lower energy ratio increase rate / wireless channel / coherent single carrier long-haul systems / carrier phase / energy ratio increase rate / long-haul optical systems / energy ratio increases / wireless channels / long-haul systems / digital signal processing functions / speed long-haul systems / optics communications / coherent optical communication systems / coherent optical digital communication systems / data communication systems / optical coherent systems / 100G transport systems / coherent optical communications / optical coherent communications / pulse energy / digital communication systems / energy ratio / optical systems / coherent systems / carrier tracking / digital signal processing blocks / optical coherent single carrier systems / coherent optical single carrier systems / energy content / digital signal processing / optical transport systems / energy / /
Movie
D. V / /
Organization
Department of Electrical and Computer Engineering / Optical Society of America OCIS / McGill University / Montreal / Canada Department of Electrical and Computer Engineering / /
Person
X. Chen / M. Luise / C. Laperle / Andrea Luise / W. Zhou / R. Reggiannini / D. J. Krause / Benoît Châtelain / Y. Fan / A. Awadalla / U. Mengali / H. Sun / Z. Li / Charles Laperle / H. Zhu / X. Zhou / T. Wu / /
A family of Nyquist pulses for coherent optical communications Benoît Châtelain,1,* Charles Laperle,2 Kim Roberts,2 Mathieu Chagnon,1 Xian Xu,1 Andrzej Borowiec,2 François Gagnon,3 and David. V. Plant1 1