More brainpower for hardware and software

(Nanowerk News) Lean back and admire the scenery while the car drives itself through the city - this is not yet possible, despite technical advancements. Conventional computer hardware and software do not have sufficient interfaces to intervene in an emergency with the same responsiveness as a human.
But neuromorphic materials might make this possible, agree Dr. Susanne Baumann from the Institute for Functional Matter and Quantum Technology, and her colleagues Dr. Hermann Osterhage and Dr. Eduardo Domínguez Vázquez from Radboud University in the Netherlands.
"In terms of how they work, algorithms are modeled on the human brain. However, conventional hardware is not yet able to implement the full potential of these algorithms," explains Baumann. "We need hardware technologies that are more like the brain. Neuromorphic materials could be the key to this."
Scanning tunneling microscopy image of a surface with individual atoms
Scanning tunneling microscopy image of a surface with individual atoms: researchers are using such atoms to develop neuromorphic materials. (Image size: 5 x 7 nanometers). (Image: Institute for Functional Matter and Quantum Technology)

Brain power transferred to hardware

The idea is to match hardware and software more precisely. In practice, this would mean fewer processing loops and more efficient and faster response performance.
To this end, the team is exploring the potential of neuromorphic materials. These are atomic-based materials that resemble the neuronal structure of the brain. With the help of scanning tunneling microscopy, Baumann and her team are able to assemble such materials atom by atom according to the puzzle principle and give them the desired properties.
"The material must be capable of adapting to suit changing requirements," says Baumann. As a result, algorithms learn to generate the desired output more efficiently and more quickly from an initially unknown input. "Just as neural pathways in the brain form and strengthen with repetitive execution of a movement, neuromorphic hardware is designed to support algorithm learning."
Source: University of Stuttgart (Note: Content may be edited for style and length)
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