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Researchers' robotic face expresses the needs of yellow slime mold (video)
Apparently, slime mold has feelings too. Researchers at the University of the West of England have a bit of a history with Physarum polycephalum -- a light-shy yellow mold known for its ability to seek out the shortest route to food. Now, they're on a quest to find out why the organism's so darn smart, and the first in their series of experiments equates the yellow goo's movements to human emotions. The team measured electrical signals the mold produced when moving across micro-electrodes, converting the collected data into sounds. This audio data was weighted against a psychological model and translated into a corresponding emotion. Data collected when the mold was moving across food, for instance, correspond to joy, while anger was derived from the colony's reaction to light. Unfortunately, mold isn't the most expressive form of life, so when the team demonstrated the studies results at the Living Machines conference in London, they enlisted the help of a robotic head. Taking cues from a soundtrack based on the mold's movements, the dismembered automaton reenacts the recorded emotions with stiff smiles and frowns. Yes, it's as creepy as you might imagine, but those brave enough can watch it go through a cycle of emotions in the video after the break. [Image credit: Jerry Kirkhart / Flickr]
English scientists set out to build first biological robot using mold
Researchers at the University of the West of England have snagged a grant to fund the building of a whole new type of robot -- a non-silicon, biological plasmobot, built using plasmodium, a vegetative type of slime mold. The mold, which is commonly found living in forests and gardens, is, according to researcher Andy Adamatzky, a "naturally occurring substance with its own built in intelligence," which is capable of carrying out complex tasks, like figuring out the shortest path between two points -- all on its own. The aim for the plasmobot will be for it to sense objects, span them in the shortest way possible, and carry tiny objects along pre-determined routes, controlled by light and electromagnetic fields. The plasmobot should also be capable of complex "number crunching power," enabled by parallel inputs and outputs. Long-term uses could include using the bots within the human body to deliver drugs to specific targets. Though much of this is still purely theoretical (and extremely complicated), we look forward to the day when we're all covered in mold, don't you?
