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Accurate photonic waveguide characterization using an arrayed waveguide structure

Measurement uncertainties in the techniques used to characterize loss in photonic waveguides becomes a significant issue as waveguide loss is reduced through improved fabrication technology. Typical loss measurement techniques involve environmentally unknown parameters such as facet reflectivity or...

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Bibliographic Details
Published in:Optics express 2018-07, Vol.26 (14), p.18082-18095
Main Authors: Gehl, Michael, Boynton, Nicholas, Dallo, Christina, Pomerene, Andrew, Starbuck, Andrew, Hood, Dana, Trotter, Douglas C, Lentine, Anthony, DeRose, Christopher T
Format: Article
Language:English
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Summary:Measurement uncertainties in the techniques used to characterize loss in photonic waveguides becomes a significant issue as waveguide loss is reduced through improved fabrication technology. Typical loss measurement techniques involve environmentally unknown parameters such as facet reflectivity or varying coupling efficiencies, which directly contribute to the uncertainty of the measurement. We present a loss measurement technique, which takes advantage of the differential loss between multiple paths in an arrayed waveguide structure, in which we are able to gather statistics on propagation loss from several waveguides in a single measurement. This arrayed waveguide structure is characterized using a swept-wavelength interferometer, enabling the analysis of the arrayed waveguide transmission as a function of group delay between waveguides. Loss extraction is only dependent on the differential path length between arrayed waveguides and is therefore extracted independently from on and off-chip coupling efficiencies, which proves to be an accurate and reliable method of loss characterization. This method is applied to characterize the loss of the silicon photonic platform at Sandia Labs with an uncertainty of less than 0.06 dB/cm.
ISSN:1094-4087
1094-4087
DOI:10.1364/OE.26.018082