Polymer optical waveguides with reduced in-plane bend loss for electro-optical PCBs

Pitwon, Richard; Smith, Callum; Wang, Kai; Graham-Jones, Jasper; Selviah, David R.; Halter, Markus; Worrall, Alex

doi:10.1117/12.919817

Cited by 3 publications

(5 citation statements)

References 13 publications

(12 reference statements)

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“…In-plane bends are an inextricable requirement in complex waveguide layouts on OPCBs; however, bend radii as large as the minimum bend radius of 17 mm deployed on the First-Light midplane would be difficult to accommodate within a high density PCB layout, especially where high numbers of optical waveguides are involved. Research into novel waveguide structures allowing a reduction in bend loss and corresponding reduction in minimum bend radius is currently underway to address this issue [29].…”

Section: Discussion and Future Workmentioning

confidence: 99%

See 1 more Smart Citation

FirstLight: Pluggable Optical Interconnect Technologies for Polymeric Electro-Optical Printed Circuit Boards in Data Centers

Pitwon¹,

Wang

Graham-Jones

et al. 2012

J. Lightwave Technol.

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The protocol data rate governing data storage devices will increase to over 12 Gb/s by 2013 thereby imposing unmanageable cost and performance burdens on future digital data storage systems. The resulting performance bottleneck can be substantially reduced by conveying high-speed data optically instead of electronically. A novel active pluggable 82.5 Gb/s aggregate bit rate optical connector technology, the design and fabrication of a compact electro-optical printed circuit board to meet exacting specifications, and a method for low cost, high precision, passive optical assembly are presented. A demonstration platform was constructed to assess the viability of embedded electro-optical midplane technology in such systems including the first ever demonstration of a pluggable active optical waveguide printed circuit board connector. High-speed optical data transfer at 10.3125 Gb/s was demonstrated through a complex polymer waveguide interconnect layer embedded into a 262 mm 240 mm 4.3 mm electro-optical midplane. Bit error rates of less than and optical losses as low as 6 dB were demonstrated through nine multimode polymer waveguides with an aggregate data bandwidth of 92.8125 Gb/s.

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Section: Discussion and Future Workmentioning

confidence: 99%

“…Though the relatively large minimum bend radii required at this stage would place significant routing constraints on future optical PCB layouts, these could be effectively mitigated by refinement of manufacturing techniques or novel structuring of the waveguide to reduce bend loss as demonstrated by Xyratex [29].…”

Section: B Optical Interconnect Designmentioning

confidence: 99%

FirstLight: Pluggable Optical Interconnect Technologies for Polymeric Electro-Optical Printed Circuit Boards in Data Centers

Pitwon¹,

Wang

Graham-Jones

et al. 2012

J. Lightwave Technol.

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“…One approach to achieve this would be to prepare a separate straight waveguide by laser ablation alongside the waveguide containing the mirror; the former can then be used as a reference for which losses due to the mirror can be obtained. It will be interesting to compare the losses associated with these structures to those already obtained with curved waveguides of different radii (Papakonstantinou et al, 2006(Papakonstantinou et al, , 2007Pitwon et al, 2012) to determine which contributes most to the total loss budget of the system. To improve manufacturing throughput, this inplane coupling technique could also be applied to fabricated mirrors in waveguides pre-prepared by other methods such as photolithography.…”

Section: Stagementioning

confidence: 99%

“…out-of-plane coupling, but also within a layer (in-plane routing); the latter would be extremely important if OI is extended to the chip level. In-plane routing can be achieved with curved multimode waveguides, but the signal losses are affected by the radii of curvature (Papakonstantinou et al, 2006(Papakonstantinou et al, , 2008Pitwon et al, 2012). The fabrication of in-plane mirrors as an alternative approach was therefore the primary objective of the work reported in this paper.…”

Section: Introductionmentioning

confidence: 99%

Integrated in‐plane mirror and multimode waveguide fabrication using 248 nm excimer laser ablation for optical interconnects on PCBs

Zakariyah

Conway²,

Hutt³

et al. 2012

Circuit World

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Purpose -The purpose of this paper is to present the need, and a potential solution, for in-plane routing of optical signals for optical-enabled circuit boards. Design/methodology/approach -Multimode waveguides and integrated 458 in-plane mirror structures were made in a low loss acrylate-based photopolymer using excimer laser ablation. The fabrication of multimode waveguides and mirrors was carried out in a single laser system which minimised alignment issues. Findings -It was established that in-plane mirror fabrication using laser ablation can be achieved and can potentially be used to define mirrors in waveguides made by other methods such as photolithography.Research limitations/implications -While the concept (integrated in-plane mirror) was demonstrated, the viability of its deployment will depend on the results of optical loss measurements for which further research is required. Originality/value -The paper gives an overview of the design concept and fabrication steps for an in-plane embedded mirror.

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“…In the first case, air trenches, where waveguide cladding material is removed and replaced with air, act to boost the refractive index contrast between the waveguide core and clad at the bend sections, thereby decreasing the radiative bending loss. The strategy has been successfully applied to waveguides made in polymers [28]- [30], silica glass [31] and oxynitride [32]. Similar concepts have also been adapted to shallow rib waveguides [33], [34] and laser-written glass waveguides [35].…”

Section: Introductionmentioning

confidence: 99%

Compact and Fabrication-Tolerant Waveguide Bends Based on Quadratic Reflectors

Qiu

Zuo

et al. 2020

J. Lightwave Technol.

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Polymer optical waveguides with reduced in-plane bend loss for electro-optical PCBs

Cited by 3 publications

References 13 publications

FirstLight: Pluggable Optical Interconnect Technologies for Polymeric Electro-Optical Printed Circuit Boards in Data Centers

FirstLight: Pluggable Optical Interconnect Technologies for Polymeric Electro-Optical Printed Circuit Boards in Data Centers

Integrated in‐plane mirror and multimode waveguide fabrication using 248 nm excimer laser ablation for optical interconnects on PCBs

Compact and Fabrication-Tolerant Waveguide Bends Based on Quadratic Reflectors

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