Mechanically Flexible Chip-to-Substrate Optical Interconnections Using Optical Pillars

We experimentally characterize the benefits of using surface-normal mechanically flexible optical waveguides, or optical pillars, for chip-to-substrate optical interconnection. In order to benchmark the performance of the optical pillars, the optical coupling efficiency from a light source to an opt...

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Bibliographic Details
Published in:IEEE transactions on advanced packaging 2008-02, Vol.31 (1), p.143-153
Main Authors: Bakir, M.S., Glebov, A.L., Lee, M.G., Kohl, P.A., Meindl, J.D.
Format: Article
Language:English
Subjects:
Apertures
Applied sciences
Assembly
Chips
Circuit properties
compliant interconnects
Design. Technologies. Operation analysis. Testing
Efficiency
Electric, optical and optoelectronic circuits
Electronics
Exact sciences and technology
flip-chip
input/output (I/O)
Integrated circuits
Integrated optics. Optical fibers and wave guides
integration
Interconnections
Joining
Light sources
Miscellaneous
Noise levels
Optical and optoelectronic circuits
Optical coupling
Optical interconnections
optical interconnects
Optical surface waves
Optical waveguides
Optoelectronic devices
packaging
Photodetectors
Pillars
polymers
Semiconductor device measurement
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Surface waves
Thermal expansion
waveguides
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Description
Summary:We experimentally characterize the benefits of using surface-normal mechanically flexible optical waveguides, or optical pillars, for chip-to-substrate optical interconnection. In order to benchmark the performance of the optical pillars, the optical coupling efficiency from a light source to an optical aperture with and without an optical pillar is measured. For a light source with 12deg beam divergence, a 50times150 mum optical pillar improves the coupling efficiency by 2-4 dB compared to pillar-free (free-space) optical coupling. A 30times150 m optical pillar improves the coupling efficiency by 3-4.5 dB. This demonstrates the importance of using optical pillars when small photodetectors (PDs) and dense optical input/outputs (I/Os) are needed. The optical excess losses of 50times150 mum optical pillars are measured to be less than 0.2 dB. Due to the high mechanical flexibility of the pillars, we also demonstrate that optical pillars enhance the optical coupling efficiency between the chip and substrate when they are misaligned in the lateral direction. This is especially important since the coefficient of thermal expansion of the chip and substrate are often mismatched, and preserving optical alignment and interconnection between them is critical during thermal excursions. The lateral mechanical compliance of the optical pillars is also measured and can be as great as 30 mum/mN. The optical pillars are also shown to be compliant under a compressive force thus allowing the optical I/Os to be assembled on nonplanar surfaces such as low-cost organic substrates.
ISSN:1521-3323
1557-9980
DOI:10.1109/TADVP.2007.914976