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NEUROmorphic energy-efficient secure accelerators based on Phase change materials aUgmented siLicon photonicSbroad

NEUROPULS · Horizon Europe grant · 2023-01-01–2027-12-31

EC contribution

€8,319,510

Total cost

€8,319,510

Beneficiaries

15
About the data

Source: CORDIS (official EU open data), Horizon Europe. Framework HORIZON · call HORIZON-CL4-2021-DIGITAL-EMERGING-01 · scheme HORIZON-RIA · topic HORIZON-CL4-2021-DIGITAL-EMERGING-01-01. CORDIS record →

Objective

The growing need to transfer massive amounts of data among multitudes of interconnected devices for e.g., self-driving vehicles, IoT or industry 4.0 has led to a quest towards low-power and secure approaches to locally processing data. Neuromorphic computing, a brain-inspired approach, addresses this need by radically changing the processing of information. Although neuromorphic electrical computing systems offer advantages in terms of CMOS implementations and scalability, they inherit limitations of conventional electronics such as low energy-efficiency, high latency and low bandwidth density. Besides, such systems often require robust security layers for e.g., safety-critical applications. Security layers based on memory-stored secret keys are prone to several types of memory-accessing attacks. Therefore, silicon hardware approaches for security primitives such as physical unclonable functions (PUFs) are currently investigated because of their absence of long-term digital memory storage. Although electronic PUFs have received major attention thanks to their native CMOS implementation, for secure authentication they are prone to machine learning and side-channel attacks due to their CMOS technology.The NEUROPULS project aims to build next-generation low-power and secure edge-computing systems by developing novel photonic computing architectures and security layers based on photonic PUFs in augmented silicon photonics CMOS-compatible platforms. The integration of emerging non-volatile phase change materials for synapses/neurons and III-V materials for on-chip spiking sources, for the first time, will allow to build novel neuromorphic accelerators featuring RISC-V compliant interfaces for smooth adoption and programmability. Optimal performance will be achieved thanks to a novel full-system simulation platform for design space exploration. Three relevant use-cases will be considered for benchmarking to demonstrate 2 orders of magnitude energy efficiency improvement.

Beneficiaries (15)

OrganisationCountryRoleEC contributionSME
CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE CNRS FR coordinator €1,682,561
COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES FR participant €1,166,324
POLITECNICO DI TORINO IT participant €885,000
UNIVERSITEIT GENT BE participant €657,000
INESC ID INSTITUTO DE ENGENHARIADE SISTEMAS E COMPUTADORES INVESTIGACAO E DESENVOLVIMENTO EM LISBOA PT participant €616,250
ETHNIKO KAI KAPODISTRIAKO PANEPISTIMIO ATHINON EL participant €593,750
BARCELONA SUPERCOMPUTING CENTER CENTRO NACIONAL DE SUPERCOMPUTACION ES participant €555,625
UNIVERSITA DEGLI STUDI DI VERONA IT participant €510,000
TECHNISCHE UNIVERSITAT BERLIN DE participant €468,814
HEWLETT PACKARD ENTERPRISE BELGIUM BE participant €448,750
ARGOTECH AS CZ participant €436,250 Yes
ALBORA TECHNOLOGIES SL ES participant €291,250 Yes
LUDWIG-MAXIMILIANS-UNIVERSITAET MUENCHEN DE participant €7,936
ECOLE CENTRALE DE LYON FR thirdParty €0
UNIVERSITE BOURGOGNE EUROPE FR thirdParty €0

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