Rebecca Berman scite author profile

Abstract-This paper presents a new optical interconnect system for intra-chip communications based on free-space optics. It provides all-to-all direct communications using dedicated lasers and photodetectors, hence avoiding packet switching while offering ultra-low latency and scalable bandwidth. A technology demonstration prototype is built on a circuit board using fabricated germanium photodetectors, micro-lenses, commercial vertical-cavity surface-emitting lasers, and micro-mirrors. Transmission loss in an optical link of 10-mm distance and crosstalk between two adjacent links are measured as 5 dB and -26 dB, respectively. The measured small-signal bandwidth of the link is 10 GHz.

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

Çiftçioğlu¹,

Berman²,

Wang³

et al. 2012

Opt. Express

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This paper presents the first chip-scale demonstration of an intra-chip free-space optical interconnect (FSOI) we recently proposed. This interconnect system provides point-to-point free-space optical links between any two communication nodes, and hence constructs an all-to-all intra-chip communication fabric, which can be extended for inter-chip communications as well. Unlike electrical and other waveguide-based optical interconnects, FSOI exhibits low latency, high energy efficiency, and large bandwidth density, and hence can significantly improve the performance of future many-core chips. In this paper, we evaluate the performance of the proposed FSOI interconnect, and compare it to a waveguide-based optical interconnect with wavelength division multiplexing (WDM). It shows that the FSOI system can achieve significantly lower loss and higher energy efficiency than the WDM system, even with optimistic assumptions for the latter. A 1×1-cm2 chip prototype is fabricated on a germanium substrate with integrated photodetectors. Commercial 850-nm GaAs vertical-cavity-surface-emitting-lasers (VCSELs) and fabricated fused silica microlenses are 3-D integrated on top of the substrate. At 1.4-cm distance, the measured optical transmission loss is 5 dB, the crosstalk is less than -20 dB, and the electrical-to-electrical bandwidth is 3.3 GHz. The latter is mainly limited by the 5-GHz VCSEL.

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Design of a high temperature (1350 °C) solar receiver based on a liquid metal heat transfer fluid: Sensitivity analysis

et al. 2018

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An intra-chip free-space optical interconnect

Xue

Garg

Çiftçioğlu

et al. 2010

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Continued device scaling enables microprocessors and other systems-on-chip (SoCs) to increase their performance, functionality, and hence, complexity. Simultaneously, relentless scaling, if uncompensated, degrades the performance and signal integrity of on-chip metal interconnects. These systems have therefore become increasingly communications-limited. The communications-centric nature of future high performance computing devices demands a fundamental change in intra-and inter-chip interconnect technologies.Optical interconnect is a promising long term solution. However, while significant progress in optical signaling has been made in recent years, applying conventional packetswitching interconnect architecture to optical networks require repeated E/O and O/E conversions that significantly diminish the advantages of optical signaling. In this paper, we propose to leverage a suite of newly-developed or emerging devices, circuits, and optics technologies to build a fully distributed interconnect architecture based on free-space optics. With a complexity-effective communication support layer to manage occasional packet collisions, the interconnect avoids packet relay altogether, offers an ultra-low transmission latency and scalable bandwidth, and provides fresh opportunities for coherency substrate designs and optimizations.

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Heterogeneous 3-D circuits: Integrating free-space optics with CMOS

Savidis

Çiftçioğlu

et al. 2016

Microelectronics Journal

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Rebecca Berman

A 3-D Integrated Intrachip Free-Space Optical Interconnect for Many-Core Chips

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

Design of a high temperature (1350 °C) solar receiver based on a liquid metal heat transfer fluid: Sensitivity analysis

An intra-chip free-space optical interconnect

Heterogeneous 3-D circuits: Integrating free-space optics with CMOS

Contact Info

Product

Resources

About

Rebecca Berman

A 3-D Integrated Intrachip Free-Space Optical Interconnect for Many-Core Chips

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

Design of a high temperature (1350 °C) solar receiver based on a liquid metal heat transfer fluid: Sensitivity analysis

An intra-chip free-space optical interconnect

Heterogeneous 3-D circuits: Integrating free-space optics with CMOS

Contact Info

Product

Resources

About

Design of a high temperature (1350 °C) solar receiver based on a liquid metal heat transfer fluid: Sensitivity analysis