Abstract
Coherent-detection (CoD) permits to fully exploit the four-dimensional (4D) signal space consisting of the in-phase and quadrature components of the two fiber polarizations. A well-known and successful format exploiting such 4D space is Polarization-multiplexed QPSK (PM-QPSK). Recently, new signal constellations specifically designed and optimized in 4D space have been proposed, among which polarization-switched QPSK (PS-QPSK), consisting of a 8-point constellation at the vertices of a 4D polychoron called hexadecachoron. We call it HEXA because of its geometrical features and to avoid acronym mix-up with PM-QPSK, as well as with other similar acronyms. In this paper we investigate the performance of HEXA in direct comparison with PM-QPSK, addressing non-linear propagation over realistic links made up of 20 spans of either standard single mode fiber (SSMF) or non-zero dispersion-shifted fiber (NZDSF). We show that HEXA not only confirms its theoretical sensitivity advantage over PM-QPSK in back-to-back, but also shows a greater resilience to non-linear effects, allowing for substantially increased span loss margins. As a consequence, HEXA appears as an interesting option for dual-format transceivers capable to switch on-the-fly between PM-QPSK and HEXA when channel propagation degrades. It also appears as a possible direct competitor of PM-QPSK, especially over NZDSF fiber and uncompensated links.
Highlights
Optical system research is currently targeting 100 Gb/s per channel transmission and higher
In this paper we investigate the performance of HEXA in direct comparison with Polarization-multiplexed QPSK (PM-QPSK), addressing non-linear propagation over realistic links made up of 20 spans of either standard single mode fiber (SSMF) or non-zero dispersion-shifted fiber (NZDSF)
We show that HEXA confirms its theoretical sensitivity advantage over polarization multiplexing (PM)-QPSK in back-to-back, and shows a greater resilience to non-linear effects, allowing for substantially increased span loss margins
Summary
Optical system research is currently targeting 100 Gb/s per channel transmission and higher. At such speeds, all detrimental fiber propagation effects are exacerbated. All detrimental fiber propagation effects are exacerbated To cope with this challenge, coherent detection (CoD) has been advocated. Thanks to CoD, multilevel constellations and polarization multiplexing (PM) have become practically exploitable, making it possible to increase the bit rate while keeping the baud rate limited. Coherent polarization-multiplexed quadrature phase-shift-keying (PM-QPSK), called polarization-division-multiplexed QPSK (PDM-QPSK) or dual-polarization QPSK (DP-QPSK), seems to be a forerunner for actual 100 Gb/s exploitation [1,2,3,4]. Other PM formats have been proposed and experimentally demonstrated, such as PM binary phase-shift keying (PM-BPSK), PM quadrature amplitude modulation with 8 points (PM-8QAM [5]) and 16 points (PM-16QAM [6]), as well as higher-order PM-QAM constellations [7,8,9]
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