Research on space-division multiplexing (SDM) came to prominence in
early 2010 being primarily proposed as a means of multiplying the
information-carrying capacity of optical fibers at the same time as
increasing efficiency through resource sharing. Proposed SDM
transmission systems range from parallel single-mode fibers with
shared amplifier pump lasers to the full spatial integration of
transceiver hardware, signal processing, and amplification around a
fiber with over 100 spatial channels comprising multiple cores each
carrying multiple modes. In this paper, we review progress in SDM
research. We first outline the main classifications and features of
novel SDM fibers such as multicore fibers (MCFs), multimode fibers,
few-mode MCFs, and coupled-core MCFs. We review research achievements
of each fiber type before discussing digital-signal processing,
amplifier technology, and milestones of transmission and networking
demonstrations. Finally, we draw comparisons between fiber types
before discussing the current trends and speculate on future
developments and applications beyond optical data transmission.
Inter-core crosstalk is a potential limitation on the achievable data-rates in optical fiber transmission systems using multi-core fibers. Crosstalk arises from unwanted coupling between cores of a homogenous multi-core fiber and it's average power has been observed to vary over time by 10s of decibels, potentially requiring an additional performance margin to achieve acceptable outage probability. Most investigations of crosstalk have so far only considered continuous wave laser light or amplified spontaneous emission as sources of crosstalk. In this paper, we theoretically and experimentally investigate the time-dependence of inter-core crosstalk in a homogeneous multi-core fiber when considering signals with various modulation formats and symbol rates. We find that crosstalk power fluctuations depend on the symbol rate, modulation and skew between cores. For carrier-free signals, such as quadrature amplitude modulation, the crosstalk power is nearly constant for expected conditions of multi-core transmission systems. However, carrier-supported signals, such as OOK, always induce time-varying crosstalk powers.
Quantum key distribution (QKD) can offer communication with unconditional security and is a promising technology to protect next generation communication systems. For QKD to see commercial success, several key challenges have to be solved, such as integrating QKD signals into existing fiber optical networks. In this paper, we present experimental verification of QKD co-propagating with a large number of wavelength division multiplexing (WDM) coherent data channels. We show successful secret key generation over 24 h for a continuous-variable QKD channel jointly transmitted with 100 WDM channels of erbium doped fiber amplified polarization multiplexed 16-ary quadrature amplitude modulation signals amounting to a datarate of 18.3 Tbit/s. Compared to previous co-propagation results in the C-band, we demonstrate more than a factor of 10 increase in the number of WDM channels and more than 90 times higher classical bitrate, showing the co-propagation with Tbit/s data-carrying channels.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.