A spiking neural network (SNN) inspired by the structure and principles of the human brain
can significantly enhance the energy efficiency of artificial intelligence computing by …

Multifunctional tactile sensors that can mimic the sensory capabilities of human skin to
perceive various external static and dynamic stimuli are essential to interact with the …

In the biological nervous system, the integration and cooperation of parallel system of
receptors, neurons, and synapses allow efficient detection and processing of intricate and …

Mechanoreceptors endow humans with the sense of touch by translating the external stimuli
into coded spikes, inspiring the rise of artificial mechanoreceptor systems. However, to …

A self‐powered artificial mechanoreceptor module is demonstrated with a triboelectric
nanogenerator (TENG) as a pressure sensor with sustainable energy harvesting and a …

Tactile electronic skin that could interface with biological nerve systems is essential for
intelligent robotic prosthetics, human augmentation, novel human-machine interfaces …

Recent advancements in artificial tactile sensory systems have significantly improved their
ability to replicate the sensory functions of biological systems by integrating various sensory …

Prosthetic hands, today, have anthropomorphic, multifinger design. A common control
method uses pattern recognition of electromyogram signals. However, these prostheses do …

Current artificial tactile sensors mostly exploit a variety of electron‐related physical
mechanisms to obtain high sensitivity and low detection force. However, these mechanisms …

To obtain deeper insights into the tactile processing pathway from a population-level point of
view, we have modeled three stages of the tactile pathway from the periphery to the cortex in …