2017
DOI: 10.15625/0868-3166/26/4/8951
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Study of Optimized Coupling Based on Micro-lensed Fibers for Fibers and Photonic Integrated Circuits in the Framework of Telecommunications and Sensing Applications

Abstract: We demonstrate the interest of expanded beam microlenses (around 55 µm of mode field diameter) to relax positioning tolerances and to decrease reflectance in single mode fiber to fiber interconnexions.  We also point out the interest of micro-lenses of very small mode field diameter (around 2 µm) to improve coupling efficiency in specialty fibers and integrated waveguides for non linear effects based functions and for sensors applications at a wavelength of 1.55 µm.

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Cited by 8 publications
(5 citation statements)
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“…The sensor is characterized with a fibered broadband 1500-1625nm tunable laser source (Yenista Tunics T100S-HP). Its 10 mW output power is coupled into the SU8 waveguide using a lensed fiber with a mode radius of 2.5 μm mounted on micro-alignment bench fabricated in the lab [23]. A second lensed single mode fiber is used to couple the output of the waveguide to a power-meter.…”
Section: Experiments and Resultsmentioning
confidence: 99%
“…The sensor is characterized with a fibered broadband 1500-1625nm tunable laser source (Yenista Tunics T100S-HP). Its 10 mW output power is coupled into the SU8 waveguide using a lensed fiber with a mode radius of 2.5 μm mounted on micro-alignment bench fabricated in the lab [23]. A second lensed single mode fiber is used to couple the output of the waveguide to a power-meter.…”
Section: Experiments and Resultsmentioning
confidence: 99%
“…Moreover, coupling losses stem from two sources namely mode mismatch losses (α d ) and Fresnel reflection losses (α f ). The mode mismatch losses come from the fact that the mode diameter of the micro-lensed fiber used for the injection of light in the waveguide [23] cannot be fully adapted to the diameter of the fundamental mode of the waveguide. The diameter of the fundamental mode of the waveguide is smaller than the mode diameter (2.0 ± 0.2 µ m) of the micro-lensed fiber.…”
Section: Linear Optical Characterizationmentioning
confidence: 99%
“…4 in order to determine their nonlinear propagation characteristics. 9.6 ps pulses with 19.3 MHz repetition rate at 1550 nm were coupled into the waveguide using a micro-lensed fiber mounted on a micro-alignment bench [23]. A variable optical attenuator was used to control the input power and a second micro-lensed fiber was used to couple the output of the waveguide to an optical spectrum analyzer.…”
Section: Self-phase Modulationmentioning
confidence: 99%
“…From that point of view, the traditional end-fire butting method involving coupling with an optical fiber is rather demanding since it necessitates a rigorous end facet polishing of the waveguide and, in the case of thin waveguides, it requires a very critical fiber-waveguide alignment tolerance. Several alternative approaches have thus been proposed, such as micro-lensed fibers [ 10 ] or different variants of taper couplers [ 11 , 12 , 13 ]. However, these options still suppose waveguide (or taper) facet polishing and they do not solve coupling issues with fibers, whose diameter remains much greater than the height (250 nm) of waveguides considered in this work, even for micro-lenses of very small mode-field diameter (~2 µm for standard micro-lensed fibers).…”
Section: Introductionmentioning
confidence: 99%