The innovative research project tackles acute questions of organisational renewal capacity and change management in the radically changing media sector. The key question is how media organisations can renew their thinking, resource bases and capabilities in order to stay competitive while addressing the challenges of digitalisation. The research is carried out by conducting qualitative and quantitative analyses based on data collected in the German media industry. The media context offers an excellent example of a dynamic business environment brought about by technological convergence, rapidly changing media usage behaviour and increasing global competition. The theoretical framework is based on modern theories of strategic management research, especially in relation to the dynamic capability view and the managerial cognition tradition. The combination of the two frameworks forms a unique multidisciplinary research approach that comprehensively helps European media organisations tackle organisational path dependencies and drivers of change. Understanding the factors that keep the media industry competitive is of great importance, because vital and diverse media is a key element of European democracy. The project is a pioneering piece of research into media management and opens many new options for projects and international collaboration as well as applications in other industries facing digital transformation. The unique interdisciplinary approach and research setting combined with a highly important topic of European interest remarkably improves the senior researcher’s competencies through applying new theories and analysis methods. The project also extends her teaching skills through opportunities at the host institution related to strategic management and the media sector than at her home university. As a result the fellowship considerably widens her career opportunities, especially as the study will spur wider interest in both academia and practice.

The EU Biodiversity Strategy (BDS) requires expanding the spatial coverage of marine protected areas to 30%, with 10% strict protection. Achieving the current 14-17% coverage has taken the Baltic Sea region 30 years, and strict protection remains almost non-existent. To meet the BDS target the countries will have to double the coverage in just 8 years. To fully capitalize on the added value of increased coverage, designation, management and measures, including restoration, need to be done in a strategic, ecologically relevant way focusing on areas and measures which enhance the existing network and optimise the possibility to secure positive biodiversity outcomes. There are however substantial challenges facing the region when it comes to leveraging the full potential of upcoming protection and restoration efforts and ultimately, positive biodiversity outcomes, especially in such a tight timeframe. To ensure that the upcoming efforts are both effective and efficient, this transboundary, network level, biogeographical region scale project will: - develop infrastructure for, and ensure long term access to, an unparalleled data driven, ecoregion scale, evidence base to support strategic planning, measures and management; - develop a blue print for, and establish, a data driven, regionally agreed protection framework to improve governance and transboundary cooperation, including politically agreed shared conservation and restoration objectives, targets etc to reach the desired state; - identify the current baseline of protection efforts across the entire sea basin. - cross-reference the desired state with the current baseline to identify gaps in protection and restoration efforts; - provide concrete and replicable support to ensure capacity for the Baltic Sea MS to strategically fill the gaps, harmonise, and achieve the full potential of the protection and restoration efforts.

Manufacturing, construction, and agriculture are major driving forces for the European economy and prosperity. Maintaining its competitiveness in these sectors demands highly efficient and flexible processes, and this can be achieved through digitization. Novel intelligent robotic capabilities that can be deployed side-by-side with humans and can operate and adapt to dynamic environments can accelerate this process. However, existing robotic systems cannot fit well into such settings as they are not versatile and flexible enough to automate certain tasks, cannot collaborate safely with humans in open and dynamic environments, nor are they easily and economically adaptable to process changes. The SOPRANO project coalesces multidisciplinary research and innovation in human-robot collaboration and intelligent multi-agent systems, aspiring to design the next generation of manufacturing floors, construction sites, and agri-food production, where humans and intelligent machines will seamlessly work together. It proposes to scale collaboration from the single human-agent dyad to a peer-based synergy between multiple interconnected robotic systems featuring different physical and cognitive properties, supporting various tasks in collaboration with human workers, robotics and other agents. SOPRANO will validate the technological offering in three novel and open-access use cases addressing both large-scale industries and small to medium enterprises, adding value to EU key sectors and instrumenting community building surrounding the open-source technologies in the EU industrial ecosystem. During the project, we will also enable external SMEs and start-ups to benefit from the project technologies via an open call, which will enable the building of demonstrators using SOPRANO technologies that will open new market opportunities for their products and services.

PALAEMON proposes the development and evaluation of a sophisticated mass centralised evacuation system, based on a radical re-thinking of Mass Evacuation Vessels (MEVs) combined with an intelligent ecosystem of critical components providing real-time access to and representation of data to establish appropriate evacuation strategies for optimizing the operational planning of the evacuation process on damaged or flooded vessels. The intelligent ecosystem of PALAEMON incorporates innovative technologies for sensing, people monitoring and counting and localisation services as well as real-time data during accident time. These will be integrated into an independent, smart situation-awareness and guidance system for sustaining an active evacuation route for large crowds, making emergency response in EU passenger ships more efficient. Continuous monitoring and permanent control will enhance the capacity to detect, prevent and mitigate any issue and potential harm arising from physical and/or man-made accidents and disasters. The proposed ecosystem will include the new IMO standard for data exchange-VDES. Since maritime disasters in recent years are a stark reminder of the imperative need for timely and effective evacuation of large passenger ships during emergency the aim of this project is to maximize the effectiveness of passenger evacuation, during an emergency and/or a serious incident, from large Cruise and RoPax ships by combining the expertise of stakeholders from the field of cruise ship manufacturing, large cruise ship operators, classification societies, sensor and technology organizations, with a multidisciplinary group of innovators (incl. innovative start-ups, consolidated SMEs in the smart ICT domain, experts in the ship evacuation domain from research institutes, international networks in maritime and key industry drivers. MEVs prototypes will be validated in controlled enviroment and the smart evacuation ecosystem will be demostrated in two use cases.