Decarbonization of maritime transport through carbon-free fuel is a daunting and expensive process. New propulsion systems, such as wind-assisted, will contribute to fuel-savings. Still, whatever the pathway for a sustainable transition towards net zero emissions by 2050, more energy-efficient operations remain a prerequisite. This applies to the ship sailing as well as the port call processes. Efficient and viable voyage and port call optimization requires much increased cooperation between parties and overcoming several important barriers such as; charter parties and contracts enabling just in time arrivals and more explicit risk/benefit sharing; improved transparency and reduce cyber-security risks; reliable and efficient voyage and port call information sharing among all parties. Any new voyage optimization tool must take all these constraints into consideration and ensure full transparency on the arrival times to be agreed between the parties before the optimized route is activated. The goal of DYNAPORT is to develop new optimization and coordination tools for ports and ships that both reduce the ship's fuel consumption and increases port efficiency with at least 10%. KPIs will be developed to quantify and measure these savings. The tools will be built on information sharing through internationally accepted protocol standards and communication systems. To improve port efficiency as well as port approach safety, the system will integrate the port VTS in arrival and departure planning and execution. This goal is fully aligned with the Strategic research and innovation agenda for the partnership on Zero-Emission Waterborne Transport, underlining the lack of standardized technologies and infrastructure enabling operational integration with ports as one key barrier to faster decarbonization of maritime transport, but also with the IMO Strategy on the reduction of GHG emissions from ships, and wider initiatives by the EC, such as the European Green Deal.

PLANET addresses the challenges of assessing the impact of emerging global trade corridors on the TEN-T network and ensuring effective integration of the European to the Global Network by focusing in two key R&D pillars: • A Geo-economics approach, modelling and specifying the dynamics of new trade routes and its impacts on logistics infrastructure & operations, with specific reference to TEN-T, including peripheral regions and landlocked developing countries; • An EU-Global network enablement through disruptive concepts and technologies (IoT, Blockchain and PI, 5G, 3D printing, autonomous vehicles /automation, hyperloop) which can shape its future and address its shortcomings, aligned to the DTLF concept of a federated network of T&L platforms. PLANET goes beyond strategic transport studies, and ICT for transport research, by rigorously modelling, analysing, demonstrating & assessing their interactions and dynamics thus, providing a more realistic view of the emerging T&L environment. The project employs 3 EU-global real-world corridor Living Labs including sea and rail for intercontinental connection and provides the experimentation environment for designing and exploiting future PI-oriented Integrated Green EU-Global T&L Networks [EGTN]. To facilitate this process, PLANET delivers a Symbiotic Digital Clone for EGTNs, as an open collaborative planning tool for TEN-T Corridor participants, infrastructure planners, and industry/technology strategists. PLANET also delivers an Active Blueprint and Road Map, providing guidance and building public & private actor capacity towards the realisation of EGTNs, and facilitating the development of disadvantaged regions. The project engages major T&L stakeholders, contributing to both strategy and technology and (importantly) has the industry weight and influence to create industry momentum in Federated Logistics and TEN-T’s integration into the Global Network.