The AMIE project opens a vast new research agenda for mobile Augmented Reality (AR) by making it interactive: Instead of only focusing on superimposing graphics on the real world, we aim at making the real world interactive by defining contextual reusable widgets attached to real objects and places. We introduce the term AR widget as a central concept of the AMIE project. The goal is to define reusable software building blocks for interactive AR. We base our approach on widgets (by analogy with Graphical User Interface) as elementary objects that take part in AR interaction. Instead of superimposing graphics on the real world, we aim at augmenting the physical world with widgets. Such widgets will be linked to the real world and will be manipulated by the users. As for Graphical User Interface (GUI) (e.g., the contextual menu attached to a selected graphical object), we will define AR contextual widget attached to a physical object. Moreover some AR widgets will be specifically designed for synchronous or asynchronous collaborative aspects (e.g., a telepointer for a distant expert). To do so the project is multidisciplinary including two complementary academic teams, one team dedicated to Sensor-Data fusion techniques for Localization/Registration and one team to Human-Computer Interaction (HCI). As a starting point towards the definition of a toolkit for mobile collaborative AR, we adopt an iterative user-centred design approach in order to design and develop usable interactive and collaborative techniques. To do so we consider maintenance/machine operators in production plants, a domain represented by two industrial partners, DIGITAL Electronics and SCHNEIDER. AMIE therefore focuses on mobile and collaborative AR systems for operators in a production plant in which augmentation occurs through available knowledge of where the operator is and what the other users (operators, experts) are doing. From the first set of interactive techniques designed, developed and experimentally tested in the context of maintenance services in production plants, we will generalize the techniques in order to define AR widgets (e.g., a menu, a panel, a telepointer) as part of reusable building blocks of a toolkit.

In semiconductor-based quantum information devices, the main focus is recently put on manipulation of discrete quantum states confined in artificial atoms. However, such localized qubits require vast infrastructure, because one needs hardware for all billions of qubits. In this project, we manipulate delocalized qubits based on electron waves in semiconductor nanostructures. In order to achieve high fidelity and high quality factor, we develop new designs of electron wave interferometers combined with quasi-particle excitations that have macroscopic coherence length. Since quasi-particle qubits are created on-demand from the Fermi sea of the electron source, the number of qubits is also set on-demand. The hardware size can thus be significantly reduced. We also control interaction between localized and delocalized quantum systems to construct hybrid systems. The concepts and technologies developed for delocalized qubits will bring a paradigm shift in quantum architectures.

The Oracle will develop scalable alternative reaction technologies for decentralised production of ammonia as a renewable fuel from N2 and H2O. Three strands for ammonia synthesis will be developed and validated at TRL3: electro-catalytic, plasma-aided electrocatalytic as well as electrified thermal catalysis process that will serve as a benchmark. The ORACLE proposes to test overlooked electrocatalysts for electrochemical synthesis of NH3 from N2 and H2O. To increase the selectivity ORACLE proposes to develop plasma-aided electrochemical cells and test exciting new concepts of NOx and H2 recombination to NH3 in an electrochemical cell. Here NOx and H2 are sourced from plasma-assisted electrolysis of N2 and H2O. The ORACLE system processes will integrate catalysts and reactor technology to create adaptable user-centered system for localized on-site ammonia production. The processes have the potential to decisively transform existing large-scale ammonia based production towards a non-fossil-based economy. At the core of ORACLES’s systems are tuned (electro)catalyst design and their 3D controlled deposition for, on the one hand magnetic nanoparticle-bearing catalyst compositions for the thermocatalytic process and, on the other hand, NRR reduction, OER and HOR catalysts for the (plasma-assisted) electro-catalytic process. The electrified thermal catalysis will use local heat delivery through magnetic particles-mediated AC-fields to push the catalytic process beyond the reactor heat transfer limits. The ORACLE project partners have accumulated a wealth of experience in e-fuels within a number of projects. In addition, the ORACLE project will benefit from the European longstanding collaboration with two Japanese research centres, AIST and ORIST. To reach this ambitious goal, ORACLE will draw on the complimentary expertise of its industrial ammonia producer CASALE and innovative catalyst manufacturer C2CAT, who cover two opposite ends of commercially-driven value chain.