Please use this identifier to cite or link to this item:
https://hdl.handle.net/20.500.14279/9449
Title: | Towards high-performance and power-efficient optical NoCs using silicon-in-silica photonic components | Authors: | Kakoulli, Elena Soteriou, Vassos Koutsides, Charalambos Kalli, Kyriacos |
metadata.dc.contributor.other: | Κακουλλή, Έλενα Σωτηρίου, Βάσος Κουτσίδης, Χαράλαμπος Καλλή, Κυριάκος |
Major Field of Science: | Engineering and Technology | Field Category: | Electrical Engineering - Electronic Engineering - Information Engineering | Keywords: | Nanophotonics;Networks-on-Chips;Photonic Interconnects;Silicon-in-Silica | Issue Date: | Jan-2015 | Source: | (2015) Proceedings - 2015 9th International Workshop on Interconnection Network Architectures: On-Chip, Multi-Chip, INA-OCMC 2015, art. no. 7051994, pp. 1-4; 9th International Workshop on Interconnection Network Architectures: On-Chip, Multi-Chip, INA-OCMC 2015; Amsterdam; Netherlands; 19 January | Conference: | International Workshop on Interconnection Network Architectures: On-Chip, Multi-Chip, INA-OCMC | Abstract: | Networks-on-Chips (NoCs) are meeting the growing inter-tile communication needs of multicore chips. However, achieving system scalability by utilizing hundreds of cores on-chip requires high performance, yet energy-efficient on-chip interconnects. As electrical interconnects are marred by high energy-to-bandwidth costs, threatening multicore scalability, on-chip nanophotonics, which offer high throughput, yet energy-efficient communication, are an alternative attractive solution. In this paper we consider silicon nanophotonic components that are embedded completely within the silica (SiO2) substrate as opposed to prior-art that utilizes die on-surface silicon nanophotonics. As nanophotonic components now reside in the silica substrate's subsurface, a greater portion of a chip's real estate can be utilized by cores and routers, while non-obstructive interconnect geometries offering higher network throughput can be implemented. First, we show using detailed simulations based on commercial tools that such silicon-in-silica (SiS) structures are feasible, and then demonstrate our proof of concept by utilizing a hybrid SiS-based photonic mesh-diagonal links topology that provides both higher effective throughput and throughput-to-power ratio versus prior-art. | ISBN: | 978-147991870-6 | DOI: | 10.1109/INA-OCMC.2015.12 | Rights: | © 2015 IEEE. | Type: | Conference Papers | Affiliation : | Cyprus University of Technology | Publication Type: | Peer Reviewed |
Appears in Collections: | Δημοσιεύσεις σε συνέδρια /Conference papers or poster or presentation |
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