Wind energy is central to Europe’s strategy for achieving climate neutrality, energy independence and global leadership in clean technologies. Offshore wind is expected to grow rapidly in the coming decades, with turbines reaching 20 MW capacity and wind farms expanding into large, dense arrays. These assets will be closely connected to digital, inverter-based power grids and expected to provide not only electricity but also flexibility and grid support services.
This transformation raises critical challenges. Wake effects between turbines reduce energy yield and increase fatigue loads. Current control systems are mostly rule-based, designed for individual turbines rather than entire farms, and cannot adapt dynamically to turbulence, grid requests or component degradation. Monitoring remains reactive rather than predictive, limiting the ability to move towards condition-based maintenance. Finally, data infrastructures are fragmented and proprietary, hindering the interoperability and scaling of digital twin solutions.
ICONIC (Smart, Aware, Integrated Wind Farm Control Interacting with Digital Twins) addresses these challenges by creating a new generation of wind farm technology that is intelligent, adaptive and cybersecure. The project integrates modelling, control and monitoring into a unified framework, combining physics-informed artificial intelligence, digital twins at multiple scales (farm, turbine and component) and advanced predictive control.
ICONIC’s key objectives are to:
1. Develop digital twins for flow reconstruction, load estimation and degradation prediction;
2. Advance turbine-level control through hybrid and stochastic model predictive control;
3. Optimize farm-wide performance with cooperative, AI-based control strategies;
4. Enable predictive maintenance with Remaining Useful Life (RUL) estimation;
5. Validate models and controllers through wind tunnel tests and offshore operational data;
6. Deliver an open, cybersecure software toolchain compatible with industrial SCADA systems.
Expected impacts include reducing operating costs and the levelized cost of energy (LCOE) by 5–8%, extending component lifetimes through condition-based maintenance, improving grid integration, and fostering innovation and transparency through open-source digital tools.