Andrew Adamatzky1, Antoni Gandia2, Alessandro Chiolerio3,4. 1. Unconventional Computing Laboratory, UWE, Bristol, UK. andrew.adamatzky@uwe.ac.uk. 2. Mogu S.r.l., Inarzo, Italy. 3. Unconventional Computing Laboratory, UWE, Bristol, UK. 4. Center for Sustainable Future Technologies, Istituto Italiano di Tecnologia, Torino, Italy.
Abstract
BACKGROUND: A fungal skin is a thin flexible sheet of a living homogeneous mycelium made by a filamentous fungus. The skin could be used in future living architectures of adaptive buildings and as a sensing living skin for soft self-growing/adaptive robots. RESULTS: In experimental laboratory studies we demonstrate that the fungal skin is capable for recognising mechanical and optical stimulation. The skin reacts differently to loading of a weight, removal of the weight, and switching illumination on and off. CONCLUSION: These are the first experimental evidences that fungal materials can be used not only as mechanical 'skeletons' in architecture and robotics but also as intelligent skins capable for recognition of external stimuli and sensorial fusion.
BACKGROUND: A fungal skin is a thin flexible sheet of a living homogeneous mycelium made by a filamentous fungus. The skin could be used in future living architectures of adaptive buildings and as a sensing living skin for soft self-growing/adaptive robots. RESULTS: In experimental laboratory studies we demonstrate that the fungal skin is capable for recognising mechanical and optical stimulation. The skin reacts differently to loading of a weight, removal of the weight, and switching illumination on and off. CONCLUSION: These are the first experimental evidences that fungal materials can be used not only as mechanical 'skeletons' in architecture and robotics but also as intelligent skins capable for recognition of external stimuli and sensorial fusion.