Radiation- and Bound-Mode Propagation in Rectangular, Multimode Dielectric, Channel Waveguides With Sidewall Roughness

Papakonstantinou, Ioannis; James, Richard; Selviah, David R.

doi:10.1109/jlt.2009.2022766

Cited by 19 publications

(14 citation statements)

References 26 publications

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“…[29] noted that both photothermal and photochemical processes were present during the fabrication, due to the higher wavelength (355 nm) of the UV Nd:YAG compared to the KrF excimer laser; although, waveguide loss measurements were not yet reported and the values of wall roughness were not stated. The first measurements of side wall roughness of polymer waveguides have only been reported recently [31]. Therefore, this paper investigates the use of UV Nd:YAG lasers and the optimisation of the fabrication process using another polymer popularly used for optical waveguides due to its inherently low loss for use in Optical Interconnects (OI).…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Polymer Waveguides by Laser Ablation Using a 355 nm Wavelength Nd:YAG Laser

Zakariyah

Conway

Hutt

et al. 2011

J. Lightwave Technol.

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-The demand for optical waveguides integrated into Printed Circuit Boards (PCBs) is increasing as the limitations of copper interconnects are being reached. Optical polymer materials offer a good solution due to their relatively low cost and compatibility with traditional PCB manufacturing processes. Laser ablation is one method of manufacture, for which excimer lasers have been used, butUV Nd:YAG (Neodymium-doped Yttrium Aluminium Garnet) lasersare an attractive alternative due to their widespread use within the PCB industry for drilling vias. In this paper, 355nm, 60ns pulse length UV Nd:YAG laser ablation of Truemode™ acrylate-based optical polymer was investigated. The UV Nd:YAG laser was found to be able to ablate the polymer efficiently and the effects of laser ablation power and pulse repetition frequency (PRF) on depth of ablation were studied and used to determine optimum settings. Multimode optical waveguides were fabricated to demonstrate the process and optical loss measurements were carried out. These measurements demonstrated that the structures were able to transmit light at the data communications wavelength of 850 nm (NIR), but further work is required to reduce the level of loss.The use of UV Nd:YAG as a possible alternative to excimer for laser micromachining would facilitate the rapid deployment of the optical technology within the PCB industry.

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Section: Introductionmentioning

confidence: 99%

Fabrication of Polymer Waveguides by Laser Ablation Using a 355 nm Wavelength Nd:YAG Laser

Zakariyah

Conway

Hutt

et al. 2011

J. Lightwave Technol.

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“…surface roughness (Papakonstantinou et al, 2009) of the waveguide, the scattering caused by imperfections along the "walls" of the waveguide; and . propagation loss, due to the natural (wavelength dependent) absorption of light by the material comprising the waveguide.…”

Section: Environmental Benefits Of Opcbsmentioning

confidence: 99%

“…Additional losses have been identified in other waveguide components such as bends , tapers (Papakonstantinou et al, 2007) and tapered bends (Papakonstantinou et al, 2009). Typically, polymer waveguides become more absorbing at longer infrared wavelengths, however, most commercially available formulations are tuned to provide excellent transmissivity in the near infrared, specifically 850 nm.…”

Section: Environmental Benefits Of Opcbsmentioning

confidence: 99%

Passive assembly of parallel optical devices onto polymer‐based optical printed circuit boards

Pitwon¹,

Hopkins²,

Milward³

et al. 2010

Circuit World

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If you would like to write for this, or any other Emerald publication, then please use our Emerald for Authors service information about how to choose which publication to write for and submission guidelines are available for all. Please visit www.emeraldinsight.com/authors for more information. About Emerald www.emeraldinsight.comEmerald is a global publisher linking research and practice to the benefit of society. The company manages a portfolio of more than 290 journals and over 2,350 books and book series volumes, as well as providing an extensive range of online products and additional customer resources and services.Emerald is both COUNTER 4 and TRANSFER compliant. The organization is a partner of the Committee on Publication Ethics (COPE) and also works with Portico and the LOCKSS initiative for digital archive preservation. AbstractPurpose -The purpose of this paper is to present the latest results from research and development into future optical printed circuit board (OPCB) interconnects and low-cost assembly methods. Design/methodology/approach -A novel method of high-precision passive alignment and assembly to OPCBs was invented and a full evaluation platform developed to demonstrate the viability of this technique. Findings -The technique was successfully deployed to passively align and assemble a lens receptacle onto an embedded polymer waveguide array in an electro-OPCB. The lens receptacle formed a critical part of a dual lens pluggable in-plane connection interface between peripheral optical devices and an OPCB. A lateral in-plane mechanical accuracy of^2 mm has been measured using this technique. Research limitations/implications -As this is a free space optical coupling process, surface scattering at the exposed waveguide end facet was significant.Originality/value -This paper details a novel method of passively assembling arbitrary optical devices onto multi-mode optical waveguides and outlines the procedure and equipment required. A lens coupling solution is also presented which reduces susceptibility of a connecting optical interface to contamination.

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“…In particular when considering the need for commercially viable design and fabrication techniques for embedded stepindex optical waveguides in printed circuit boards, one must operate within a limiting trade-off space, which includes insertion loss, signal dispersion, refractive index difference between core and cladding, waveguide size, misalignment tolerance, minimum bend radius, maximum waveguide length and sidewall roughness [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

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

Pitwon¹,

Smith

Wang

et al. 2012

SPIE Proceedings

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In-plane bend loss represents the greatest commercial inhibitor to deploying multimode optical waveguides on densely populated electro-optical printed circuit boards (OPCB) as the minimum bend radii currently possible are too large to be practical in common designs. We present a concept and fabrication method for creating novel polymer optical waveguide structures with reduced bend losses to enable higher density routing on an OPCB. These nested core waveguide structures comprise a core surrounded by a thin shell of cladding, which allows for twofold modal containment by first a conventional low refractive index contrast (LIC) boundary followed by a secondary high refractive index contrast (HIC) boundary. The purpose of this is to reduce the in-plane bend losses incurred on tightly routed optical channels, while not incurring prohibitive dispersion, sidewall scattering and optical crosstalk penalties. We have designed and fabricated nested core multimode polymer waveguides, evaluated their performance in comparison to conventional step-index waveguides and simulated these structures using the beam propagation method. Preliminary results are presented of our measurements and simulations.

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Radiation- and Bound-Mode Propagation in Rectangular, Multimode Dielectric, Channel Waveguides With Sidewall Roughness

Cited by 19 publications

References 26 publications

Fabrication of Polymer Waveguides by Laser Ablation Using a 355 nm Wavelength Nd:YAG Laser

Fabrication of Polymer Waveguides by Laser Ablation Using a 355 nm Wavelength Nd:YAG Laser

Passive assembly of parallel optical devices onto polymer‐based optical printed circuit boards

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

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