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Orbital angular momentum multiplexing

April 26, 2024

Orbital angular momentum (OAM) multiplexing is a physical layer method for multiplexing signals carried on electromagnetic waves using the orbital angular momentum of the electromagnetic waves to distinguish between the different orthogonal signals.[1]

Orbital angular momentum is one of two forms of angular momentum of light. OAM is distinct from, and should not be confused with, light spin angular momentum. The spin angular momentum of light offers only two orthogonal quantum states corresponding to the two states of circular polarization, and can be demonstrated to be equivalent to a combination of polarization multiplexing and phase shifting. OAM on the other hand relies on an extended beam of light, and the higher quantum degrees of freedom which come with the extension. OAM multiplexing can thus access a potentially unbounded set of states, and as such offer a much larger number of channels, subject only to the constraint of real-world optics. The constraint has been clarified in terms of independent scattering channels or the degrees of freedom of scattered fields through angular-spectral analysis, in conjunction with a rigorous Green function method. [2] The degrees of freedom limit is universal for arbitrary spatial-mode multiplexing, which is launched by a planar electromagnetic device, such as antenna, metasurface, etc., with a predefined physical aperture.

As of 2013, although OAM multiplexing promises very significant improvements in bandwidth when used in concert with other existing modulation and multiplexing schemes, it is still an experimental technique, and has so far only been demonstrated in the laboratory. Following the early claim that OAM exploits a new quantum mode of information propagation, the technique has become controversial, with numerous studies suggesting it can be modelled as a purely classical phenomenon by regarding it as a particular form of tightly modulated MIMO multiplexing strategy, obeying classical information theoretic bounds.

As of 2020, new evidence from radio telescope observations suggests that radio-frequency orbital angular momentum may have been observed in natural phenomena on astronomical scales, a phenomenon which is still under investigation.[3]

History edit

OAM multiplexing was demonstrated using light beams in free space as early as 2004.[4] Since then, research into OAM has proceeded in two areas: radio frequency and optical transmission.

Radio frequency edit

Terrestrial experiments edit

An experiment in 2011 demonstrated OAM multiplexing of two incoherent radio signals over a distance of 442 m.[5] It has been claimed that OAM does not improve on what can be achieved with conventional linear-momentum based RF systems which already use MIMO, since theoretical work suggests that, at radio frequencies, conventional MIMO techniques can be shown to duplicate many of the linear-momentum properties of OAM-carrying radio beam, leaving little or no extra performance gain.[6]

In November 2012, there were reports of disagreement about the basic theoretical concept of OAM multiplexing at radio frequencies between the research groups of Tamburini and Thide, and many different camps of communications engineers and physicists, with some declaring their belief that OAM multiplexing was just an implementation of MIMO, and others holding to their assertion that OAM multiplexing is a distinct, experimentally confirmed phenomenon.[7][8][9]

In 2014, a group of researchers described an implementation of a communication link over 8 millimetre-wave channels multiplexed using a combination of OAM and polarization-mode multiplexing to achieve an aggregate bandwidth of 32 Gbit/s over a distance of 2.5 metres.[10] These results agree well with predictions about severely limited distances made by Edfors et al.[6]

The industrial interest for long-distance microwave OAM multiplexing seems to have been diminishing since 2015, when some of the original promoters of OAM-based communication at radio frequencies (including Siae Microelettronica) have published a theoretical investigation[11] showing that there is no real gain beyond traditional spatial multiplexing in terms of capacity and overall antenna occupation.

Radio astronomy edit

In 2019, a letter published in the Monthly Notices of the Royal Astronomical Society presented evidence that OAM radio signals had been received from the vicinity of the M87* black hole, over 50 million light-years distant, suggesting that orbital angular momentum information can propagate over astronomical distances.[3]

Optical edit

OAM multiplexing has been trialled in the optical domain. In 2012, researchers demonstrated OAM-multiplexed optical transmission speeds of up to 2.5 Tbits/s using 8 distinct OAM channels in a single beam of light, but only over a very short free-space path of roughly one metre.[1][12] Work is ongoing on applying OAM techniques to long-range practical free-space optical communication links.[13]

OAM multiplexing can not be implemented in the existing long-haul optical fiber systems, since these systems are based on single-mode fibers, which inherently do not support OAM states of light. Instead, few-mode or multi-mode fibers need to be used. Additional problem for OAM multiplexing implementation is caused by the mode coupling that is present in conventional fibers,[14] which cause changes in the spin angular momentum of modes under normal conditions and changes in orbital angular momentum when fibers are bent or stressed. Because of this mode instability, direct-detection OAM multiplexing has not yet been realized in long-haul communications. In 2012, transmission of OAM states with 97% purity after 20 meters over special fibers was demonstrated by researchers at Boston University.[15] Later experiments have shown stable propagation of these modes over distances of 50 meters,[16] and further improvements of this distance are the subject of ongoing work. Other ongoing research on making OAM multiplexing work over future fibre-optic transmission systems includes the possibility of using similar techniques to those used to compensate mode rotation in optical polarization multiplexing.[citation needed]

Alternative to direct-detection OAM multiplexing is a computationally complex coherent-detection with (MIMO) digital signal processing (DSP) approach, that can be used to achieve long-haul communication,[17] where strong mode coupling is suggested to be beneficial for coherent-detection-based systems.[18]

In the beginning, people achieve OAM multiplexing by employing several phase plates or spatial light modulators. An on-chip OAM multiplexer was then an interest of research. In 2012, a paper by Tiehui Su and et al. demonstrated an integrated OAM multiplexer.[19] Different solutions for integrated OAM multiplexer were demonstrated like Xinlun Cai with his paper in 2012.[20] In 2019, Jan Markus Baumann and et al. designed a chip for OAM multiplexing.[21]

Practical demonstration in optical-fiber system edit

A paper by Bozinovic et al. published in Science in 2013 claims the successful demonstration of an OAM-multiplexed fiber-optic transmission system over a 1.1 km test path.[22][23] The test system was capable of using up to 4 different OAM channels simultaneously, using a fiber with a "vortex" refractive-index profile. They also demonstrated combined OAM and WDM using the same apparatus, but using only two OAM modes.[23]

A paper by Kasper Ingerslev et al. published in Optics Express in 2018 demonstrates a MIMO-free transmission of 12 orbital angular momentum (OAM) modes over a 1.2 km air-core fiber.[24] WDM compatibility of the system is shown by using 60, 25 GHz spaced WDM channels with 10 GBaud QPSK signals.

Practical demonstration in conventional optical-fiber systems edit

In 2014, articles by G. Milione et al. and H. Huang et al. claimed the first successful demonstration of an OAM-multiplexed fiber-optic transmission system over a 5 km of conventional optical fiber,[25][26][27] i.e., an optical fiber having a circular core and a graded index profile. In contrast to the work of Bozinovic et al., which used a custom optical fiber that had a "vortex" refractive-index profile, the work by G. Milione et al. and H. Huang et al. showed that OAM multiplexing could be used in commercially available optical fibers by using digital MIMO post-processing to correct for mode mixing within the fiber. This method is sensitive to changes in the system that change the mixing of the modes during propagation, such as changes in the bending of the fiber, and requires substantial computation resources to scale up to larger numbers of independent modes, but shows great promise.

In 2018 Zengji Yue, Haoran Ren, Shibiao Wei, Jiao Lin & Min Gu[28] at Royal Melbourne Institute of Technology miniaturised this technology, shrinking it from the size of a large dinner table to a small chip which could be integrated into communications networks. This chip could, they predict, increase the capacity of fibre-optic cables by at least 100-fold and likely higher as the technology is further developed.

See also edit

References edit

  1. ^ a b Sebastian Anthony (2012-06-25). "Infinite-capacity wireless vortex beams carry 2.5 terabits per second". Extremetech. Retrieved 2012-06-25.
  2. ^ Yuan, Shuai S. A.; Wu, Jie; Chen, Menglin L. N.; Lan, Zhihao; Zhang, Liang; Sun, Sheng; Huang, Zhixiang; Chen, Xiaoming; Zheng, Shilie; Jiang, Lijun; Zhang, Xianmin; Sha, Wei E. I. (16 December 2021). "Approaching the Fundamental Limit of Orbital-Angular-Momentum Multiplexing Through a Hologram Metasurface". Physical Review Applied. 16 (6): 064042. arXiv:2106.15120. Bibcode:2021PhRvP..16f4042Y. doi:10.1103/PhysRevApplied.16.064042. S2CID 245269914.
  3. ^ a b Tamburini, F.; Thidé, B.; Della Valle, M. (November 2019). "Measurement of the spin of the M87 black hole from its observed twisted light". Monthly Notices of the Royal Astronomical Society: Letters. Vol. 492, no. 1. pp. L22–L27. doi:10.1093/mnrasl/slz176.
  4. ^ Gibson, G.; Courtial, J.; Padgett, M. J.; Vasnetsov, M.; Pas'Ko, V.; Barnett, S. M.; Franke-Arnold, S. (2004). "Free-space information transfer using light beams carrying orbital angular momentum". Optics Express. 12 (22): 5448–5456. Bibcode:2004OExpr..12.5448G. doi:10.1364/OPEX.12.005448. PMID 19484105.
  5. ^ Tamburini, F.; Mari, E.; Sponselli, A.; Thidé, B.; Bianchini, A.; Romanato, F. (2012). "Encoding many channels on the same frequency through radio vorticity: First experimental test". New Journal of Physics. 14 (3): 033001. arXiv:1107.2348. Bibcode:2012NJPh...14c3001T. doi:10.1088/1367-2630/14/3/033001. S2CID 3570230.
  6. ^ a b Edfors, O.; Johansson, A. J. (2012). "Is Orbital Angular Momentum (OAM) Based Radio Communication an Unexploited Area?". IEEE Transactions on Antennas and Propagation. 60 (2): 1126. Bibcode:2012ITAP...60.1126E. doi:10.1109/TAP.2011.2173142. S2CID 446298.
  7. ^ Jason Palmer (8 November 2012). "'Twisted light' data-boosting idea sparks heated debate". BBC News. Retrieved 8 November 2012.
  8. ^ Tamagnone, M.; Craeye, C.; Perruisseau-Carrier, J. (2012). "Comment on 'Encoding many channels on the same frequency through radio vorticity: First experimental test'". New Journal of Physics. 14 (11): 118001. arXiv:1210.5365. Bibcode:2012NJPh...14k8001T. doi:10.1088/1367-2630/14/11/118001. S2CID 46656508.
  9. ^ Tamburini, F.; Thidé, B.; Mari, E.; Sponselli, A.; Bianchini, A.; Romanato, F. (2012). "Reply to Comment on 'Encoding many channels on the same frequency through radio vorticity: First experimental test'". New Journal of Physics. 14 (11): 118002. Bibcode:2012NJPh...14k8002T. doi:10.1088/1367-2630/14/11/118002.
  10. ^ Yan, Y.; Xie, G.; Lavery, M. P. J.; Huang, H.; Ahmed, N.; Bao, C.; Ren, Y.; Cao, Y.; Li, L.; Zhao, Z.; Molisch, A. F.; Tur, M.; Padgett, M. J.; Willner, A. E. (2014). "High-capacity millimetre-wave communications with orbital angular momentum multiplexing". Nature Communications. 5: 4876. Bibcode:2014NatCo...5.4876Y. doi:10.1038/ncomms5876. PMC 4175588. PMID 25224763.
  11. ^ Oldoni, Matteo; Spinello, Fabio; Mari, Elettra; Parisi, Giuseppe; Someda, Carlo Giacomo; Tamburini, Fabrizio; Romanato, Filippo; Ravanelli, Roberto Antonio; Coassini, Piero; Thide, Bo (2015). "Space-Division Demultiplexing in Orbital-Angular-Momentum-Based MIMO Radio Systems". IEEE Transactions on Antennas and Propagation. 63 (10): 4582. Bibcode:2015ITAP...63.4582O. doi:10.1109/TAP.2015.2456953. S2CID 44003803.
  12. ^ "'Twisted light' carries 2.5 terabits of data per second". BBC News. 2012-06-25. Retrieved 2012-06-25.
  13. ^ Djordjevic, I. B.; Arabaci, M. (2010). "LDPC-coded orbital angular momentum (OAM) modulation for free-space optical communication". Optics Express. 18 (24): 24722–24728. Bibcode:2010OExpr..1824722D. doi:10.1364/OE.18.024722. PMID 21164819.
  14. ^ McGloin, D.; Simpson, N. B.; Padgett, M. J. (1998). "Transfer of orbital angular momentum from a stressed fiber-optic waveguide to a light beam". Applied Optics. 37 (3): 469–472. Bibcode:1998ApOpt..37..469M. doi:10.1364/AO.37.000469. PMID 18268608.
  15. ^ Bozinovic, Nenad; Steven Golowich; Poul Kristensen; Siddharth Ramachandran (July 2012). "Control of orbital angular momentum of light with optical fibers". Optics Letters. 37 (13): 2451–2453. Bibcode:2012OptL...37.2451B. doi:10.1364/ol.37.002451. PMID 22743418.
  16. ^ Gregg, Patrick; Poul Kristensen; Siddharth Ramachandran (January 2015). "Conservation of orbital angular momentum in air-core optical fibers". Optica. 2 (3): 267–270. arXiv:1412.1397. Bibcode:2015Optic...2..267G. doi:10.1364/optica.2.000267. S2CID 119238835.
  17. ^ Ryf, Roland; Randel, S.; Gnauck, A. H.; Bolle, C.; Sierra, A.; Mumtaz, S.; Esmaeelpour, M.; Burrows, E. C.; Essiambre, R.; Winzer, P. J.; Peckham, D. W.; McCurdy, A. H.; Lingle, R. (February 2012). "Mode-Division Multiplexing Over 96 km of Few-Mode Fiber Using Coherent 6 × 6 MIMO Processing". Journal of Lightwave Technology. 30 (4): 521–531. Bibcode:2012JLwT...30..521R. doi:10.1109/JLT.2011.2174336. S2CID 6895310.
  18. ^ Kahn, J.M.; K.-P. Ho; M. B. Shemirani (March 2012). "Mode Coupling Effects in Multi-Mode Fibers" (PDF). Proc. Of Optical Fiber Commun. Conf.: OW3D.3. doi:10.1364/OFC.2012.OW3D.3. ISBN 978-1-55752-938-1. S2CID 11736404.
  19. ^ Su, Tiehui; Scott, Ryan P.; Djordjevic, Stevan S.; Fontaine, Nicolas K.; Geisler, David J.; Cai, Xinran; Yoo, S. J. B. (2012-04-23). "Demonstration of free space coherent optical communication using integrated silicon photonic orbital angular momentum devices". Optics Express. 20 (9): 9396–9402. Bibcode:2012OExpr..20.9396S. doi:10.1364/OE.20.009396. ISSN 1094-4087. PMID 22535028.
  20. ^ Cai, Xinlun; Wang, Jianwei; Strain, Michael J.; Johnson-Morris, Benjamin; Zhu, Jiangbo; Sorel, Marc; O’Brien, Jeremy L.; Thompson, Mark G.; Yu, Siyuan (2012-10-19). "Integrated Compact Optical Vortex Beam Emitters". Science. 338 (6105): 363–366. Bibcode:2012Sci...338..363C. doi:10.1126/science.1226528. ISSN 0036-8075. PMID 23087243. S2CID 206543391.
  21. ^ Baumann, Jan Markus; Ingerslev, Kasper; Ding, Yunhong; Frandsen, Lars Hagedorn; Oxenløwe, Leif Katsuo; Morioka, Toshio (2019). "A Silicon Photonic Design Concept for a Chip-to-Fibre Orbital Angular Momentum Mode-Division Multiplexer". 2019 Conference on Lasers and Electro-Optics Europe & European Quantum Electronics Conference (CLEO/Europe-EQEC) (PDF). IEEE. pp. Paper pd_1_9. doi:10.1109/cleoe-eqec.2019.8872253. ISBN 978-1-7281-0469-0. S2CID 204822462.
  22. ^ Jason Palmer (28 June 2013). "'Twisted light' idea makes for terabit rates in fibre". BBC News.
  23. ^ a b Bozinovic, N.; Yue, Y.; Ren, Y.; Tur, M.; Kristensen, P.; Huang, H.; Willner, A. E.; Ramachandran, S. (2013). "Terabit-Scale Orbital Angular Momentum Mode Division Multiplexing in Fibers". Science. 340 (6140): 1545–8. Bibcode:2013Sci...340.1545B. doi:10.1126/science.1237861. PMID 23812709. S2CID 206548907.
  24. ^ Ingerslev, Kasper; Gregg, Patrick; Galili, Michael; Ros, Francesco Da; Hu, Hao; Bao, Fangdi; Castaneda, Mario A. Usuga; Kristensen, Poul; Rubano, Andrea; Marrucci, Lorenzo; Rottwitt, Karsten (2018-08-06). "12 mode, WDM, MIMO-free orbital angular momentum transmission". Optics Express. 26 (16): 20225–20232. Bibcode:2018OExpr..2620225I. doi:10.1364/OE.26.020225. ISSN 1094-4087. PMID 30119335.
  25. ^ Richard Chirgwin (19 Oct 2015). "Boffins' twisted enlightenment embiggens fibre". The Register.
  26. ^ Milione, G.; et al. (2014). "Orbital-Angular-Momentum Mode (De)Multiplexer: A Single Optical Element for MIMO-based and non-MIMO-based Multimode Fiber Systems". Orbital-Angular-Momentum Mode (De)Multiplexer: A Single Optical Element for MIMO-based and non-MIMO based Multimode Fiber Systems. pp. M3K.6. doi:10.1364/OFC.2014.M3K.6. ISBN 978-1-55752-993-0. S2CID 2055103. {{cite book}}: |journal= ignored (help)
  27. ^ Huang, H.; Milione, G.; et al. (2015). "Mode division multiplexing using an orbital angular momentum mode sorter and MIMO-DSP over a graded-index few-mode optical fibre". Scientific Reports. 5: 14931. Bibcode:2015NatSR...514931H. doi:10.1038/srep14931. PMC 4598738. PMID 26450398.
  28. ^ Gu, Min; Lin, Jiao; Wei, Shibiao; Ren, Haoran; Yue, Zengji (2018-10-24). "Angular-momentum nanometrology in an ultrathin plasmonic topological insulator film". Nature Communications. 9 (1): 4413. Bibcode:2018NatCo...9.4413Y. doi:10.1038/s41467-018-06952-1. ISSN 2041-1723. PMC 6200795. PMID 30356063.

External links edit

  • * Siae Microelettronica patent

April 26, 2024
orbital, angular, momentum, multiplexing, orbital, angular, momentum, multiplexing, physical, layer, method, multiplexing, signals, carried, electromagnetic, waves, using, orbital, angular, momentum, electromagnetic, waves, distinguish, between, different, ort. Orbital angular momentum OAM multiplexing is a physical layer method for multiplexing signals carried on electromagnetic waves using the orbital angular momentum of the electromagnetic waves to distinguish between the different orthogonal signals 1 Orbital angular momentum is one of two forms of angular momentum of light OAM is distinct from and should not be confused with light spin angular momentum The spin angular momentum of light offers only two orthogonal quantum states corresponding to the two states of circular polarization and can be demonstrated to be equivalent to a combination of polarization multiplexing and phase shifting OAM on the other hand relies on an extended beam of light and the higher quantum degrees of freedom which come with the extension OAM multiplexing can thus access a potentially unbounded set of states and as such offer a much larger number of channels subject only to the constraint of real world optics The constraint has been clarified in terms of independent scattering channels or the degrees of freedom of scattered fields through angular spectral analysis in conjunction with a rigorous Green function method 2 The degrees of freedom limit is universal for arbitrary spatial mode multiplexing which is launched by a planar electromagnetic device such as antenna metasurface etc with a predefined physical aperture As of 2013 update although OAM multiplexing promises very significant improvements in bandwidth when used in concert with other existing modulation and multiplexing schemes it is still an experimental technique and has so far only been demonstrated in the laboratory Following the early claim that OAM exploits a new quantum mode of information propagation the technique has become controversial with numerous studies suggesting it can be modelled as a purely classical phenomenon by regarding it as a particular form of tightly modulated MIMO multiplexing strategy obeying classical information theoretic bounds As of 2020 update new evidence from radio telescope observations suggests that radio frequency orbital angular momentum may have been observed in natural phenomena on astronomical scales a phenomenon which is still under investigation 3 Contents 1 History 2 Radio frequency 2 1 Terrestrial experiments 2 2 Radio astronomy 3 Optical 3 1 Practical demonstration in optical fiber system 3 2 Practical demonstration in conventional optical fiber systems 4 See also 5 References 6 External linksHistory editOAM multiplexing was demonstrated using light beams in free space as early as 2004 4 Since then research into OAM has proceeded in two areas radio frequency and optical transmission Radio frequency editTerrestrial experiments edit An experiment in 2011 demonstrated OAM multiplexing of two incoherent radio signals over a distance of 442 m 5 It has been claimed that OAM does not improve on what can be achieved with conventional linear momentum based RF systems which already use MIMO since theoretical work suggests that at radio frequencies conventional MIMO techniques can be shown to duplicate many of the linear momentum properties of OAM carrying radio beam leaving little or no extra performance gain 6 In November 2012 there were reports of disagreement about the basic theoretical concept of OAM multiplexing at radio frequencies between the research groups of Tamburini and Thide and many different camps of communications engineers and physicists with some declaring their belief that OAM multiplexing was just an implementation of MIMO and others holding to their assertion that OAM multiplexing is a distinct experimentally confirmed phenomenon 7 8 9 In 2014 a group of researchers described an implementation of a communication link over 8 millimetre wave channels multiplexed using a combination of OAM and polarization mode multiplexing to achieve an aggregate bandwidth of 32 Gbit s over a distance of 2 5 metres 10 These results agree well with predictions about severely limited distances made by Edfors et al 6 The industrial interest for long distance microwave OAM multiplexing seems to have been diminishing since 2015 when some of the original promoters of OAM based communication at radio frequencies including Siae Microelettronica have published a theoretical investigation 11 showing that there is no real gain beyond traditional spatial multiplexing in terms of capacity and overall antenna occupation Radio astronomy edit In 2019 a letter published in the Monthly Notices of the Royal Astronomical Society presented evidence that OAM radio signals had been received from the vicinity of the M87 black hole over 50 million light years distant suggesting that orbital angular momentum information can propagate over astronomical distances 3 Optical editOAM multiplexing has been trialled in the optical domain In 2012 researchers demonstrated OAM multiplexed optical transmission speeds of up to 2 5 Tbits s using 8 distinct OAM channels in a single beam of light but only over a very short free space path of roughly one metre 1 12 Work is ongoing on applying OAM techniques to long range practical free space optical communication links 13 OAM multiplexing can not be implemented in the existing long haul optical fiber systems since these systems are based on single mode fibers which inherently do not support OAM states of light Instead few mode or multi mode fibers need to be used Additional problem for OAM multiplexing implementation is caused by the mode coupling that is present in conventional fibers 14 which cause changes in the spin angular momentum of modes under normal conditions and changes in orbital angular momentum when fibers are bent or stressed Because of this mode instability direct detection OAM multiplexing has not yet been realized in long haul communications In 2012 transmission of OAM states with 97 purity after 20 meters over special fibers was demonstrated by researchers at Boston University 15 Later experiments have shown stable propagation of these modes over distances of 50 meters 16 and further improvements of this distance are the subject of ongoing work Other ongoing research on making OAM multiplexing work over future fibre optic transmission systems includes the possibility of using similar techniques to those used to compensate mode rotation in optical polarization multiplexing citation needed Alternative to direct detection OAM multiplexing is a computationally complex coherent detection with MIMO digital signal processing DSP approach that can be used to achieve long haul communication 17 where strong mode coupling is suggested to be beneficial for coherent detection based systems 18 In the beginning people achieve OAM multiplexing by employing several phase plates or spatial light modulators An on chip OAM multiplexer was then an interest of research In 2012 a paper by Tiehui Su and et al demonstrated an integrated OAM multiplexer 19 Different solutions for integrated OAM multiplexer were demonstrated like Xinlun Cai with his paper in 2012 20 In 2019 Jan Markus Baumann and et al designed a chip for OAM multiplexing 21 Practical demonstration in optical fiber system edit A paper by Bozinovic et al published in Science in 2013 claims the successful demonstration of an OAM multiplexed fiber optic transmission system over a 1 1 km test path 22 23 The test system was capable of using up to 4 different OAM channels simultaneously using a fiber with a vortex refractive index profile They also demonstrated combined OAM and WDM using the same apparatus but using only two OAM modes 23 A paper by Kasper Ingerslev et al published in Optics Express in 2018 demonstrates a MIMO free transmission of 12 orbital angular momentum OAM modes over a 1 2 km air core fiber 24 WDM compatibility of the system is shown by using 60 25 GHz spaced WDM channels with 10 GBaud QPSK signals Practical demonstration in conventional optical fiber systems edit In 2014 articles by G Milione et al and H Huang et al claimed the first successful demonstration of an OAM multiplexed fiber optic transmission system over a 5 km of conventional optical fiber 25 26 27 i e an optical fiber having a circular core and a graded index profile In contrast to the work of Bozinovic et al which used a custom optical fiber that had a vortex refractive index profile the work by G Milione et al and H Huang et al showed that OAM multiplexing could be used in commercially available optical fibers by using digital MIMO post processing to correct for mode mixing within the fiber This method is sensitive to changes in the system that change the mixing of the modes during propagation such as changes in the bending of the fiber and requires substantial computation resources to scale up to larger numbers of independent modes but shows great promise In 2018 Zengji Yue Haoran Ren Shibiao Wei Jiao Lin amp Min Gu 28 at Royal Melbourne Institute of Technology miniaturised this technology shrinking it from the size of a large dinner table to a small chip which could be integrated into communications networks This chip could they predict increase the capacity of fibre optic cables by at least 100 fold and likely higher as the technology is further developed See also editAngular momentum of light Optical vortex Polarization division multiplexing Vorticity Wavelength division multiplexingReferences edit a b Sebastian Anthony 2012 06 25 Infinite capacity wireless vortex beams carry 2 5 terabits per second Extremetech Retrieved 2012 06 25 Yuan Shuai S A Wu Jie Chen Menglin L N Lan Zhihao Zhang Liang Sun Sheng Huang Zhixiang Chen Xiaoming Zheng Shilie Jiang Lijun Zhang Xianmin Sha Wei E I 16 December 2021 Approaching the Fundamental Limit of Orbital Angular Momentum Multiplexing Through a Hologram Metasurface Physical Review Applied 16 6 064042 arXiv 2106 15120 Bibcode 2021PhRvP 16f4042Y doi 10 1103 PhysRevApplied 16 064042 S2CID 245269914 a b Tamburini F Thide B Della Valle M November 2019 Measurement of the spin of the M87 black hole from its observed twisted light Monthly Notices of the Royal Astronomical Society Letters Vol 492 no 1 pp L22 L27 doi 10 1093 mnrasl slz176 Gibson G Courtial J Padgett M J Vasnetsov M Pas Ko V Barnett S M Franke Arnold S 2004 Free space information transfer using light beams carrying orbital angular momentum Optics Express 12 22 5448 5456 Bibcode 2004OExpr 12 5448G doi 10 1364 OPEX 12 005448 PMID 19484105 Tamburini F Mari E Sponselli A Thide B Bianchini A Romanato F 2012 Encoding many channels on the same frequency through radio vorticity First experimental test New Journal of Physics 14 3 033001 arXiv 1107 2348 Bibcode 2012NJPh 14c3001T doi 10 1088 1367 2630 14 3 033001 S2CID 3570230 a b Edfors O Johansson A J 2012 Is Orbital Angular Momentum OAM Based Radio Communication an Unexploited Area IEEE Transactions on Antennas and Propagation 60 2 1126 Bibcode 2012ITAP 60 1126E doi 10 1109 TAP 2011 2173142 S2CID 446298 Jason Palmer 8 November 2012 Twisted light data boosting idea sparks heated debate BBC News Retrieved 8 November 2012 Tamagnone M Craeye C Perruisseau Carrier J 2012 Comment on Encoding many channels on the same frequency through radio vorticity First experimental test New Journal of Physics 14 11 118001 arXiv 1210 5365 Bibcode 2012NJPh 14k8001T doi 10 1088 1367 2630 14 11 118001 S2CID 46656508 Tamburini F Thide B Mari E Sponselli A Bianchini A Romanato F 2012 Reply to Comment on Encoding many channels on the same frequency through radio vorticity First experimental test New Journal of Physics 14 11 118002 Bibcode 2012NJPh 14k8002T doi 10 1088 1367 2630 14 11 118002 Yan Y Xie G Lavery M P J Huang H Ahmed N Bao C Ren Y Cao Y Li L Zhao Z Molisch A F Tur M Padgett M J Willner A E 2014 High capacity millimetre wave communications with orbital angular momentum multiplexing Nature Communications 5 4876 Bibcode 2014NatCo 5 4876Y doi 10 1038 ncomms5876 PMC 4175588 PMID 25224763 Oldoni Matteo Spinello Fabio Mari Elettra Parisi Giuseppe Someda Carlo Giacomo Tamburini Fabrizio Romanato Filippo Ravanelli Roberto Antonio Coassini Piero Thide Bo 2015 Space Division Demultiplexing in Orbital Angular Momentum Based MIMO Radio Systems IEEE Transactions on Antennas and Propagation 63 10 4582 Bibcode 2015ITAP 63 4582O doi 10 1109 TAP 2015 2456953 S2CID 44003803 Twisted light carries 2 5 terabits of data per second BBC News 2012 06 25 Retrieved 2012 06 25 Djordjevic I B Arabaci M 2010 LDPC coded orbital angular momentum OAM modulation for free space optical communication Optics Express 18 24 24722 24728 Bibcode 2010OExpr 1824722D doi 10 1364 OE 18 024722 PMID 21164819 McGloin D Simpson N B Padgett M J 1998 Transfer of orbital angular momentum from a stressed fiber optic waveguide to a light beam Applied Optics 37 3 469 472 Bibcode 1998ApOpt 37 469M doi 10 1364 AO 37 000469 PMID 18268608 Bozinovic Nenad Steven Golowich Poul Kristensen Siddharth Ramachandran July 2012 Control of orbital angular momentum of light with optical fibers Optics Letters 37 13 2451 2453 Bibcode 2012OptL 37 2451B doi 10 1364 ol 37 002451 PMID 22743418 Gregg Patrick Poul Kristensen Siddharth Ramachandran January 2015 Conservation of orbital angular momentum in air core optical fibers Optica 2 3 267 270 arXiv 1412 1397 Bibcode 2015Optic 2 267G doi 10 1364 optica 2 000267 S2CID 119238835 Ryf Roland Randel S Gnauck A H Bolle C Sierra A Mumtaz S Esmaeelpour M Burrows E C Essiambre R Winzer P J Peckham D W McCurdy A H Lingle R February 2012 Mode Division Multiplexing Over 96 km of Few Mode Fiber Using Coherent 6 6 MIMO Processing Journal of Lightwave Technology 30 4 521 531 Bibcode 2012JLwT 30 521R doi 10 1109 JLT 2011 2174336 S2CID 6895310 Kahn J M K P Ho M B Shemirani March 2012 Mode Coupling Effects in Multi Mode Fibers PDF Proc Of Optical Fiber Commun Conf OW3D 3 doi 10 1364 OFC 2012 OW3D 3 ISBN 978 1 55752 938 1 S2CID 11736404 Su Tiehui Scott Ryan P Djordjevic Stevan S Fontaine Nicolas K Geisler David J Cai Xinran Yoo S J B 2012 04 23 Demonstration of free space coherent optical communication using integrated silicon photonic orbital angular momentum devices Optics Express 20 9 9396 9402 Bibcode 2012OExpr 20 9396S doi 10 1364 OE 20 009396 ISSN 1094 4087 PMID 22535028 Cai Xinlun Wang Jianwei Strain Michael J Johnson Morris Benjamin Zhu Jiangbo Sorel Marc O Brien Jeremy L Thompson Mark G Yu Siyuan 2012 10 19 Integrated Compact Optical Vortex Beam Emitters Science 338 6105 363 366 Bibcode 2012Sci 338 363C doi 10 1126 science 1226528 ISSN 0036 8075 PMID 23087243 S2CID 206543391 Baumann Jan Markus Ingerslev Kasper Ding Yunhong Frandsen Lars Hagedorn Oxenlowe Leif Katsuo Morioka Toshio 2019 A Silicon Photonic Design Concept for a Chip to Fibre Orbital Angular Momentum Mode Division Multiplexer 2019 Conference on Lasers and Electro Optics Europe amp European Quantum Electronics Conference CLEO Europe EQEC PDF IEEE pp Paper pd 1 9 doi 10 1109 cleoe eqec 2019 8872253 ISBN 978 1 7281 0469 0 S2CID 204822462 Jason Palmer 28 June 2013 Twisted light idea makes for terabit rates in fibre BBC News a b Bozinovic N Yue Y Ren Y Tur M Kristensen P Huang H Willner A E Ramachandran S 2013 Terabit Scale Orbital Angular Momentum Mode Division Multiplexing in Fibers Science 340 6140 1545 8 Bibcode 2013Sci 340 1545B doi 10 1126 science 1237861 PMID 23812709 S2CID 206548907 Ingerslev Kasper Gregg Patrick Galili Michael Ros Francesco Da Hu Hao Bao Fangdi Castaneda Mario A Usuga Kristensen Poul Rubano Andrea Marrucci Lorenzo Rottwitt Karsten 2018 08 06 12 mode WDM MIMO free orbital angular momentum transmission Optics Express 26 16 20225 20232 Bibcode 2018OExpr 2620225I doi 10 1364 OE 26 020225 ISSN 1094 4087 PMID 30119335 Richard Chirgwin 19 Oct 2015 Boffins twisted enlightenment embiggens fibre The Register Milione G et al 2014 Orbital Angular Momentum Mode De Multiplexer A Single Optical Element for MIMO based and non MIMO based Multimode Fiber Systems Orbital Angular Momentum Mode De Multiplexer A Single Optical Element for MIMO based and non MIMO based Multimode Fiber Systems pp M3K 6 doi 10 1364 OFC 2014 M3K 6 ISBN 978 1 55752 993 0 S2CID 2055103 a href Template Cite book html title Template Cite book cite book a journal ignored help Huang H Milione G et al 2015 Mode division multiplexing using an orbital angular momentum mode sorter and MIMO DSP over a graded index few mode optical fibre Scientific Reports 5 14931 Bibcode 2015NatSR 514931H doi 10 1038 srep14931 PMC 4598738 PMID 26450398 Gu Min Lin Jiao Wei Shibiao Ren Haoran Yue Zengji 2018 10 24 Angular momentum nanometrology in an ultrathin plasmonic topological insulator film Nature Communications 9 1 4413 Bibcode 2018NatCo 9 4413Y doi 10 1038 s41467 018 06952 1 ISSN 2041 1723 PMC 6200795 PMID 30356063 External links edit Siae Microelettronica patent Retrieved from https en wikipedia org w index php title Orbital angular momentum multiplexing amp oldid 1220742155, wikipedia, wiki, book, books, library,

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