The wine industry is strategically for Europe, both economically and socially speaking. Its competitive position in the global market depends on the long-term reputation of its wines, which needs many years to be built but can be lost quickly with a poor wine. The risk of losing reputation is high when repeatability cannot be granted, which happens ever more in the vineyards where manual data sampling is meager due to unaffordable costs. Therefore, our aim is to industrialize, demonstrate, and take as first ones to market an innovative expert field monitoring system (decision support system) embedded in a small-size and cost-efficient robot for the vineyard, which will be the follow-up of the successful EU-funded project VineRobot (TRL6/7). In order to ensure commercial success, we will optimize both the external design and the internal electronics, as well as industrialize the navigation and mapping software for top performance, protection, and user friendliness. For this we count on an industry-driven consortium, targeting one of the largest agricultural sectors in Europe, with a strong business plan and the support of a large number of committed industry leaders and end-users, ensuring a rapid market deployment. Market penetration will be boosted by the SMEs already active in the robotics and viticulture sectors, reinforced by strategic tradeshows and international conferences. As a result, we target a cumulative turnover of €33 Million in five years yielding €10.9 Million of industrial benefits, reaching a market adoption of 5% which will provide service to 54,540 ha of EU vineyard area. In addition, VineScout technology will attract young farmers to rural areas, which is becoming crucial for the sustainability of the sector since current farming population is near retirement age. The practical adoption of robotics in agriculture will create employment, in part with the advent of new industries related to ICT, precision management, and data interpretation.

Tulipp will develop a reference platform that defines implementation rules and interfaces to tackle power consumption issues while delivering high, efficient and guaranteed computing performance for image processing applications. Using this reference platform will enable designers to develop an elementary board at a reduced cost to meet typical embedded systems requirements: Size, Weight and Power (SWaP) requirements. Moreover, for less constrained systems which performance requirements cannot be fulfilled by one instance of the platform, the reference platform will also be scalable so that the resulting boards be chained for higher processing power. To demonstrate its effectiveness, an instance of the reference platform will be developed during the project. The instance of the reference platform will be use-case driven and split between the implementation of: a reference HW architecture - a scalable low-power board; a low-power operating system and image processing libraries; an energy aware tool chain. It will lead to three proof-of-concept demonstrators across different application domains: real-time and low-power medical image processing product prototype of surgical X-ray system (Mobile c-arm); embedded image processing systems within Unmanned Aerial Vehicles (UAV); automotive real time embedded systems for driver assistance. The Tulipp approach will also give rise to advances in system integration, processing innovation and idle power management. Tulipp will closely work with standardisation organisations to propose new standards derived from its reference platform to the industry. Its consortium includes the necessary and sufficient number of partners covering all the required inter-disciplinary expertise to successfully carry out the required experimentation, integration and demonstration activities as well as to assure a manageable project structure and minimise the risks to achieve the ambitious goals of the project.