At first, the line looks like a jumble. It makes turns in all directions and goes around and around, apparently randomly. Then – all of a sudden, an almost straight line leads right back to the starting point.
The path describes a bee on an excursion for nectar. When it has accumulated its wanted amounts, it flies, without hesitation, straight home. Literally.
"Inside the bee’s brain, there are functions that help with this. The bee, unlike us humans, knows at every moment exactly how far from home it is, and in which direction the nest is located", says David Winge", post doc researcher at Lund University.
In a collaboration between the Department of Physics and the Department of Biology at Lund University, and the School of Informatics at the University of Edinburgh, the research group has focused on calculating how to use light signals in a circuit of nanowires to build a similar function.
"You could say that we have been using the biologists’ results as a design to construct a very simple and energy-efficient way of navigating, by imitating the insect brain’s function for that area", says David Winge.
"There are many possible uses for this type of technology. Small drones, robot vacuum cleaners or other things that need to navigate with a very limited energy supply".
The components, which in the research group’s numerical calculations consist of nanowires, are able to receive two different signals, compare them and send out a new signal. Optical signals – light – are a non-expensive, fast, and energy-efficient way to communicate. Since nanowires can absorb a lot of light in relation to their size, they are very efficient to work with.
"This is a pilot study, and in the long run we hope to get funding for constructing it in the lab", says David Winge.
"Our component sketches have not, in full, been produced in the lab yet. The time span is at least 10 years. The big challenge is to get the parts, which the nanocomponents consist of, into functioning units", concludes David Winge.
Publication in ACS Publications: Implementing an Insect Brain Computational Circuit Using III–V Nanowire Components in a Single Shared Waveguide Optical Network