SEAMLESS aims at developing and adapting missing building blocks and enablers into a fully automated, economically viable, cost-effective, and resilient waterborne freight feeder loop service for Short Sea Shipping (SSS) and/or Inland Waterways Transport (IWT). Autonomous systems will be integrated to ensure safe, resilient, efficient, and environmentally friendly operation to shift road freight movements to hinterland waterways, while enhancing the performance of the TEN-T network. The service will be delivered 24/7 by a fleet of autonomous cargo shuttles, with humans-in-the-loop located in Remote Operation Centres (ROCs), which efficiently cooperate with automated and autonomous shore-side infrastructure and safely interact with conventional systems. The services will rely on a redesigned logistics system enabling seamless freight flows by minimising delays at intermodal nodes. A digital bird’s eye view of the supply chain allows the exploitation of real-time information for planning optimisation and reconfiguration to support resilient logistics, incl. digitalised administrative procedures. The SEAMLESS building blocks will be verified and validated by conducting full-scale demonstrations in selected real-world scenarios. Transferability will be fully demonstrated in selected use cases that cover a wide range of transport applications and geographical regions throughout Europe. Based on a structured methodological framework evaluating sustainability criteria, they will act as guidance for the replication of the project results beyond the project scope and timespan. Novel business models will be thus developed and provide a framework for implementing the SEAMLESS service to minimise investment risk for first movers. Regulatory gaps and challenges related to autonomous vessel operation (e.g. social aspects) will be identified, and recommendations for policy makers to allow the smooth and safe deployment of fully automated services will be provided.

Ports are essential for the European economy; 74% of goods exported or imported to the EU are transported via its seaports. At the same time, the challenges they face are only getting greater: Volumes of cargo increase while they also arrive in a shrinking number of vessels: Post-Panamax vessels have a capacity of more than 18k containers. Port operators need to comply with increasingly stricter environmental regulations and societal views for sustainability. A sustainable land-use strategy in and around the port and a strategic transition to new, service-based, management models that improve capacity and efficiency are paramount. They are key enablers for ports that want to keep pace with the ocean carriers needs and establish themselves as trans-shipment hubs with a ‘societal license to operate’; for ports whose land strategy, hinterland accessibility and operations are underpinned by circular economy principles. COREALIS proposes a strategic, innovative framework, supported by disruptive technologies, including IoT, data analytics, next generation traffic management and 5G,for modern ports to handle future capacity, traffic, efficiency and environmental challenges. It respects their limitations regarding the port land, intermodal infrastructure and terminal operation. It proposes beyond state of the art innovations to increase efficiency and optimize land-use, while being financially viable, respecting circular economy and being of service to the city. Through COREALIS, the port will minimize its environmental footprint to the city, it will decrease disturbance to local population through a reduction in the congestion around the port. It will be a pillar of business innovation, promoting local startups in disruptive technologies of mutual interest. COREALIS innovations are key both for the major deep sea European ports in view of the new mega-vessel era, but also relevant for medium sized ports with limited investment funds for infrastructure and automation.

CLARION gathers a strong multidisciplinary team of 21 partners with complementary research, technical and business profiles, including four ports with inland waterway connections, the top-3 in Europe, in terms of container throughput, namely Rotterdam, Antwerp/Brugge and Hamburg in the North Sea and Constantza, the largest European port in the Black Sea. CLARION ports handle 35.5% of the total container traffic in European ports as per EUROSTAT published 2021 data and provide access to the major inland waterways of the Rhine-Main-Danube axis, Scheldt and Elbe, ensuring significant impact of the application of results on the European maritime ports industry. 10 pilot demonstrations focused on making port infrastructure and hinterland transport resilient and sustainable. CLARION pilot demonstrations will focus on going beyond the SotA to test and deploy smart and sustainable quay walls, monitoring and management system for the corrosion of port infrastructure with an automated floating mobile measuring system, shore tension applicability for RORO and CONRO terminals during storm conditions, flood impact control DT, dredged sediment reuse in port infrastructure, NBS applicability in maritime ports, DT to support the resilience of connected inland waterways infrastructure, a DT for extreme weather forecasts, federated learning using aerial drones/satellite data/in-situ sensors for cadastral measurements and response to extreme weather, and an EMS for extreme weather events. Though each pilot demonstration will be carried out in one of the CLARION ports, achievements will be shared among them and beneficial results will be adopted in the short-term. International stakeholder communities will be engaged to create an Open Innovation Ecosystem that will promote collaboration and sharing of experiences supported by an AB consisting of experts in climate resilience in ports to ensure that transferability of CLARIONs results will not be limited among CLARION ports.

ICONET will significantly extend state of the art research and development around the PI concept in pursuit of a new networked architecture for interconnected logistics hubs that combine with IoT capabilities and aiming towards commercial exploitation of results. ICONET strives to achieve the end commercial goal of allowing shipments to be routed towards final destinations automatically, by using collaborative decisions inspired by the information centric networking paradigm, and optimizing efficiency and customer service levels across the whole network. According to this vision, cargo regarded as smart physical packets will flow between hubs based on ‘content’ of the cargo influencing key commercial imperatives such as cost, optimisation, routing, efficiency and advancing EU's Green agenda. Consequently, the consortium are discernibly aimed at three (3) avenues of commercialisation and exploitation from the ICONET innovation, specifically targeted in the areas of (a) Warehousing as a service, (b) E-commerce fulfillment as a service, and (c) Synchromodality as a service. PI based logistic configurations will be simulated, prototyped and validated in the project . Modelling and analysis techniques will be combined with serious game type simulation, physical and digital prototyping, using living lab (LL) requirements scenarios and data. With analyses and simulations, optimal topologies and distribution policies for PI will be determined. The project implementation will be based on a succession of phases of modelling and design/prototyping, learning and experimentation and feedback and interaction with the wider business community, including the ALICE logistics platform as well as members of the partner Associations ESC, UIRR and ELUPEG. Through its Living Labs, the project will address under the PI paradigm both Supply Network Collaboration and Supply Network Coordination.

AUTOSUP will drive the industrial transition to seamless multimodal automatic freight transport and enhance the operation of hubs as nodes in a Physical Internet logistics network. A multidisciplinary team of 17 partners including four organisations engaging in the activities their ecosystems of Transport and Logistics stakeholders will: • Define automation requirements for seamless multimodal automatic freight transport. • Empower stakeholders with an open, ready-to-use data-driven Decision Support System to help them implement and deploy automated processes and solutions and make strategic decisions about future investments. The systems will support undertaking feasibility studies via simulation to assess the efficiencies and impact of new solutions, whilst considering sustainability, financial and social impacts. • Support the transition path to automation in two Living Hubs (Antwerp and Trieste ports), focusing on the link of the two large transport nodes with road corridors, rail, inland waterways and airports, covering 6 diverse use cases. • Design new operational, governance and organisational change management models for autonomous logistics that incentivise cross-mode collaboration and reduce investment costs. • Validate operational and cost efficiencies of solutions via feasibility analysis, impact assessment and the engagement of representative stakeholders. • Establish a strategic and cohesive alliance and thematic working group for the alignment of multimodal automation adoption roadmaps across rail, road, aviation, waterborne and alternative innovative modes of transport and contribute to lowering automation adoption barriers through comprehensive transition guidelines, capacity-building sessions and policy recommendations. AUTOSUP integrates social innovation practices in research to foster automation adoption and enhance safety, accounting for the workforce dynamics and skills needed for the transition to autonomous operations.