PLANTS adhered to a broader vision where the virtual (computing) space was seamlessly integrated with the physical environment. One of its main objectives was to develop the necessary software modules, tools and methodologies that enable the efficient and flexible integration of 'augmented' plants and artefacts into ubiquitous computing applications which may range from domestic plant care to precision agriculture.
"The main idea behind PLANTS is to develop a system that produces the optimal growing conditions for a crop, so that crops are kept in the best possible health with the minimum of inputs," says Dr Fiona Tooke of the Eden Project, one of the project partners. "It promotes sustainability, because there isn't excessive use of inputs like fertilizer and water. It makes crop management more economic too, as well as less damaging to the environment."
"The system picks up on the plants' signals that indicate when plants need help, such as more water, more nutrients or more or less light. Essentially, the plants are controlling the system," she continues.
The system uses an infrared camera to scan the entire crop canopy. It can automatically detect when individual or groups of plants are getting too hot. Another sensor detects chlorophyll fluorescence, which tells the system the rate at which the plant is absorbing energy. That reflects the current state of photosynthesis, itself a reflection of the plant's health.
These sensors communicate their data through specially developed wireless transmitters. Scientists at lead project partner the Tyndall National Institute managed to reduce the essential technology from 100mm Field Programmable Gate Arrays (FPGA), to a specialised 25mm module.
This system incorporates a wireless transceiver capability with embedded protocol software to minimise power consumption and maximise data throughput. What's more, these chips work wirelessly and contain their own batteries. They can communicate over large distances for their size, with a current range of about 10m, but again the Tyndall team hope to push their range further. "Finally, they are also looking at the potential of 'Power Harvesting' for the chip, where it would supply its own energy needs through solar energy or ground vibrations, making the chip completely independent,'' says Tooke.
She believes these could have many applications outside of the PLANTS project. "We were speculating, for example, that they might have an application in hostile environments, like growing plants in space or soil-less systems. Potentially, these are situations where our system could prove very useful."
The sensors and transmitters are two key elements of the system, but its heart is the management software, designed by Computer Technology Institute, Greece, that gathers, and then acts, on the data operating as a plant/environmental context management system. Called ePlantOS, it can control the deployment of water, nutrients or pesticides, as necessary.
One of PLANTS' demonstrator went live at the Eden Project end March 2006 and was the centre point of a special workshop to introduce the technology to experts in the fields of plant science, crop management, microelectronics and software engineering. A temporary exhibit will now show PLANTS results from mid-April to end June 2006 at the Eden Project.
Three partners lodged a patent for the technology developed during the PLANTS project. "They certainly hope to carry the work further, by initially developing a prototype, and then possibly commercialising the system," says Tooke. "That work will go beyond the life of this project, however. PLANTS ended in March 2006."
However, none of those system improvements will make the plants totally stress free, but if the project's crop management system takes off, at least their complaints will be heard and listened to.
Dr Anthony Morrissey
Biomedical Microsystems Team
Tyndall National Institute
Source: Based on information from PLANTS