DS0710 - Sciences et technologies des composants nanoélectroniques et nanophotoniques

Magnetic Associative MEMory based on Coupled Nano-OScillators – MEMOS

Submission summary

MEMOS is an interdisciplinary project at the interface between Spintronics, Neuroscience and Microelectronics. Its goal is to implement an Associative Memory, a bio-inspired concept that operates differently from classical Random Access Memories, by exploiting the complex properties of magnetic nano-devices. Associative memories are memories with cognitive abilities, allowing information to be reconstructed from noisy or incomplete data. Because their operations are performed in parallel, they are fast and consume little energy. They are inspired by the brain, for which it is thought that associative memory operations are performed via the synchronization of neural assemblies. Indeed neurons can in some contexts be abstracted as weakly coupled nonlinear oscillators, and it has been shown theoretically that arrays of oscillators can perform associative memory operations. In that case, data storage and retrieval is obtained by modifying the coupling between oscillators. Although several implementations have been proposed, experimental demonstrations are extremely scarce. One reason is that the performance of these memories depends on the number of oscillators in the network. Spin Torque Nano-Oscillators (STNOs), which are nano-scale, non-linear, tunable oscillators that can couple and synchronize, therefore appear as extremely promising candidates as building blocks for large scale, fast, low power associative memory processors. Our main research objectives are to build a lab-scale demonstrator of an associative memory based on STNOs, and to demonstrate its potential for scaling to large networks through multi-physics and multi-scale simulations. In order to achieve its ambitious goals, the interdisciplinary MEMOS consortium, by uniting internationally recognized academic (3) and industrial (1) partners, gathers the wide spectrum of necessary expertise: bio-inspired computing approaches (UMPhy-CNRS, IEF), synchronization and coupling of STNOs (experiments: UMPhy-CNRS, CEA-Spec & theory: IEF, UMPhy-CNRS), spintronics/CMOS system co-integration and design (IEF), large scale dynamic simulations (IEF, Thales-TRT) and evaluation of benefit for applications (IEF, Thales-TRT).

Project coordination

Julie Grollier (Unité Mixte de Physique CNRS/Thales)

The author of this summary is the project coordinator, who is responsible for the content of this summary. The ANR declines any responsibility as for its contents.

Partner

CEA CEA/DSM/IRAMIS/Service de Physique de l'Etat Condensé
Thales THALES TRT
UPSud/IEF Université Paris-Sud / Institut d'Electronique Fondamentale
UMPhy CNRS Unité Mixte de Physique CNRS/Thales

Help of the ANR 769,428 euros
Beginning and duration of the scientific project: September 2014 - 48 Months

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