Project description
Wireless sensors for healthy plants
Wireless wearable devices can track our every move and monitor our health. This technology can also be used on plants for the benefit of urban policies, the agri-food industry and forestry. The EU-funded WATCHPLANT project will develop a wireless, wearable, self-powered sensor for in-situ monitoring of urban environments. Specifically, this system equips plants with artificial intelligence to create a smart net of sensors for measuring environmental parameters and the responding physiological state of plants at a very early stage, using a barely-explored fluid, phloem sap. The project will explore how to extract sufficient sap volume in a healthy plant and how to make long-lasting bioelectronics to use sap for sensing and energy harvesting purposes.
Objective
WatchPlant will develop a new biohybrid system technology, a wireless wearable self-powered sensor for in-situ monitoring of urban environments. This system equips urban biological organisms -plants- with Artificial Intelligence (AI) to create a smart sensor for measuring both, environmental parameters and the responding physiological state of plants, in a very early stage by the use of a barely explored fluid, phloem sap, in combination with chemical, and physical sensors. It will be integrated into complex network that allows performing distributed information processing, decision making, modeling and data fitting, paving the way for the self-awareness or self-adaptation. Additionally, it will constitute a clean energy self-powered device due to the novel use of sap, not only for transforming plants into living sensors, but also for clean energy generation.
A consortium of EU research, technology centers and ambitious high-tech SMEs will stretch and combine the limits of plant physiology and bioelectronics with microtechnology, multiphysics modelling, sensor engineering, AI and environmental modelling, to transform plant into living autonomous and self-powered sensors. The project has the ambition to solve how to extract sufficient sap volume in a healthy plant, how to make long-lasting bioelectronics, and how create a smart self-powered wearable phytosensor in a single device. It also has the challenge of modelling urban environments using novel combinations of exiting parameters and explores the future role of sap in this sense. Thus, it is a promising tool to carry out weather/pollution/pandemics development forecasting systems up to social networks for proving an ecological/environmental feedback to citizens. Thus it will be possible to perform specific actions and apply efficient use of resources and correct policies, which can have a great impact not only in urban monitoring but a huge range of plant-related sectors such as agro-food industry or forestry.
Fields of science
- engineering and technologyenvironmental engineeringenergy and fuelsrenewable energy
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectronic engineeringsensorssmart sensors
- natural sciencescomputer and information sciencescomputational sciencemultiphysics
- engineering and technologyother engineering and technologiesmicrotechnology
- natural sciencescomputer and information sciencesdata sciencedata processing
Keywords
Programme(s)
Funding Scheme
RIA - Research and Innovation actionCoordinator
46022 Paterna
Spain