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Items: 1 to 20 of 88

1.

Multiscale free-space optical interconnects for intrachip global communication: motivation, analysis, and experimental validation.

McFadden MJ, Iqbal M, Dillon T, Nair R, Gu T, Prather DW, Haney MW.

Appl Opt. 2006 Sep 1;45(25):6358-66.

PMID:
16912771
2.

3-D integrated heterogeneous intra-chip free-space optical interconnect.

Ciftcioglu B, Berman R, Wang S, Hu J, Savidis I, Jain M, Moore D, Huang M, Friedman EG, Wicks G, Wu H.

Opt Express. 2012 Feb 13;20(4):4331-45. doi: 10.1364/OE.20.004331.

PMID:
22418191
3.

Modeling diffraction in free-space optical interconnects by the mode expansion method.

Petrović NS, Rakić AD.

Appl Opt. 2003 Sep 10;42(26):5308-18.

PMID:
14503699
4.
5.
6.

Analysis of intrachip electrical and optical fanout.

Pappu AM, Apsel AB.

Appl Opt. 2005 Oct 20;44(30):6361-72.

PMID:
16252648
7.

Performance-based adaptive power optimization for digital optical interconnects.

Wang X, Kiamilev F, Papen GC, Ekman J, Gui P, McFadden MJ, Deroba JC, Haney MW, Kuznia C.

Appl Opt. 2005 Oct 10;44(29):6240-52.

PMID:
16237941
9.

Dispensed polymer waveguides and laser-fabricated couplers for optical interconnects on printed circuit boards.

Leng Y, Yun V, Lucas L, Herman WN, Goldhar J.

Appl Opt. 2007 Feb 1;46(4):602-10.

PMID:
17230255
10.

Analysis of optical channel cross talk for free-space optical interconnects in the presence of higher-order transverse modes.

Tsai FC, O'Brien CJ, Petrović NS, Rakić AD.

Appl Opt. 2005 Oct 20;44(30):6380-7.

PMID:
16252650
11.
12.

Optomechanical design and characterization of a printed-circuit-board-based free-space optical interconnect package.

Zheng X, Marchand PJ, Huang D, Kibar O, Ozkan NS, Esener SC.

Appl Opt. 1999 Sep 10;38(26):5631-40.

PMID:
18324074
13.

Guided-wave and free-space optical interconnects for parallel-processing systems: a comparison.

Camp LJ, Sharma R, Feldman MR.

Appl Opt. 1994 Sep 10;33(26):6168-80. doi: 10.1364/AO.33.006168.

PMID:
20936034
14.

High-speed reconfigurable card-to-card optical interconnects based on hybrid free-space and multi-mode fiber propagations.

Wang K, Nirmalathas A, Lim C, Skafidas E, Alameh K.

Opt Express. 2013 Dec 16;21(25):31166-75. doi: 10.1364/OE.21.031166.

PMID:
24514690
15.

Comparison between optical and electrical interconnects based on power and speed considerations.

Feldman MR, Esener SC, Guest CC, Lee SH.

Appl Opt. 1988 May 1;27(9):1742-51. doi: 10.1364/AO.27.001742.

PMID:
20531646
16.

Integrated polymer microprisms for free space optical beam deflecting.

Reardon C, Di Falco A, Welna K, Krauss T.

Opt Express. 2009 Mar 2;17(5):3424-8.

PMID:
19259180
17.

On the limits of optical interconnects.

Davidson N, Friesem AA, Hasman E.

Appl Opt. 1992 Sep 10;31(26):5426-30. doi: 10.1364/AO.31.005426.

PMID:
20733727
18.

Experimental demonstration of 3×3 10 Gb/s reconfigurable free space optical card-to-card interconnects.

Wang K, Nirmalathas A, Lim C, Skafidas E, Alameh K.

Opt Lett. 2012 Jul 1;37(13):2553-5. doi: 10.1364/OL.37.002553.

PMID:
22743452
19.

Design and implementation of a modulator-based free-space optical backplane for multiprocessor applications.

Kirk AG, Plant DV, Szymanski TH, Vranesic ZG, Tooley FA, Rolston DR, Ayliffe MH, Lacroix FK, Robertson B, Bernier E, Brosseau DF.

Appl Opt. 2003 May 10;42(14):2465-81.

PMID:
12749558
20.

Tolerance of optical interconnections to misalignment.

Neilson DT.

Appl Opt. 1999 Apr 10;38(11):2282-90.

PMID:
18319792

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