Summary
COGITOR represents a novel approach to cybernetics, proposing the study of Colloidal (liquid) Cybernetic Systems (CCS), a multifunctional liquid-based platform that we have designed to be capable of pressure sensing (i), computing and data storage (ii), energy harvesting (iii) and integrating fully custom electronics (iv). A CCS provides operation in extreme environments by definition, having distributed architecture (homogeneous liquid plus random network architecture), being fault-tolerant and featuring self-healing capabilities. Within COGITOR in 54 months the consortium will provide a platform where liquid electronics efforts can converge from all over the world, making European research the point of reference for this big step forward. COGITOR measurable and specific objectives are: i) creating an impedance liquid state pressure sensor with spatial and temporal resolution; ii) producing an holonomic reversible memory written/erased electrically and read by tomographic Microwave Impedance Spectroscopy; the electrical operation will be used to implement learning (both sequential and concurrent) and calculation, where the system acts as a many-input Boolean circuit; iii) harvesting energy from a thermal gradient artificially induced by IR radiation upon the prototype; iv) integration and testing of the final CCS prototype, testing self-healing and fault tolerance capabilities, as well as assessing interference, also under EE conditions varying T, p and B. The engineering applications that we plan to exploit will be part of the intellectual property of a spin-off company. The consortium is well-balanced with cutting edge Research Organizations across EU (IIT – Italy, UWE – UK, EMPA - Suisse) and companies (PC – Germany, PNO – Spain) that will closely collaborate to develop and really transfer knowledge and innovations into products and related services.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/964388 |
| Start date: | 01-06-2021 |
| End date: | 30-11-2025 |
| Total budget - Public funding: | 3 342 140,00 Euro - 3 342 140,00 Euro |
Cordis data
Original description
COGITOR represents a novel approach to cybernetics, proposing the study of Colloidal (liquid) Cybernetic Systems (CCS), a multifunctional liquid-based platform that we have designed to be capable of pressure sensing (i), computing and data storage (ii), energy harvesting (iii) and integrating fully custom electronics (iv). A CCS provides operation in extreme environments by definition, having distributed architecture (homogeneous liquid plus random network architecture), being fault-tolerant and featuring self-healing capabilities. Within COGITOR in 54 months the consortium will provide a platform where liquid electronics efforts can converge from all over the world, making European research the point of reference for this big step forward. COGITOR measurable and specific objectives are: i) creating an impedance liquid state pressure sensor with spatial and temporal resolution; ii) producing an holonomic reversible memory written/erased electrically and read by tomographic Microwave Impedance Spectroscopy; the electrical operation will be used to implement learning (both sequential and concurrent) and calculation, where the system acts as a many-input Boolean circuit; iii) harvesting energy from a thermal gradient artificially induced by IR radiation upon the prototype; iv) integration and testing of the final CCS prototype, testing self-healing and fault tolerance capabilities, as well as assessing interference, also under EE conditions varying T, p and B. The engineering applications that we plan to exploit will be part of the intellectual property of a spin-off company. The consortium is well-balanced with cutting edge Research Organizations across EU (IIT – Italy, UWE – UK, EMPA - Suisse) and companies (PC – Germany, PNO – Spain) that will closely collaborate to develop and really transfer knowledge and innovations into products and related services.Status
SIGNEDCall topic
FETOPEN-01-2018-2019-2020Update Date
27-04-2024
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