Cory Merkel, assistant professor of computer engineering at Rochester Institute of Technology, will represent the university as one of five collegiate partners in the new Center of Neuromorphic ...

The human brain is the ultimate supercomputer. It uses a highly branched and interconnected network of neurons and synapses ...

As artificial intelligence platforms like OpenAI's ChatGPT and Microsoft's Copilot go mainstream, power bills from their usage are exploding. In response, researchers are racing to build hardware that ...

Computing ecosystems are changing dramatically. AI, quantum computing, exascale supercomputers, biological DNA, chemical and ...

There is a growing necessity for edge training to adapt to dynamically changing environments. Neuromorphic computing represents a significant pathway for highly efficient intelligent computation in ...

Memristive synapses are very popular building blocks for neuromorphic computing. Synapses are used to construct circuits and systems such as neuroprocessors, dot product engines 1,2, ...

Acoustic synapses outperform standard, electronic AI hardware ...

Neuromorphic computing, inspired by the brain, integrates memory and processing to drastically reduce power consumption compared to traditional CPUs and GPUs, making AI at the network edge more ...

Neuromorphic computing -- a field that applies principles of neuroscience to computing systems to mimic the brain's function and structure -- needs to scale up if it is to effectively compete with ...

Neuromorphic chips mimic the brain’s architecture, offering massive energy savings and real-time processing for edge AI applications. Companies like Intel, IBM, and BrainChip are pioneering the space, ...

Neuromorphic computers, inspired by the architecture of the human brain, are proving surprisingly adept at solving complex mathematical problems that underpin scientific and engineering challenges.

Scientists have taken a major step toward mimicking nature’s tiniest gateways by creating ultra-small pores that rival the dimensions of biological ion channels—just a few atoms wide. The breakthrough ...