Modular architecture for fully non-blocking silicon photonic switch fabric

Nikolova, Dessislava; Calhoun, David M.; Liu, Yang; Rumley, Sébastien; Novack, Ari; Baehr‐Jones, Tom; Hochberg, Michael; Bergman, Keren

doi:10.1038/micronano.2016.71

Cited by 37 publications

(16 citation statements)

References 51 publications

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“…The miniature size of silicon ring resonators make them attractive candidates for large-scale photonic systems as they can be densely integrated on-chip for lowering size, power-consumption, and cost [1][2][3]. As a result, numerous solutions based on ring resonators have been proposed for applications in communications systems [2,[4][5][6], signal processing [1,7], quantum computing [8], sensing [9], and machine learning [10]. A key requirement for the practical use of these systems is the ability to precisely control the resonance conditions of their ring resonators, which allows to 1) correct for fabrication errors, 2) adapt the system in real-time to account for temperature variations or laser wavelength fluctuations, and 3) reprogram the system altogether for implementing various transfer functions and different functionalities.…”

Section: Introductionmentioning

confidence: 99%

Photoconductive heaters enable control of large-scale silicon photonic ring resonator circuits

Jayatilleka

Shoman

Chrostowski

et al. 2019

Optica

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A multitude of large-scale silicon photonic systems based on ring resonators have been envisioned for applications ranging from biomedical sensing to quantum computing and machine learning. Yet, due to the lack of a scalable solution for controlling ring resonators, practical demonstrations have been limited to systems with only a few rings. Here, we demonstrate that large systems can be controlled only by using doped waveguide elements inside their rings whilst preserving their area and cost. We measure the large photoconductive changes of the waveguides for monitoring rings' resonance conditions across high-dynamic ranges and leverage their thermo-optic effects for tuning. This allows us to control ring resonators without requiring additional components, complex tuning algorithms, or additional electrical I/Os. We demonstrate automatic resonance alignment of 31 rings of a 16 × 16 switch and of a 14-ring coupled resonator optical waveguide (CROW), making them the largest, yet most compact, automatically controlled silicon ring resonator circuits to date.

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Section: Introductionmentioning

confidence: 99%

Photoconductive heaters enable control of large-scale silicon photonic ring resonator circuits

Jayatilleka

Shoman

Chrostowski

et al. 2019

Optica

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“…Recently, we proposed a modular switch-and-select topology by assembling 1 × N/N × 1 ring-based spatial (de-)multiplexers with low-loss fibers or 2D optical interposer (Fig. 6c) [76]. Each (de-)multiplexer comprises N ring resonators coupled to a bus waveguide to add or drop optical signals.…”

Section: Mrr-based Optical Switchesmentioning

confidence: 99%

“…This design only allows second-order crosstalk and maintains the number of drop-rings per path at two, while further scale-up only adds bypassing rings through the bus. A proof-of-principle demonstration of an 8 × 8 switch-and-select MRR switch was performed with excellent results [76]. However, it scales with regard to the number of MRRs as 2N 2 and for monolithic integration, managing waveguide crossings at the central shuffle network becomes more and more difficult at high numbers.…”

Section: Mrr-based Optical Switchesmentioning

confidence: 99%

Photonic switching in high performance datacenters [Invited]

et al. 2018

Self Cite

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Photonic switches are increasingly considered for insertion in high performance datacenter architectures to meet the growing performance demands of interconnection networks. We provide an overview of photonic switching technologies and develop an evaluation methodology for assessing their potential impact on datacenter performance. We begin with a review of three categories of optical switches, namely, free-space switches, III-V integrated switches and silicon integrated switches. The state-of-the-art of MEMS, LCOS, SOA, MZI and MRR switching technologies are covered, together with insights on their performance limitations and scalability considerations. The performance metrics that are required for optical switches to truly emerge in datacenters are discussed and summarized, with special focus on the switching time, cost, power consumption, scalability and optical power penalty. Furthermore, the Pareto front of the switch metric space is analyzed. Finally, we propose a hybrid integrated switch fabric design using the III-V/Si wafer bonding technique and investigate its potential impact on realizing reduced cost and power penalty.

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“…Multiple variants of fat pipe switches have been demonstrated in silicon photonics in [2][3][4]. Ring-resonatorbased wavelength-selective switches have been demonstrated by different groups [5,6], and provide the advantage of fine granularity wavelength switches which better fit the traffic patterns in datacenters.…”

mentioning

confidence: 99%

On-chip wavelength locking for photonic switches

et al. 2017

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We present an on-chip wavelength reference with a partial drop ring resonator and germanium photodetector. This approach can be used in ring-resonator-based wavelength-selective switches where absolute wavelength alignment is required. We use the temperature dependence of heater resistance as a temperature sensor. Additionally, we discuss locking speed, statistical variation of heater resistances, and tuning speed of the switches.

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Modular architecture for fully non-blocking silicon photonic switch fabric

Cited by 37 publications

References 51 publications

Photoconductive heaters enable control of large-scale silicon photonic ring resonator circuits

Photoconductive heaters enable control of large-scale silicon photonic ring resonator circuits

Photonic switching in high performance datacenters [Invited]

On-chip wavelength locking for photonic switches

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