Description du projet
Un système robotisé pour la culture de précision des noisettes
La robotique détient le potentiel d’améliorer l’agriculture de précision en Europe. Le projet PANTHEON financé par l’UE, contribuera à élaborer un système de contrôle et d’acquisition de données pour la culture de précision de grands vergers de noisetiers (Corylus avellana L.). S’appuyant sur les progrès de la robotique, de la télédétection et de la gestion des données massives, ce projet entend créer un système complet utilisant un nombre limité de composants robotiques autonomes, à la fois terrestres et aériens. Ces robots navigueront dans les vergers, collectant et stockant des données dans une unité opérationnelle centrale. L’unité intégrera les informations provenant des différentes unités robotisées, ce qui permettra d’effectuer des actions automatisées en retour, telles que le traitement des drageons, et de fournir aux agriculteurs un système d’aide à la décision. Il suggérera, par exemple, la manière de procéder à la mise en forme et à l’élagage des plants.
Objectif
The goal of PANtHEOn is to develop the agricultural equivalent of an industrial Supervisory Control And Data Acquisition (SCADA) system to be used for the precision farming of large orchards of hazelnut (Corylus avellana L.). By taking advantage of the technological advancements in the fields of robotics, remote sensing and big-data management, our objective is to design an integrated system where a relatively limited number of heterogeneous unmanned robotics components (including terrestrial and aerial robots) move within the orchards to collect data and perform some of the most common farming operations. The information will be stored in a central operative unit that will integrate the data coming from the different robotic units to perform automatic feedback actions (e.g. to regulate the irrigation system) and to support the decisions of agronomists and farmers.
We expect that the proposed SCADA system will be able to acquire information at the resolution of the single plant. This will permit to drastically increase the detection of possible limiting factors for each individual plant, such as lack of water or pests and diseases affecting the plant health, and to react accordingly. Compared to the current state of the art in precision farming, we believe that the proposed SCADA infrastructure represents a relevant step ahead in the context of orchards management. In fact, the capability of monitoring the state and the evolution of each single tree will be the enabling-technology to allow more focused interventions. This will result in a better average state of health of the orchard, and in an increased effectiveness of Integrated Pest Managements (IPM). In conclusion, the main advantages of this architecture are:
• Increase in hazelnut productions
• Decrease in chemical inputs usage
• Environmentally-friendly water usage
• Simplified orchard management
The outcome of the project will be validated through a final demo on a real-world (1:1 scale) hazelnut orchard.
Champ scientifique
- engineering and technologymechanical engineeringvehicle engineeringautomotive engineeringautonomous vehicles
- engineering and technologycivil engineeringwater engineeringirrigation
- engineering and technologyenvironmental engineeringremote sensing
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectronic engineeringroboticsautonomous robots
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectronic engineeringsensors
Programme(s)
Régime de financement
RIA - Research and Innovation actionCoordinateur
00154 Roma
Italie