Single-mode fiber (SMF) has been th

Single-mode fiber (SMF) has been the de facto medium for high-capacity data transmission for over three decades. However, the exponential growth of internet traffic at about 2 dB per annum could exhaust the available capacity of SMF in the near future [1]. Consequently, there has been an intense research effort in space-division multiplexing (SDM) based on multi-core fiber (MCF) [2–4] or multi-mode fiber (MMF) [5–7] to overcome the barrier from capacity limit of SMF. Compared with the standard MMF that supports over a hundred modes making it extremely difficult to receive and process the optical signal, few-mode fiber (FMF) (supporting a small number of modes) has the potential to significantly reduce the system complexity to a manageable level [8]. Namely, using FMF has the advantage of better mode selectivity and easier management of the mode impairments. By utilizing mode-division multiplexing (MDM) and multiple-input multiple-output (MIMO) digital signal processing (DSP) techniques, it is expected that N spatial modes in a FMF can support N times the capacity of a SMF. The feasibility of using MDM and MIMO in FMF transmission has recently been demonstrated by several groups [5–7, 9–13]. In these experiments, MDM is achieved in two-mode fiber (TMF, the simplest of FMFs) with different combinations of supported modes, e.g., LP01 and LP11 modes [5, 6, 9], two degenerate LP11 modes (LP11a + LP11b) [10], and even all three modes (LP01 + LP11a + LP11b) [7, 11–13]. We also note that there has been exciting progress on SDM in MCF transmission [2–4], and free-space optical communications using orbital angular momentum multiplexing [14]. In this report, we here focus on the SDM systems using FMF. In particular, we will elucidate the overall system architecture, critical components and sub-system modules for MDM transmission.
II. SDM System Architecture
The architecture of N × N SDM transmission system is illustrated in Fig. 1. The signals are first generated by N transmitters. Mode multiplexing of the N signals is achieved using the spatial-mode multiplexer (S-MUX). The signals carried by different spatial modes are then launched into the FMF. During the transmission, all the modes on the same wavelengths are to be processed as an entity as an SDM superchannel, namely, they are amplified, dropped and added at the same time without individual mode processing. After transmission over FMF, the received signals are then mode demultiplexed by a spatial-mode demultiplexer (S-DMUX). The demultiplexed signals are then detected by N coherent receivers. The signals are then converted from optical-to-electrical domain, electrically sampled with high speed ADCs, and finally processed using a DSP module. MIMO algorithm is used for compensating the mode coupling and/or crosstalk in the channel that may be introduced at S-MUX/DEMUX or inside the FMF. It is expected that if the MUX/DEDUX has a unitary transfer function with a rank of N equal to the number of modes supported in a SDM fiber, the channel capacity can be increased by a factor of N times that of single mode system [15].