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13 - Silicon photonic system example

from Part IV - System design

Published online by Cambridge University Press:  05 April 2015

Lukas Chrostowski  and
Michael Hochberg
Lukas Chrostowski
Affiliation:
University of British Columbia, Vancouver
Michael Hochberg
Affiliation:
Coriant Advanced Technology Group
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Silicon Photonics Design
From Devices to Systems
 , pp. 406 - 413
Publisher: Cambridge University Press
Print publication year: 2015

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References

[1] Yang, Liu, Ran, Ding, Qi, Li, et al. “Ultra-compact 320 Gb/s and 160 Gb/s WDM transmitters based on silicon microrings”. OSA Optical Fiber Communication Conference. 2014, Th4G-6 (cit. on pp. 406, 407, 408, 409, 410, 411, 412).Google Scholar
[2] Guoliang, Li, Ashok V., Krishnamoorthy, Ivan, Shubin, et al. “Ring resonator modulators in silicon for interchip photonic links”. IEEE Journal of Selected Topics in Quantum Electronics 19.6 (2013), p. 3401819 (cit. on p. 406).Google Scholar
[3] Chao, Li, Linjie, Zhou, and Andrew W., Poon. “Silicon microring carrier-injection-based modulators/switches with tunable extinction ratios and OR-logic switching by using waveguide cross-coupling”. Optics Express 15.8 (2007), pp. 5069–5076 (cit. on p. 406).Google Scholar
[4] Chen, Chen, Paul O., Leisher, Daniel M., Kuchta, and Kent D., Choquette. “High-speed modulation of index-guided implant-confined vertical-cavity surface-emitting lasers”. IEEE Journal of Selected Topics in Quantum Electronics 15.3 (2009), pp. 673–678 (cit. on p. 406).CrossRefGoogle Scholar
[5] S., Akiyama, T., Kurahashi, T., Baba, et al. “1-V pp 10-Gb/s operation of slow-light silicon Mach-Zehnder modulator in wavelength range of 1 nm”. Group IV Photonics (GFP). IEEE. 2010, pp. 45–47 (cit. on p. 406).Google Scholar
[6] Ivan, Shubin, Guoliang, Li, Xuezhe, Zheng, et al. “Integration, processing and performance of low power thermally tunable CMOS-SOI WDM resonators”. Optical and Quantum Electronics 44.12-13 (2012), pp. 589–604 (cit. on p. 407).Google Scholar
[7] Xuezhe, Zheng, Eric, Chang, Ivan, Shubin, et al. “A 33-mW 100Gbps CMOS silicon photonic WDM transmitter using off-chip laser sources”. National Fiber Optic Engineers Conference. Optical Society of America. 2013, PDP5C-9 (cit. on p. 407).Google Scholar
[8] Kishore, Padmaraju, Dylan F., Logan, Xiaoliang, Zhu, et al. “Integrated thermal stabilization of a microring modulator”. Optics Express 21.12 (2013), pp. 14342–14350 (cit. on p. 407).Google Scholar
[9] Andrew P., Knights, Edgar, Huante-Ceron, Jason, Ackert, et al. “Comb-laser driven WDM for short reach silicon photonic based optical interconnection”. Group IV Photonics (GFP). IEEE. 2012, pp. 210–212 (cit. on p. 407).Google Scholar
[10] Tom, Baehr-Jones, Ran, Ding, Ali, Ayazi, et al. “A 25 Gb/s Silicon Photonics Platform”. arXiv:1203.0767v1(2012) (cit. on p. 408).
[11] Xuezhe, Zheng, Ivan, Shubin, Guoliang, Li, et al. “A tunable 1x4 silicon CMOS photonic wavelength multiplexer/demultiplexer for dense optical interconnects”. Optics Express 18.5 (2010), pp. 5151–5160 (cit. on p. 410).Google Scholar

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