Resistive switches are a class of emerging nanoelectronics devices that exhibit a wide variety of switching characteristics closely resembling behaviors of biological synapses. Assembled into random networks, such resistive switches produce emerging behaviors far more complex than that of individual devices. This was previously demonstrated in simulations that exploit information processing within these random networks to solve tasks that require nonlinear computation as well as memory. Physical assemblies of such networks manifest complex spatial structures and basic processing capabilities often related to biologically-inspired computing. We model and simulate random resistive switch networks and analyze their computational capacities. We...
Thermodynamic-driven filament formation in redox-based resistive memory and the impact of thermal fl...
We propose and investigate a nanoscale multi-junction network architecture that can be configured on...
Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building b...
Unconventional computing explores multi-scale platforms connecting molecular-scale devices into netw...
The emergent dynamical behaviors of biological neuronal networks and other natural, complex systems ...
Neuromorphic engineering is the research field dedicated to the study and design of brain-inspired h...
Random nanowire networks (NWNs) are promising synthetic architectures for non-volatile memory device...
Emerging memcapacitive nanoscale devices have the potential to perform computations in new ways. In ...
The human brain can perform advanced computing tasks, such as learning, recognition, and cognition, ...
Brain inspired computing is a pioneering computational method gaining momentum in recent years. With...
We report a detailed study of neuromorphic switching behaviour in inherently complex percolating net...
The past decade has seen a sharp rise in the development and manufacture of different hardware frame...
As conventional memory concepts are approaching their physical scaling limits, novel memory device c...
Originally studied for their suitability to store information compactly, memristive networks are now...
As the demand for processing artificial intelligence (AI), big data, and cognitive tasks increases, ...
Thermodynamic-driven filament formation in redox-based resistive memory and the impact of thermal fl...
We propose and investigate a nanoscale multi-junction network architecture that can be configured on...
Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building b...
Unconventional computing explores multi-scale platforms connecting molecular-scale devices into netw...
The emergent dynamical behaviors of biological neuronal networks and other natural, complex systems ...
Neuromorphic engineering is the research field dedicated to the study and design of brain-inspired h...
Random nanowire networks (NWNs) are promising synthetic architectures for non-volatile memory device...
Emerging memcapacitive nanoscale devices have the potential to perform computations in new ways. In ...
The human brain can perform advanced computing tasks, such as learning, recognition, and cognition, ...
Brain inspired computing is a pioneering computational method gaining momentum in recent years. With...
We report a detailed study of neuromorphic switching behaviour in inherently complex percolating net...
The past decade has seen a sharp rise in the development and manufacture of different hardware frame...
As conventional memory concepts are approaching their physical scaling limits, novel memory device c...
Originally studied for their suitability to store information compactly, memristive networks are now...
As the demand for processing artificial intelligence (AI), big data, and cognitive tasks increases, ...
Thermodynamic-driven filament formation in redox-based resistive memory and the impact of thermal fl...
We propose and investigate a nanoscale multi-junction network architecture that can be configured on...
Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building b...