Abstract

Conventional computing systems are limited in performance by the well-known von Neumann bottleneck, arising from the physical separation of processor and memory units. The use of electrical signals in such systems also limits computing speeds and introduces significant energy losses. There is thus a pressing need for unconventional computing approaches, ones that can exploit the high bandwidths/speeds and low losses intrinsic to photonics. A promising platform for such a purpose is that offered by integrated phase-change photonics. Here, chalcogenide phase-change materials are incorporated into standard integrated photonics devices to deliver wide-ranging computational functionality, including non-volatile memory and fast, low-energy arithmetic and neuromorphic processing. We report the development of a compact behavioral model for integrated phase-change photonic devices, one which is fast enough to allow system level simulations to be run in a reasonable timescale with basic computing resources, while also being accurate enough to capture the key operating characteristics of real devices. Moreover, our model is readily incorporated with commercially available simulation software for photonic integrated circuits, thereby enabling the design, simulation and optimization of large-scale phase-change photonics systems. We demonstrate such capabilities by exploring the optimization and simulation of the operating characteristics of two important phase-change photonic systems recently reported, namely a spiking neural network system and a matrix-vector photonic crossbar array (photonic tensor core). Results show that use of our behavioral model can significantly facilitate the design and optimization at the system level, as well as expediting exploration of the capabilities of novel phase-change computing architectures.

Highlights

  • THE von Neumann architecture is one of the pillars underpinning the progress of computing technologies over many decades. This architecture is based on a central processing unit (CPU) which carries out the computations and a separated memory that stores data and instructions

  • We aim here to reduce simulation times for the programming of single integrated phasechange photonic devices from the several to many hours typically required by fully physical modeling to the seconds to tens of seconds timescale required to enable, the simulation of photonic integrated circuits (PICs) containing hundreds or thousands of such devices

  • In the work described above we have concentrated on what is often called the basic unit cell comprising here a straight rib type waveguide fabricated in SiN, suitable libraries can be readily developed for other device types, different device geometries/configurations, and different phase-change materials (e.g. GeSbTe, GeSbSeTe, GeTe, AgInSbTe, SbS etc.)

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Summary

INTRODUCTION

THE von Neumann architecture is one of the pillars underpinning the progress of computing technologies over many decades. We aim here to reduce simulation times for the programming (write/erase) of single integrated phasechange photonic devices from the several to many hours typically required by fully physical modeling (e.g. finiteelement simulations of optical and thermal characteristics combined with nucleation and growth type phase-change models) to the seconds to tens of seconds timescale required to enable, the simulation of photonic integrated circuits (PICs) containing hundreds or thousands of such devices. It is just such a compact model that we develop in this paper. We do not explore integration/interfacing aspects of the active components (lasers, photodetectors etc.) required for realization of functionally-complete integrated photonic systems, and the reader is referred to many excellent reviews (e.g. [11] – [13]) for such information

COMPACT BEHAVIORAL MODEL
Readout model
Experimental data fitting
COMBINATION WITH INTEGRATED PHOTONICS DESIGN FRAMEWORK
Synapse and collector simulation
Pattern detection
COMBINATION WITH INTEGRATED PHOTONIC DESIGN FRAMEWORK
CONCLUSION

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