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- Feb 14, 2010, 7:27:44 AM (15 years ago)
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- anr
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anr/section-6.1.tex
r137 r140 10 10 scientific and technical information, development, as well as 11 11 providing expert advice and participating in international programs. 12 12 \parlf 13 13 By playing a leading role in the scientific community in the field and 14 14 being in close contact with industry, INRIA is a major participant in … … 22 22 approximately 1 000 doctoral students work on theses as part of INRIA 23 23 research project-teams. 24 24 \parlf 25 25 INRIA develops many partnerships with industry and fosters technology 26 26 transfer and company foundation in the field of ICST - some ninety … … 30 30 involved in standardization committees such as the IETF, ISO and the 31 31 W3C of which INRIA was the European host from 1995 to 2002. 32 32 \parlf 33 33 INRIA maintains important international relations and exchanges. In 34 34 Europe, INRIA is a member of ERCIM which brings together research … … 37 37 collaborates with numerous scientific and academic institutions abroad 38 38 (joint laboratories such as LIAMA, associated research teams, training 39 and internship programs).\\ 40 39 and internship programs). 41 40 Two \inria project-teams participate to this project. 42 41 \begin{itemize} 43 \item CAIRN. The CAIRN group of INRIA Rennes -- Bretagne Atlantique study 44 reconfigurable system-on-chip, i.e. hardware systems whose 45 configuration may change before or even during execution. To this end, 46 CAIRN has 13 permanent researchers and a variable number of PhDstudents, post-docs and engineers.42 \item CAIRN. The CAIRN group of INRIA Rennes -- Bretagne Atlantique study reconfigurable 43 system-on-chip, i.e. hardware systems whose configuration may change before or even during 44 execution. To this end, CAIRN has 13 permanent researchers and a variable number of PhD 45 students, post-docs and engineers. 47 46 CAIRN intends to approach reconfigurable architectures from three 48 47 angles: the invention of new reconfigurable platforms, the development … … 50 49 exploration of the interaction between algorithms and architectures. 51 50 CAIRN is a joint team with CNRS, INSA of Rennes, University of Rennes 1 and ENS Cachan. 52 53 51 \item COMPSYS. The Compsys group of Ecole Normale Sup\'erieure de Lyon is a project-team 54 52 of INRIA Rh\^one-Alpes and a part of Laboratoire de l'Informatique du … … 59 57 several well known libraries for linear programming, polyhedra manipulation 60 58 and optimization in general. It has strong industrial cooperations, notably 61 with ST Microelectronics and Thales.59 with ST Microelectronics and \thales. 62 60 \end{itemize} 63 61 … … 74 72 digital components on one end of the spectrum, to multiprocessor 75 73 Systems-on-Chip together with their basic operating system on the other end. 76 74 \parlf 77 75 Currently, the lab employs 124 persons among which 60 PhD candidates, and runs 78 76 32 ongoing French/European funded projects. 79 77 Since its creation in 1984, TIMA funded 7 startups, patented 36 inventions 80 78 and had 243 PhD thesis defended. 81 79 \parlf 82 80 The System Level Synthesis Group (25 people including PhDs) is 83 81 involved in several FP6, FP7, CATRENE and ANR projects. … … 101 99 books, 200 journal publications, 500 conference publications, 22 102 100 patents, 69 PhDs diploma. 103 \par 101 \parlf 104 102 The UBS/Lab-STICC laboratory is involved in several national research 105 103 projects (e.g. RNTL : SystemC'Mantic, EPICURE - RNRT : MILPAT, ALIPTA, … … 114 112 syntax and semantics-oriented editor, the DSP power estimation tool 115 113 Soft-explorer or the co-design framework Design Trotter. 116 \\ 117 \par 114 \parlf 118 115 The CACS department of the Lab-STICC (also referred as UBS/Lab-STICC), 119 116 located in Lorient, is involved in COACH. … … 126 123 which enclose signal, image, video, vision, and communication processing. 127 124 128 129 125 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 130 126 \subsubsection{\upmc} 131 127 132 University Pierre et Marie Curie (UPMC) is the largest university in France (7400 employees,38000 students). 133 The Laboratoire d'Informatique de Paris 6 (LIP6) is the computer science laboratory of UPMC, hosting 134 more than 400 researchers, under the umbrella of the CNRS (Centre National de la Recherche Scientifique). 135 The \og System on Chip \fg Department of LIP6 consists of 80 people, including 40 PHD students. 128 University Pierre et Marie Curie (UPMC) is the largest university in France (7400 129 employees,38000 students). 130 The Laboratoire d'Informatique de Paris 6 (LIP6) is the computer science laboratory of 131 UPMC, hosting more than 400 researchers, under the umbrella of the CNRS (Centre National 132 de la Recherche Scientifique). 133 The \og System on Chip \fg Department of LIP6 consists of 80 people, including 40 PHD 134 students. 136 135 The research focuses on CAD tools and methods for VLSI and System on Chip design. 137 \ parlf136 \\ 138 137 The annual budget is about 3 M{\texteuro}, and 1.5 M{\texteuro} are from research contracts. 139 The SoC department has been involved in several european projects :IDPS, EVEREST, OMI-HIC, OMI-MACRAME, 140 OMI-ARCHES, EUROPRO, COSY, Medea SMT, Medea MESA, Medea+ BDREAMS, Medea+ TSAR. 141 \parlf 142 The public domain VLSI CAD system ALLIANCE, developped at UPMC is installed in more than 200 universities worldwide. 143 The LIP6 is in charge of the technical coordination of the SoCLib national project, and is hosting 144 the SoCLib WEB server. 145 In the SoCLin platform, the DSX tool is used for design space exploration. 146 It helps the system designer to describe the coarse grain parallelism of the software application 147 as a Task and Communication Graph, to configure the hardware architecture, and to map the 148 multi-task software application on the multi-processors architecture. 149 The DSX toll will be extended to support the FPGA target. 150 Moreover, the LIP6 developped during the last 10 years the UGH tool for high level synthesis 151 of control-dominated coprocessors. 138 The SoC department has been involved in several european projects :IDPS, EVEREST, OMI-HIC, 139 OMI-MACRAME, OMI-ARCHES, EUROPRO, COSY, Medea SMT, Medea MESA, Medea+ BDREAMS, Medea+ 140 TSAR. 141 \parlf 142 The public domain VLSI CAD system ALLIANCE, developped at UPMC is installed in more than 143 200 universities worldwide. 144 The LIP6 is in charge of the technical coordination of the SoCLib national project, and is 145 hosting the SoCLib WEB server. 146 The SoCLib DSX component was designed and developped in our laboratory. 147 It allows design space exploration and will the base of the $CSG$ COACH tools. 148 Moreover, the LIP6 developped during the last 10 years the UGH tool for high level 149 synthesis of control-dominated coprocessors. 152 150 This tool will be modified to be integrated in the COACH design flow. 153 151 \parlf 154 Even if the preferred dissemination policy for the COACH design flow will be the free software policy, 155 (following the SoCLib model), the SoC department is ready to support start-ups : Six startup companies 156 (including \zied) have been created by former researchers from the SoC department of LIP6 between 1997 and 2002. 152 Even if the preferred dissemination policy for the COACH design flow will be the free 153 software policy, (following the SoCLib model), the SoC department is ready to support 154 start-ups : Six startup companies (including \zied) have been created by former 155 researchers from the SoC department of LIP6 between 1997 and 2002. 157 156 158 157 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% … … 216 215 core businesses: aerospace (with all major aircraft manufacturers as customers), defence, 217 216 and security (including ground transportation solutions). It employs 68000 people 218 worldwide, and is present in 50 countries. \thales develops its strategic capabilities in 219 component, software and system engineering and architectures through its R \& T organization. 220 Its six Divisions manage their strategy and technical co-ordination per domain with 221 hundreds of Units in these Divisions developing their technical activities in close 222 relationship with their market. In this environment, \thales Research \& Technology 223 operates at the corporate level as the technical community network architect, in charge of 224 developing upstream and \thales-wide R \& T activities, with vision and visibility. 225 In support of \thales applications, TRT's mission is also to anticipate and speed up 226 technology transfer from research to development in Divisions by developing collaborations 227 in R\&T. 228 229 Thales is international, but Europe-centered. Research \& Development activities are 230 disseminated, and corporate Research and Technology is concentrated in Centers in France, 231 the United Kingdom and the Netherlands. 232 The R\&T in Thales is focused mostly on critical information systems, 233 processing, control and cognitive systems, and autonomous systems. 234 235 A key mission of our R\&T centres is to have a bi-directional transfer, or âimpedance 236 matchingâ function between the scientific research network and the corresponding 237 businesses. Benefiting from its presence and visibility on the international scene in 238 advanced sciences, technology and software, \thales Research \& Technology is perceived as 239 a valuable partner of the best research centres (academic or industrial) through 240 recognized scientists and research engineer participation in collaborative projects. 241 The TRTâs Information Science and Technology Group is able to develop innovative solutions 242 along the information chain exploiting sensors data, through expertise in: computational 243 architectures in embedded systems, typically suitable for autonomous system environments, 244 mathematics and technologies for decision involving information fusion and cognitive 245 processing, and cooperative technologies including man system interaction. 217 worldwide, and is present in 50 countries. \thales Research \& Technology operates at the 218 corporate level as the technical community network architect, in charge of developing 219 upstream and \thales-wide R \& T activities, with vision and visibility. In support of 220 \thales applications, TRT's mission is also to anticipate and speed up technology transfer 221 from research to development in Divisions by developing collaborations in R\&T. \thales is 222 international, but Europe-centered. Research \& Development activities are disseminated, 223 and corporate Research and Technology is concentrated in Centres in France, the United 224 Kingdom and the Netherlands. A key mission of our R\&T centres is to have a bi-directional 225 transfer, or âimpedance matchingâ function between the scientific research network and the 226 corresponding businesses. The TRTâs Information Science and Technology Group is able to 227 develop innovative solutions along the information chain exploiting sensors data, through 228 expertise in: computational architectures in embedded systems, typically suitable for 229 autonomous system environments, mathematics and technologies for decision involving 230 information fusion and cognitive processing, and cooperative technologies including man 231 system interaction. 232 \parlf 246 233 The Embedded System Laboratory (ESL) of TRT involved in the COACH project is part of the 247 Information Science and Technology Group. 248 249 Like other labs of TRT, ESL is in charge of making the link between the needs from Thales 250 business units and the emerging technologies, in particular through assessment and 251 de-risking studies. 252 It has a long experience on parallel architectures design, in particular on SIMD 253 architectures used for image processing and signal processing applications and on 254 reconfigurable architectures. 234 Information Science and Technology Group. Like other labs of TRT, ESL is in charge of 235 making the link between the needs from \thales business units and the emerging 236 technologies, in particular through assessment and de-risking studies. It has a long 237 experience on parallel architectures design, in particular on SIMD architectures used for 238 image processing and signal processing applications and on reconfigurable architectures. 255 239 ESL is also strongly involved in studies on programming tools for these types of 256 architectures and has developed the SpearDE tool used in this project. 257 The laboratory had coordinated the FP6 IST MORPHEUS project on reconfigurable technology, 258 being highly involved in the associated programming toolset. 259 260 The team is also involved in 261 the FP6 IST FET AETHER project on self-adaptability technologies and coordinates national 262 projects on MPSoC architecture and tools like the \verb+Ter@ops+ project (P\^{o}le de 263 Comp\'{e}titivit\'{e} \verb+System@tic+) dedicated to the design of a MPSoC for intensive 240 architectures and has developed the SpearDE tool used in this project. The laboratory had 241 coordinated the FP6 IST MORPHEUS project on reconfigurable technology, being highly 242 involved in the associated programming toolset. The team is also involved in the FP6 IST 243 FET AETHER project on self-adaptability technologies and coordinates national projects on 244 MPSoC architecture and tools like the Ter\verb+@+ops project (P\^{o}le de 245 Comp\'{e}titivit\'{e} System\verb+@+tic) dedicated to the design of a MPSoC for intensive 264 246 computing embedded systems. 265 247 … … 273 255 level of logic density. This high capacity is accessible using a traditional RTL flow from 274 256 Verilog/VHDL synthesis all the way to bitstream generation. 275 257 \parlf 276 258 \zied is a spin-off from LIP6 (Laboratoire Informatique Paris 6) and was awarded at the 277 259 French National Competition for Business Startup and Innovative Technology in 2007 and … … 305 287 Eutelsat, AIRBUS, Schlumberger. \navtel participates from the R\&D phase up to the 306 288 system delivery. 307 308 289 \begin{description} 309 290 \item[Recognitions:]\mbox{} -
anr/section-6.2.tex
r134 r140 3 3 Alain Greiner is the initiator and the main architect of the SoCLib project. 4 4 This ANR platform for virtual prototyping of MPSoCs involved 6 industrial companies 5 (including ST Microelectronics and Thales) and ten academic laboratories5 (including ST Microelectronics and \thales) and ten academic laboratories 6 6 (5 of them are involved in the COACH project). 7 The SoCLib project was managed by Thales, but the technical coordination has been done7 The SoCLib project was managed by \thales, but the technical coordination has been done 8 8 by Alain Greiner, who has a good experience in coordinating large technical projects 9 9 in both industrial and academic contexts: 10 10 % 11 11 \begin {itemize} 12 12 \item
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