Concept and Project. Objective(s) This training network is formed by major European institutions in the field of radiation detectors in which European science has a leading role worldwide. The network will contribute to reinforce this role through challenging common projects. The results of the proposed projects will find their applications in the next generation of particle physics experiments like at the SLHC, the Super-B factory, ILC and FAIR, as well as in astro-particle physics, medicine, photon science and a number of other scientific and industrial applications. The main scientific achievement of this training network will be an overall and clearly visible gain in the performance of particle detectors for SLHC, ILC and other future particle physics experiments. The R&D conducted in the network is expected to lead to the following main results: • Silicon tracking devices: Availability of specifically engineered materials and optimized xx- xxxxxx layouts which withstand the unprecedented radiation loads expected in SLHC or FAIR. • Novel tracking detectors: Understanding the intrinsic limitations. New performance records for novel particle detectors like MAPS, 3D semiconductor detectors, GEMs or Micromegas; • Photon detectors: Development for fast single photon detection devices, able to cover large areas and/or operate in high magnetic fields. • Construction and complete characterization of fully functional prototypes of particle detector subsystems for considered applications in HEP experiments (calorimetry, particle ID). To fully exploit future accelerator facilities like SLHC, FAIR and ILC, which may come into operation in the years 2012 to 2020, a new generation of detector scientists is required. The proposed Training Network will make an essential contribution to train them. The partners of this consortium are universities, national research institutes, international accelerator laboratories and industrial partners. Together they provide a unique stimulating inter- national environment for a broad high-quality education in all aspects of detector science for young scientists, starting from BSc students to post-doctoral fellows. The network provides the trainees access to a broad range of world class facilities and allows them to perform research in direct collaboration with industrial partners. The trainees profit from the combined research and teaching experience and the full spectrum of training programmes offered by the network. This Training Network primarily ta...
Concept and Project. Objective(s) This training network is formed by major European institutions in the field of radiation detectors in which European science has a leading role worldwide. The network will contribute to reinforce this role through challenging common projects. The results of the proposed projects will find their applications in the next generation of particle physics experiments like at the SLHC, the Super-B factory, ILC and FAIR, as well as in astro-particle physics, medicine, photon science and a number of other scientific and industrial applications. The main scientific achievement of this training network will be an overall and clearly visible gain in the performance of particle detectors for SLHC, ILC and other future particle physics experiments. The R&D conducted in the network is expected to lead to the following main results: − Silicon tracking devices: Availability of specifically engineered materials and optimized xx- xxxxxx layouts which withstand the unprecedented radiation loads expected in SLHC or FAIR. − Novel tracking detectors: Understanding the intrinsic limitations. New performance records for novel particle detectors like MAPs, 3D semiconductor detectors, GEMs or Micromegas; − Photon detectors: Development for fast single photon detection devices, able to cover large areas and/or operate in high magnetic fields. − Construction and complete characterization of fully functional prototypes of particle detector subsystems for considered applications in HEP experiments (calorimetry, particle ID).
Concept and Project objective(s) EO-MINERS aims at integrating new and existing Earth Observation tools to improve best prac- xxxx in mining activities and to reduce the mining related environmental and societal footprint by • introducing innovative remote sensing tools to the mining industry, • providing accuracy and quality measures for remote sensing products, • demonstrating the application of Earth Observation in different case studies, • fostering the dialogue between mining industry and environmental organisations based on EO-derived information and • generalising the obtained results to be used in operational mining applications in the fu- ture.
Concept and Project objective(s) What: A pluggable distributed infrastructure for Web-reasoning and search Why: To provide an infrastructure that scales up to realistic semantic computing applications For Whom: For European applications industry, to enable real-scale semantic computing By Whom: A multi-disciplinary team of scientists, two innovative IT SMEs, and two strong European industries (ICT and Pharmaceutical), enriched by expertise from the US, Korea and China. Overall Vision The driving vision behind LarKC is to go beyond the limited storage, querying and inference technology currently available for semantic computing. The fundamental assumption taken is that such an infrastructure must go beyond the current paradigms which are strictly based on logic. By fusing reasoning (in the sense of logic) with search (in the sense of information retrieval), and taking seriously the notion of limited rationality (in the sense of Xxxxxxx Xxxxx) we will obtain the paradigm shift that is required for reasoning at Web scale. The overall vision of LarKC is: To build an integrated platform for semantic computing on a scale well beyond what is currently possible. The platform will fulfill needs in sectors that are dependent on massive heterogeneous information sources such as telecommunication services, bio-medical research, and drug-discovery. The platform will have a pluggable architecture in which it is possible to exploit techniques and heuristics from diverse areas such as databases, machine learning, cognitive science, Semantic Web, and others. The platform will be implemented on a computing cluster and via “computing at home”, and will be available to researchers and practitioners from outside the consortium to run their own experiments and applications, using suitable plug-in components. What We will develop the Large Knowledge Collider. The Large Knowledge Collider is a pluggable algorithmic framework and will be implemented on a distributed computational platform. It will scale to web-reasoning by trading quality for computational cost and by embracing incompleteness and unsoundness. Pluggable: Instead of being built only on logic, the Large Knowledge Collider will exploit a large variety of methods from other fields: cognitive science (human heuristics), economics (limited rationality and cost/benefit trade-offs), information retrieval (recall/precision trade-offs), and databases (very large datasets). A pluggable architecture will ensure that computational methods from the...
Concept and Project
