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Andrew Ellis

Expressions for the nonlinear transmission performance of multi-mode optical fiber

Typeset version

 

 

TY  - JOUR
  - Ellis, AD; Mac Suibhne,N; Garcia Gunning, FC; Sygletos, S
  - 2013
  - September
  - Optics Express
  - Expressions for the nonlinear transmission performance of multi-mode optical fiber
  - Published
  - ()
  - Fiber optics and optical communications; Nonlinear optics, fibers
  - 21
  - 19
  - 22834
  - 22846
  - We develop an analytical theory which allows us to identify the information spectral density limits of multimode optical fiber transmission systems. Our approach takes into account the Kerr-effect induced interactions of the propagating spatial modes and derives closed-form expressions for the spectral density of the corresponding nonlinear distortion. Experimental characterization results have confirmed the accuracy of the proposed models. Application of our theory in different FMF transmission scenarios has predicted a ~10% variation in total system throughput due to changes associated with inter-mode nonlinear interactions, in agreement with an observed 3dB increase in nonlinear noise power spectral density for a graded index four LP mode fiber.
  - USA
  - http://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-21-19-22834
  - http://dx.doi.org/10.1364/OE.21.022834
  - European Framework Programme Seven (FP7)
  - 258033
DA  - 2013/09
ER  - 
@article{V250206186,
   = {Ellis, AD and  Mac Suibhne,N and  Garcia Gunning, FC and  Sygletos, S},
   = {2013},
   = {September},
   = {Optics Express},
   = {Expressions for the nonlinear transmission performance of multi-mode optical fiber},
   = {Published},
   = {()},
   = {Fiber optics and optical communications; Nonlinear optics, fibers},
   = {21},
   = {19},
  pages = {22834--22846},
   = {{We develop an analytical theory which allows us to identify the information spectral density limits of multimode optical fiber transmission systems. Our approach takes into account the Kerr-effect induced interactions of the propagating spatial modes and derives closed-form expressions for the spectral density of the corresponding nonlinear distortion. Experimental characterization results have confirmed the accuracy of the proposed models. Application of our theory in different FMF transmission scenarios has predicted a ~10% variation in total system throughput due to changes associated with inter-mode nonlinear interactions, in agreement with an observed 3dB increase in nonlinear noise power spectral density for a graded index four LP mode fiber.}},
   = {USA},
   = {http://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-21-19-22834},
   = {http://dx.doi.org/10.1364/OE.21.022834},
   = {European Framework Programme Seven (FP7)},
   = {258033},
  source = {IRIS}
}
AUTHORSEllis, AD; Mac Suibhne,N; Garcia Gunning, FC; Sygletos, S
YEAR2013
MONTHSeptember
JOURNAL_CODEOptics Express
TITLEExpressions for the nonlinear transmission performance of multi-mode optical fiber
STATUSPublished
TIMES_CITED()
SEARCH_KEYWORDFiber optics and optical communications; Nonlinear optics, fibers
VOLUME21
ISSUE19
START_PAGE22834
END_PAGE22846
ABSTRACTWe develop an analytical theory which allows us to identify the information spectral density limits of multimode optical fiber transmission systems. Our approach takes into account the Kerr-effect induced interactions of the propagating spatial modes and derives closed-form expressions for the spectral density of the corresponding nonlinear distortion. Experimental characterization results have confirmed the accuracy of the proposed models. Application of our theory in different FMF transmission scenarios has predicted a ~10% variation in total system throughput due to changes associated with inter-mode nonlinear interactions, in agreement with an observed 3dB increase in nonlinear noise power spectral density for a graded index four LP mode fiber.
PUBLISHER_LOCATIONUSA
ISBN_ISSN
EDITION
URLhttp://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-21-19-22834
DOI_LINKhttp://dx.doi.org/10.1364/OE.21.022834
FUNDING_BODYEuropean Framework Programme Seven (FP7)
GRANT_DETAILS258033
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