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Physics for neuromorphic computing

Danijela Marković, Alice Mizrahi, Damien Querlioz, Julie Grollier

2020Nature Reviews Physics19 citationsDOIOpen Access PDF

Abstract

Neuromorphic computing takes inspiration from the brain to create energy-efficient hardware for information processing, capable of highly sophisticated tasks. Systems built with standard electronics achieve gains in speed and energy by mimicking the distributed topology of the brain. Scaling-up such systems and improving their energy usage, speed and performance by several orders of magnitude requires a revolution in hardware. We discuss how including more physics in the algorithms and nanoscale materials used for data processing could have a major impact in the field of neuromorphic computing. We review striking results that leverage physics to enhance the computing capabilities of artificial neural networks, using resistive switching materials, photonics, spintronics and other technologies. We discuss the paths that could lead these approaches to maturity, towards low-power, miniaturized chips that could infer and learn in real time. Neuromorphic computing takes inspiration from the brain to create energy-efficient hardware for information processing, capable of highly sophisticated tasks. Including more physics in the algorithms and nanoscale materials used for computing could have a major impact in this field.

Topics & Concepts

Neuromorphic engineeringKey (lock)Computer scienceElectronicsArtificial intelligenceHuman–computer interactionEnergy (signal processing)Data scienceComputer architectureArtificial neural networkElectrical engineeringEngineeringPhysicsQuantum mechanicsComputer securityAdvanced Memory and Neural ComputingNeural Networks and Reservoir ComputingFerroelectric and Negative Capacitance Devices
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