An integrated CMOS–silicon photonics transmitter with a 112 gigabaud transmission and picojoule per bit energy efficiency
An integrated CMOS–silicon photonics transmitter with a 112 gigabaud transmission and picojoule per bit energy efficiency
The widening application of advanced digital infrastructure requires the development of communications technologies with increased data transmission rates. However, ensuring that this can be achieved in an energy-efficient way is challenging. Here we report an integrated complementary metal–oxide–semiconductor/silicon-photonics-based transmitter in which a switching current is applied to the passive-equalization-network-guided silicon Mach–Zehnder modulator, rather than driving a standard Mach–Zehnder modulator with a traditional voltage swing. This approach allows the total electrical energy to be selectively distributed to different frequency components by choosing an appropriate inductance and near-end termination impedance values. With the approach, we achieve 112 gigabaud—112 gigabits per second on–off keying and 224 gigabit per second pulse-amplitude modulation with four levels—transmission with energy efficiencies below picojoules per bit, and without the need for signal-shaping functions in the data source. We also investigate the bit error rate for different electrical and optical power conditions at 100 gigabaud, including the electrical power consumption of the driver amplifier.
910-921
Li, Ke
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Thomson, David J.
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Liu, Shenghao
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Zhang, Weiwei
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Cao, Wei
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Littlejohns, Callum G.
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Yan, Xingzhao
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Ebert, Martin
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Banakar, Mehdi
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Meng, Fanfan
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Du, Han
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Reed, Graham T.
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23 October 2023
Li, Ke
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Thomson, David J.
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Liu, Shenghao
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Zhang, Weiwei
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Cao, Wei
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Littlejohns, Callum G.
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Yan, Xingzhao
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Ebert, Martin
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Banakar, Mehdi
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Meng, Fanfan
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Du, Han
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Reed, Graham T.
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Li, Ke, Thomson, David J., Liu, Shenghao, Zhang, Weiwei, Cao, Wei, Littlejohns, Callum G., Yan, Xingzhao, Ebert, Martin, Banakar, Mehdi, Meng, Fanfan, Du, Han and Reed, Graham T.
(2023)
An integrated CMOS–silicon photonics transmitter with a 112 gigabaud transmission and picojoule per bit energy efficiency.
Nature Electronics, 6, .
(doi:10.1038/s41928-023-01048-1).
Abstract
The widening application of advanced digital infrastructure requires the development of communications technologies with increased data transmission rates. However, ensuring that this can be achieved in an energy-efficient way is challenging. Here we report an integrated complementary metal–oxide–semiconductor/silicon-photonics-based transmitter in which a switching current is applied to the passive-equalization-network-guided silicon Mach–Zehnder modulator, rather than driving a standard Mach–Zehnder modulator with a traditional voltage swing. This approach allows the total electrical energy to be selectively distributed to different frequency components by choosing an appropriate inductance and near-end termination impedance values. With the approach, we achieve 112 gigabaud—112 gigabits per second on–off keying and 224 gigabit per second pulse-amplitude modulation with four levels—transmission with energy efficiencies below picojoules per bit, and without the need for signal-shaping functions in the data source. We also investigate the bit error rate for different electrical and optical power conditions at 100 gigabaud, including the electrical power consumption of the driver amplifier.
Text
s41928-023-01048-1
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Accepted/In Press date: 15 September 2023
Published date: 23 October 2023
Identifiers
Local EPrints ID: 500339
URI: http://eprints.soton.ac.uk/id/eprint/500339
PURE UUID: 47a76dfe-1380-4311-a137-6663142a6a86
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Date deposited: 25 Apr 2025 16:42
Last modified: 17 Sep 2025 01:48
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Contributors
Author:
Ke Li
Author:
David J. Thomson
Author:
Shenghao Liu
Author:
Weiwei Zhang
Author:
Wei Cao
Author:
Callum G. Littlejohns
Author:
Xingzhao Yan
Author:
Martin Ebert
Author:
Mehdi Banakar
Author:
Fanfan Meng
Author:
Han Du
Author:
Graham T. Reed
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