Daniel M. Kuchta scite author profile

We demonstrate 4 × 4 and 8 × 8 switch fabrics in multistage topologies based on 2 × 2 Mach-Zehnder interferometer switching elements. These fabrics are integrated onto a single chip with digital CMOS logic, device drivers, thermo-optic phase tuners, and electro-optic phase modulators using IBM's 90 nm silicon integrated nanophotonics technology. We show that the various switch-and-driver systems are capable of delivering nanosecondscale reconfiguration times, low crosstalk, compact footprints, low power dissipations, and broad spectral bandwidths. Moreover, we validate the dynamic reconfigurability of the switch fabric changing the state of the fabric using time slots with sub-100-ns durations. We further verify the integrity of high-speed data transfers under such dynamic operation. This chip-scale switching system technology may provide a compelling solution to replace some routing functionality currently implemented as bandwidth-and power-limited electronic switch chips in high-performance computing systems.

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160 Gb/s Bidirectional Polymer-Waveguide Board-Level Optical Interconnects Using CMOS-Based Transceivers

Doany

Schow

Baks

et al. 2009

IEEE Trans. Adv. Packag.

134

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64Gb/s Transmission over 57m MMF using an NRZ Modulated 850nm VCSEL

Kuchta

Rylyakov

Schow

et al. 2014

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Low Power and High Density Optical Interconnects for Future Supercomputers

Pepeljugoski

Kash

Doany

et al. 2010

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High-speed receiver based on waveguide germanium photodetector wire-bonded to 90nm SOI CMOS amplifier

Pan¹,

Assefa²,

Green³

et al. 2012

Opt. Express

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The performance of a receiver based on a CMOS amplifier circuit designed with 90nm ground rules wire-bonded to a waveguide germanium photodetector is characterized at data rates up to 40Gbps. Both chips were fabricated through the IBM Silicon CMOS Integrated Nanophotonics process on specialty photonics-enabled SOI wafers. At the data rate of 28Gbps which is relevant to the new generation of optical interconnects, a sensitivity of -7.3dBm average optical power is demonstrated with 3.4pJ/bit power-efficiency and 0.6UI horizontal eye opening at a bit-error-rate of 10(-12). The receiver operates error-free (bit-error-rate < 10(-12)) up to 40Gbps with optimized power supply settings demonstrating an energy efficiency of 1.4pJ/bit and 4pJ/bit at data rates of 32Gbps and 40Gbps, respectively, with an average optical power of -0.8dBm.

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Daniel M. Kuchta

Exploitation of optical interconnects in future server architectures

A 71-Gb/s NRZ Modulated 850-nm VCSEL-Based Optical Link

Terabus: Terabit/Second-Class Card-Level Optical Interconnect Technologies

Monolithic Silicon Integration of Scaled Photonic Switch Fabrics, CMOS Logic, and Device Driver Circuits

160 Gb/s Bidirectional Polymer-Waveguide Board-Level Optical Interconnects Using CMOS-Based Transceivers

64Gb/s Transmission over 57m MMF using an NRZ Modulated 850nm VCSEL

Low Power and High Density Optical Interconnects for Future Supercomputers

High-speed receiver based on waveguide germanium photodetector wire-bonded to 90nm SOI CMOS amplifier

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