Litcius/Paper detail

Magnon scattering modulated by omnidirectional hopfion motion in antiferromagnets for meta-learning

Zhizhong Zhang, Kelian Lin, Yue Zhang, Arnaud Bournel, Ke Xia, Mathias Kläui, Weisheng Zhao

2023Science Advances37 citationsDOIOpen Access PDF

Abstract

Neuromorphic computing is expected to achieve human-brain performance by reproducing the structure of biological neural systems. However, previous neuromorphic designs based on synapse devices are all unsatisfying for their hardwired network structure and limited connection density, far from their biological counterpart, which has high connection density and the ability of meta-learning. Here, we propose a neural network based on magnon scattering modulated by an omnidirectional mobile hopfion in antiferromagnets. The states of neurons are encoded in the frequency distribution of magnons, and the connections between them are related to the frequency dependence of magnon scattering. Last, by controlling the hopfion's state, we can modulate hyperparameters in our network and realize the first meta-learning device that is verified to be well functioning. It not only breaks the connection density bottleneck but also provides a guideline for future designs of neuromorphic devices.

Topics & Concepts

Neuromorphic engineeringMagnonBottleneckComputer scienceScatteringArtificial neural networkPhysicsBootstrapping (finance)Artificial intelligenceOpticsMathematicsQuantum mechanicsEmbedded systemFerromagnetismEconometricsNeural Networks and Reservoir ComputingAdvanced Memory and Neural ComputingNeural Networks and Applications
Magnon scattering modulated by omnidirectional hopfion motion in antiferromagnets for meta-learning | Litcius