. Differential common base TIA with 56 dB Ohm gain and 45 GHz bandwidth in 130 nm SiGe [C]// IEEE APMC. Kuala Lumpur, Malaysia. 2017: 13-16.
[9] [9] OMEED M, HOSSEIN H, EHSAN A. A 10-Gb/s inductorless transimpedance amplifier [J]. IEEE Trans Circ Syst II: Expr Brie, 2010, 57(12): 926-930.
[10] [10] WU C H, LEE C H, CHEN W S, et al. CMOS wideband amplifiers using multiple inductive- series peaking technique [J]. IEEE J Sol Sta Circ, 2005, 40(2): 548-552.
[11] [11] CHEN F, WANG R, WANG Z G. Design of a 12 Gbit/s CMOS DNFFCG differential transimpedance amplifier [J]. J Southeast University, 2018, 34(1): 1-5.
[12] [12] HITOSHI I, TOMOYUKI O, MASANORI T, et al. An auto-gain control transimpedance amplifier with low noise and wide input dynamic range for 10-Gb/s optical communication systems [J]. IEEE J Sol Sta Circ, 2001, 36(9): 1303-1308.
[13] [13] LEE Y S, HO W H, CHEN W Z. A 25-Gb/s, 2.1-pJ/bit, fully integrated optical receiver with a baud-rate clock and data recovery [J]. IEEE J Sol Sta Circ, 2019, 8(54): 2243-2254.
[14] [14] FARD M M P, LIBOIRON-LADOUCEUR O, COWAN G E R. 1.23-pJ/bit 25-Gb/s inductor-less optical receiver with low-voltage silicon photodetector [J]. IEEE J Sol Sta Circ, 2018, 6 (53): 1793-1805.
[15] [15] LI S, PAN J R, HE J, et al. A 25-Gb/s inductorless SiGe BiCMOS receiver for 100-Gb/s optical links [J]. Integr.-the VLSI J, 2021, 77(1): 131-138.
[16] [16] WANG H, CHEN Y M, ZHAN J L. A 25 Gbps single-end input limiting amplifier with loss of signal for low power integrated optical receivers [J]. Microw Optical Technol Lett, 2021, 63(5), 1566-1570.
Tools
Get Citation
Copy Citation Text
CHEN Yuxing, XU YongJia, KONG Moufu, LIAO Xiyi, WU Kejun, XU Kaikai. A Front-End Amplifying Circuit of Monolithic Integrated Optical Receiver Based on SiGe BiCMOS Process[J]. Microelectronics, 2022, 52(6): 936
Paper Information
Category:
Received: Oct. 28, 2021
Accepted: --
Published Online: Mar. 11, 2023
The Author Email:
© Copyright 2018-2021 | Chinese Laser Press.
All Rights Reserved 沪ICP备15018463号-20