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A planar plasmonic sensor based on textured metallic disk is demonstrated, where a simple and integrated method is used to excite the spoof localized surface plasmons (LSPs). Multipolar plasmonic resonant modes can be easily observed on the textured metallic disk. The multipolar resonant modes of the textured metallic disk are calculated by eigenmode solver of CST microwave studio. The resonant frequencies...
Monolithically integrated dense WDM photonic network topologies optimized for loss and power footprint of optical components can achieve up to 4x better energy-efficiency and throughput than electrical interconnects in core-to-core, and 10x in core-to-DRAM networks.
This paper presents a monolithically integrated dense WDM photonic network for manycore processors, optimized for loss and power footprint of optical components, which can achieve up to 10x better energy-efficiency and throughput than electrical interconnects.
We present a vertical integration approach for designing silicon photonic networks for communication in manycore systems. Using a top-down approach we project the photonic device requirements for a 64-tile system designed in 22 nm technology.
Future many core processors will require energy-efficient, high-throughput on-chip networks. Silicon-photonics is a promising new interconnect technology which offers lower power, higher bandwidth density, and shorter latencies than electrical interconnects. In this paper we explore using photonics to implement low-diameter non-blocking crossbar and Clos networks. We use analytical modeling to show...
This paper presents an overview of advances in highly-integrated photonic networks for emerging many-core processors. It explores the tight interaction among logical and physical implementations of all-to-all core-to-core and core-to-DRAM networks, and underlying photonic devices.
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