TR2016-014
A Fully-Blind Fractionally-Oversampled Frequency Domain Adaptive Equalizer
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- , "A Fully-Blind Fractionally-Oversampled Frequency Domain Adaptive Equalizer", Optical Fiber Communication Conference and Exposition (OFC), DOI: 10.1364/OFC.2016.Th2A.33, March 2016.BibTeX TR2016-014 PDF
- @inproceedings{Paskov2016mar,
- author = {Paskov, Milen and Millar, David S. and Parsons, Kieran},
- title = {A Fully-Blind Fractionally-Oversampled Frequency Domain Adaptive Equalizer},
- booktitle = {Optical Fiber Communication Conference and Exposition (OFC)},
- year = 2016,
- month = mar,
- doi = {10.1364/OFC.2016.Th2A.33},
- isbn = {978-1-943580-07-1},
- url = {https://www.merl.com/publications/TR2016-014}
- }
- , "A Fully-Blind Fractionally-Oversampled Frequency Domain Adaptive Equalizer", Optical Fiber Communication Conference and Exposition (OFC), DOI: 10.1364/OFC.2016.Th2A.33, March 2016.
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Abstract:
A frequency domain adaptive equalizer, operating with fewer than 2 Sa/Symbol is investigated. Steady state performance and dynamic operation are demonstrated without equalizer training. We find that the equalizer exhibits no penalty as low as 1.1 Sa/Symbol.
Related News & Events
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AWARD MERL researchers presented 5 papers at the 2016 Optical Fiber Communication Conference (OFC), including one "Top Scored" paper Date: March 24, 2016
Awarded to: Toshiaki Koike-Akino, Keisuke Kojima, David S. Millar, Kieran Parsons, Tsuyoshi Yoshida, Takashi Sugihara
MERL Contacts: Toshiaki Koike-Akino; Kieran Parsons
Research Areas: Communications, Electronic and Photonic Devices, Signal ProcessingBrief- Five papers from the Optical Comms team were presented at the 2016 Optical Fiber Conference (OFC) held in Anaheim, USA in March 2016. The papers relate to enhanced modulation formats, constellation shaping, chromatic dispersion estimation, low complexity adaptive equalization and coding for coherent optical links. The top-scored paper studied optimal selection of coding and modulation sets to jointly maximize nonlinear tolerance and spectral efficiency.