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OAM‐DM, polarization‐division multiplexing, and wavelength‐division multiplexing is shown in Figure 1.14. OAM‐DM can be combined with other multiplexing schemes, such as time, polarization, and wavelength multiplexing, to satisfy the ever‐growing need for transmission capacity.

      The possibility of using OAM‐DM extends beyond optical frequencies. Thidé et al. [62] were the first to numerically show that antenna arrays can generate OAM beams in radio frequencies and highlight the potential of OAM communications in the lower frequencies. The first experimental test of encoding multiple channels on the same radio frequency using OAM was performed by Tamburini et al. [23]. Subsequently, several OAM‐DM experiments have been performed in the radio frequency domain. In [63], an OAM‐DM 10 m microwave link operated at 10 GHz with four OAM modes was experimentally demonstrated to quadruple the spectral efficiency while keeping a low‐receiver computational complexity. The antenna aperture size was 0.6 m, which corresponds to a far‐field distance of 2D2/λ = 24 m and the 10 m link cannot be considered a far‐field link. In [64], a 32 Gbit s−1 mm‐wave link was demonstrated over 2.5 m at a carrier frequency of 28 GHz with a spectral efficiency of 16 bit s−1 Hz−1 using four independent OAM beams on each of the two orthogonal polarizations. The receiving and transmitting antenna aperture had circular apertures with diameters of 30 cm, which correspond to a far‐field distance of 2D2/λ = 16.8 m and the 2.5 m link cannot be considered a far‐field link. As discussed in Section 1.3, the adoption of OAM in far‐field wireless radio frequency (RF) communications is still an open problem.

      1.3.2.2 Optical Fiber Communications

      Optical fibers have been successfully integrated into communication systems, offering the advantages of large bandwidth, low loss and cost, and immunity to electromagnetic interference [65]. The conventional optical fiber is known as single‐mode fiber (SMF) and includes a core surrounded by a transparent cladding material with a lower index of refraction; the attenuation is typically 0.2 dB/km at 1550 nm and the core radius does not exceed 10 μm [53]. Up to now, the increasing demand for high‐speed data transfer in optical networks has been covered by the conventional SMF. The growing demand for network capacity is expected to continue in the future. According to Ref. [66], the annual global data center traffic will reach 20.6 Zettabytes (zB) – or 20.6 × 1021 bytes – (1.7 zB per month) by the end of 2021, up from 6.8 zB per year (568 exabytes per month) in 2016.

Schematic illustration of the concept of three-dimensional multiplexing to increase the multiplexed data channels by combing (a) OAM-DM, (b) polarization-division multiplexing, and (c) wavelength-division multiplexing.

      Source: Huang et al. [60] © 2014 Optical Society of America.

Schematic illustration of different types of optical fibers.

      To avoid inter‐modal coupling and MIMO DSP complexity in MMFs, OAM modes have been proposed as an alternative modal basis set [69]. The electric field of OAM modes in fibers can be expressed in terms of HE and EH hybrid modes as [71, 72]:

      (1.16)upper O upper A upper M Subscript plus-or-minus l comma m Baseline equals StartLayout Enlarged left-brace 1st Row upper H upper E Subscript l plus 1 comma m Superscript even Baseline plus-or-minus j upper H upper E Subscript l plus 1 comma m Superscript o d d Baseline 2nd Row upper E upper H Subscript l minus 1 comma m Superscript even Baseline plus-or-minus j upper E upper H Subscript l minus 1 comma m Superscript o d d EndLayout

      The intensity profiles of OAM modes, the constituent eigenmodes, and the corresponding propagation constants β are shown in Figure 1.16e–h. Unlike LP modes, OAM modes are formed by the superposition of a single eigenmode type with even and odd symmetry [73]. That is, OAM modes are inherently de‐coupled resulting in low crosstalk, and the constituent eigenmodes with even and odd symmetry share the same propagation constant leading to a reduced walk‐off effect compared to LP modes [74]. As a result, OAM has the potential to increase the spectral efficiency of optical fiber communications while obviating complex DSP algorithms.

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