Joint Superchannel Digital Signal Processing for Effective Inter-Channel Interference Cancellation
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Mikael Mazur | Jochen Schröder | Peter A. Andrekson | Magnus Karlsson | P. Andrekson | M. Karlsson | J. Schröder | M. Mazur
[1] N. Wada,et al. Linear block-coding across >5 Tb/s PDM-64QAM spatial-super-channels in a 19-core fiber , 2015, 2015 European Conference on Optical Communication (ECOC).
[2] Peter J. Winzer,et al. Record-High 17.3-bit/s/Hz Spectral Efficiency Transmission over 50 km Using Probabilistically Shaped PDM 4096-QAM , 2018, 2018 Optical Fiber Communications Conference and Exposition (OFC).
[3] Sercan Ö. Arik,et al. High-dimensional modulation for coherent optical communications systems. , 2014, Optics express.
[4] Yu-Ting Hsueh,et al. Super receiver design for superchannel coherent optical systems , 2011, OPTO.
[5] Maxim Kuschnerov,et al. Flex-grid optical networks: spectrum allocation and nonlinear dynamics of super-channels. , 2013, Optics express.
[6] Ali Mirani,et al. Phase-coherent lightwave communications with frequency combs , 2019, Nature Communications.
[7] S. Radic,et al. Overcoming Kerr-induced capacity limit in optical fiber transmission , 2015, Science.
[8] Giulio Colavolpe,et al. Optical Time–Frequency Packing: Principles, Design, Implementation, and Experimental Demonstration , 2014, Journal of Lightwave Technology.
[9] Mikael Mazur,et al. High Spectral Efficiency Coherent Superchannel Transmission With Soliton Microcombs , 2018, Journal of Lightwave Technology.
[10] Yunfeng Peng,et al. Improved FFT-Based Frequency Offset Estimation Algorithm for Coherent Optical Systems , 2014, IEEE Photonics Technology Letters.
[11] Jie Pan,et al. Inter-Channel Crosstalk Cancellation for Nyquist-WDM Superchannel Applications , 2012, Journal of Lightwave Technology.
[12] Mikael Mazur,et al. 10 Tb/s PM-64QAM Self-Homodyne Comb-Based Superchannel Transmission With 4% Shared Pilot Tone Overhead , 2018, Journal of Lightwave Technology.
[13] Kerry J. Vahala,et al. Gigahertz-repetition-rate soliton microcombs , 2018 .
[14] Peter J Winzer,et al. Fiber-optic transmission and networking: the previous 20 and the next 20 years [Invited]. , 2018, Optics express.
[15] M. Gorodetsky,et al. Temporal solitons in optical microresonators , 2012, Nature Photonics.
[16] K. Kikuchi. Characterization of semiconductor-laser phase noise and estimation of bit-error rate performance with low-speed offline digital coherent receivers. , 2012, Optics express.
[17] William Shieh,et al. End-to-End Energy Modeling and Analysis of Long-Haul Coherent Transmission Systems , 2014, Journal of Lightwave Technology.
[18] Roberto Proietti,et al. Demonstration of a carrier frequency offset estimator for 16-/32-QAM coherent receivers: a hardware perspective. , 2018, Optics express.
[19] Seb J. Savory,et al. Design of a 1 Tb/s Superchannel Coherent Receiver , 2016, Journal of Lightwave Technology.
[20] Masataka Nakazawa,et al. 4096 QAM (72 Gbit/s) Single-Carrier Coherent Optical Transmission with a Potential SE of 15.8 bit/s/Hz in All-Raman Amplified 160 km Fiber Link , 2018, 2018 Optical Fiber Communications Conference and Exposition (OFC).
[21] Lutz Lampe,et al. Interference Cancellation for Time-Frequency Packed Super-Nyquist WDM Systems , 2018, IEEE Photonics Technology Letters.
[22] Takehiro Tsuritani,et al. Super-Nyquist-WDM transmission over 7,326-km seven-core fiber with capacity-distance product of 1.03 Exabit/s · km. , 2014, Optics express.
[23] Peter A. Andrekson,et al. Frequency-comb regeneration for self-homodyne superchannels , 2015, 2015 European Conference on Optical Communication (ECOC).
[24] Gabriella Bosco,et al. Advanced Modulation Techniques for Flexible Optical Transceivers: The Rate/Reach Tradeoff , 2019, Journal of Lightwave Technology.
[25] Junwen Zhang,et al. Transmission of 8 × 480-Gb/s super-Nyquist-filtering 9-QAM-like signal at 100 GHz-grid over 5000-km SMF-28 and twenty-five 100 GHz-grid ROADMs. , 2013, Optics express.
[26] Laurent Schmalen,et al. Status and Recent Advances on Forward Error Correction Technologies for Lightwave Systems , 2014, Journal of Lightwave Technology.
[27] Giulio Colavolpe. Faster-than-Nyquist and beyond: how to improve spectral efficiency by accepting interference , 2011 .
[28] Mikael Mazur,et al. Multi-Channel Equalization for Comb-Based Systems , 2020, 2020 Optical Fiber Communications Conference and Exhibition (OFC).
[29] Songnian Fu,et al. Fast and robust chromatic dispersion estimation based on temporal auto-correlation after digital spectrum superposition. , 2015, Optics express.
[30] Polina Bayvel,et al. On the performance of multichannel digital backpropagation in high-capacity long-haul optical transmission. , 2014, Optics express.
[31] Thierry Zami,et al. Throughput comparison between 50-GHz and 37.5-GHz grid transparent networks [Invited] , 2015, IEEE/OSA Journal of Optical Communications and Networking.
[32] L. B. Mercer,et al. 1/f frequency noise effects on self-heterodyne linewidth measurements , 1990 .
[33] S. Daumont,et al. Root-Raised Cosine filter influences on PAPR distribution of single carrier signals , 2008, 2008 3rd International Symposium on Communications, Control and Signal Processing.
[34] Fredrik Rusek,et al. Faster-Than-Nyquist Signaling , 2013, Proceedings of the IEEE.
[35] Maurice O'Sullivan,et al. Advances in High-Speed DACs, ADCs, and DSP for Optical Coherent Transceivers , 2014, Journal of Lightwave Technology.
[36] Seb J. Savory,et al. Digital Signal Processing for Coherent Transceivers Employing Multilevel Formats , 2017, Journal of Lightwave Technology.
[37] Nicolas K Fontaine,et al. Tb/s Coherent Optical OFDM Systems Enabled by Optical Frequency Combs , 2010, Journal of Lightwave Technology.
[38] Xi Chen,et al. Probabilistically shaped PDM 4096-QAM transmission over up to 200 km of fiber using standard intradyne detection. , 2018, Optics express.
[39] Abel Lorences Riesgo,et al. Frequency Comb-Based WDM Transmission Systems Enabling Joint Signal Processing , 2018 .
[40] Michael A. Lombardi,et al. The Use of GPS Disciplined Oscillators as Primary Frequency Standards for Calibration and Metrology Laboratories , 2008 .
[41] Roland Ryf,et al. Fiber nonlinearity compensation by digital backpropagation of an entire 1.2-Tb/s superchannel using a full-field spectrally-sliced receiver , 2013 .
[42] Joachim Speidel,et al. 16QAM symbol timing recovery in the upstream transmission of DOCSIS standard , 2003, IEEE Trans. Broadcast..
[43] Peter J. Winzer,et al. From Scaling Disparities to Integrated Parallelism: A Decathlon for a Decade , 2017, Journal of Lightwave Technology.
[44] Benn C. Thomsen,et al. 246 GHz digitally stitched coherent receiver , 2017, 2017 Optical Fiber Communications Conference and Exhibition (OFC).
[45] P. Poggiolini,et al. On the Performance of Nyquist-WDM Terabit Superchannels Based on PM-BPSK, PM-QPSK, PM-8QAM or PM-16QAM Subcarriers , 2011, Journal of Lightwave Technology.
[46] Linjie Zhou,et al. Real-time full-field arbitrary optical waveform measurement , 2010 .
[47] S. Radic,et al. Two-fold transmission reach enhancement enabled by transmitter-side digital backpropagation and optical frequency comb-derived information carriers. , 2015, Optics express.
[48] Varghese A. Thomas,et al. Frequency Dependent ENoB Requirements for M-QAM Optical Links: An Analysis Using an Improved Digital to Analog Converter Model , 2018, Journal of Lightwave Technology.
[49] Lee Dardis,et al. DSP-Enabled Frequency Locking for Near-Nyquist Spectral Efficiency Superchannels utilizing Integrated Photonics , 2018, 2018 Optical Fiber Communications Conference and Exposition (OFC).
[50] Polina Bayvel,et al. Replacing the Soft-Decision FEC Limit Paradigm in the Design of Optical Communication Systems , 2015, Journal of Lightwave Technology.
[51] Mikael Mazur,et al. Overhead-optimization of pilot-based digital signal processing for flexible high spectral efficiency transmission. , 2019, Optics express.
[52] Yu-Ting Hsueh,et al. Joint digital signal processing for superchannel coherent optical communication systems. , 2013, Optics express.