This report describes the methodology used to define the “validation scenarios”, accounting for the different potential use cases. Given the large number of permutations of tools, use cases, and the set of minimum validation requirements, the number of validation scenarios has been reduced to a number that can be run during the life of the DTOceanPlus project but that are sufficient to fully demonstrate the functionality of the DTOceanPlus suite of tools. The selection process, based on a successive approximation approach, has led to the cases that the potential users in the DTOceanPlus consortium have considered as the most relevant for the sector. In Section 4 of the document, the selected validation scenarios is described; the definition of these scenarios has been completed during the project to ensure that the most updated information is used.

This report is the outcome of a task dedicated to specific sector standards for business management models for the ocean energy sector. The aim of this task was to define alternative business models for the sector by developing a greater understanding of these models and recommending development routes to industrial roll-out to improving the market opportunity.

Deliverable D5.2 “Site Characterisation – alpha version” of the DTOceanPlus project include the details of the Deployment Tool module: “Site Characterisation” (SC), and it represents the result of the work developed during the task 5.3 of the project. This document summarises both the functionalities as well as the more technical aspects of the code implemented for this module.

The aim of this document is to present the activity carried out by the four industrial partners who validated the DTOcean+ suite against five wave energy validation scenarios.

This document summarizes both the module functionalities and the more technical aspects of the code implemented in the station keeping module.

A coherent set of requirements have been developed for the DTOceanPlus suite of design tools based on analysis of gaps between the current state-of-the-art tools, learning from the DTOcean project, and the stakeholder expectations identified in the user consultation exercise. The requirements in this document are split into general requirements for the overall suite of tools, and specific requirements (functional, operational, user, interfacing, and data) for each of the design tools that is developed as part of this, which are split by work package and task. They act as user specifications for the tool development work packages, and focus the development effort to best meet the needs of the ocean energy industry. Subsequent tasks of the DTOceanPlus project develop these requirements into more detailed technical requirements and software specifications, prior to software coding and integration, then testing and validation.

This document summarises both the functionalities as well as the more technical aspects of the code implemented for this module. This module will provide the user with four assessments: identification of the potential presence of endangered species in the area; environmental impacts estimated using relevant metrics such as the underwater noise or the collision risk between vessels/devices and the marine wildlife; estimation of the carbon footprint of the project in terms of two mid-point indicators; information to improve the social acceptance of the project considering cost of consenting and jobs creation.

This document serves as the technical manual of the alpha version of the energy delivery module, including all the data requirements, main functions, interfaces and all pertinent technical details.

This report collates the materials used throughout the DTOceanPlus project on knowledge exchange and training.

The Structured Innovation (SI) design tool comprises innovation methodologies that can enhance concept creation and selection in ocean energy systems, enabling a structured approach to address complex ocean energy engineering challenges where design options are numerous. Thus, it can facilitate efficient evolution from concept to commercialisation. The tool is one of a kind beyond the current state-of-the-art, that will enable the transfer and adaptation of the QFD/TRIZ and FMEA methodologies to the ocean energy sector.