Near-Zero Modal-Dispersion (NEMO) Coupled-Core Multi-Core Fibers

Abstract: We propose a design for coupled-core multi-core fibers that allows to achieve extremely low levels of modal dispersion. These fibers, which we dub NEar-zero MOdal-dispersion (NEMO) fibers, have an even number of cores regularly distributed on a circle, and the optimal design parameters follow from a simple condition independent of the number of cores. The modal-dispersion reduction trades off some of the fiber modemixing effectiveness, yet without compromising its beneficial property of mitigating nonlinear si… Show more

“…pace-division multiplexing (SDM) has emerged as a solution to overcome the capacity limit of single-mode fibers (SMFs) [1]. Among the possible SDM approaches, multimode fibers (MMFs) [2][3][4][5] offer the highest spatial information density followed by coupled-core multi-core fibers (MCFs) [6][7][8][9]. Spatial density plays a critical role in maximizing opportunities for opto-electronic integration gains, and transceiver-specific integration is key to the overall value proposition of SDM.…”

“…For short-reach systems at 850 nm, new types of multimode fiber increasing bandwidth several-fold have been demonstrated: a multicore multimode fiber formed from a large number of single mode cores [3] or a larger core graded-index multimode fibers [21]. For highcapacity SDM systems at ~1.55 m, there has been significant progress on coupled-core MCFs with near-zero modal dispersion [8,9,22] up to 19 cores and on rescaled standard graded-index-core MMFs [23,24] up to 55 spatial modes. Here, we extend the latter approach to a much larger number of modes (up to 1000 spatial modestwice as many polarization modes) by scaling the core-cladding contrast and the core radius within a 125 m cladding.…”

Maximizing the Capacity of Graded-Index Multimode Fibers in the Linear Regime

“…pace-division multiplexing (SDM) has emerged as a solution to overcome the capacity limit of single-mode fibers (SMFs) [1]. Among the possible SDM approaches, multimode fibers (MMFs) [2][3][4][5] offer the highest spatial information density followed by coupled-core multi-core fibers (MCFs) [6][7][8][9]. Spatial density plays a critical role in maximizing opportunities for opto-electronic integration gains, and transceiver-specific integration is key to the overall value proposition of SDM.…”

“…For short-reach systems at 850 nm, new types of multimode fiber increasing bandwidth several-fold have been demonstrated: a multicore multimode fiber formed from a large number of single mode cores [3] or a larger core graded-index multimode fibers [21]. For highcapacity SDM systems at ~1.55 m, there has been significant progress on coupled-core MCFs with near-zero modal dispersion [8,9,22] up to 19 cores and on rescaled standard graded-index-core MMFs [23,24] up to 55 spatial modes. Here, we extend the latter approach to a much larger number of modes (up to 1000 spatial modestwice as many polarization modes) by scaling the core-cladding contrast and the core radius within a 125 m cladding.…”

Maximizing the Capacity of Graded-Index Multimode Fibers in the Linear Regime

Coupled Multi-core Fiber Design with Low Spatial Mode Dispersion for Long-haul Submarine Transmission

Modelling of propagation effects in SDM fibers