1 | \anrdoc{(maximum 0,5 page par partenaire) Decrire brievement chaque |
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2 | partenaire et fournir ici les elements permettant d'apprecier la |
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3 | qualification des partenaires dans le projet (le \og pourquoi qui fait quoi |
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4 | \fg). Il peut s'agir de realisations passees, d'indicateurs (publications, |
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5 | brevets), de l'interet du partenaire pour le projet.\\ |
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6 | Montrer la complementarite et la valeur ajoutee des cooperations entre les |
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7 | differents partenaires. L'interdisciplinarite et l'ouverture à diverses |
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8 | collaborations seront à justifier en accord avec les orientations du |
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9 | projet. (1 page maximum)} |
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10 | |
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11 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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12 | \subsubsection{\inria/CAIRN} |
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13 | |
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14 | INRIA, the French national institute for research in computer science |
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15 | and control, operating under the dual authority of the Ministry of |
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16 | Research and the Ministry of Industry, is dedicated to fundamental and |
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17 | applied research in information and communication science and |
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18 | technology (ICST). The Institute also plays a major role in technology |
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19 | transfer by fostering training through research, diffusion of |
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20 | scientific and technical information, development, as well as |
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21 | providing expert advice and participating in international programs. |
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22 | \parlf |
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23 | By playing a leading role in the scientific community in the field and |
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24 | being in close contact with industry, INRIA is a major participant in |
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25 | the development of ICST in France. Throughout its eight research |
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26 | centres in Rocquencourt, Rennes, Sophia Antipolis, Grenoble, Nancy, |
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27 | Bordeaux, Lille and Saclay, INRIA has a workforce of 3 800, 2 800 of |
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28 | whom are scientists from INRIA and INRIA's partner organizations such |
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29 | as CNRS (the French National Center for Scientific Research), |
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30 | universities and leading engineering schools. They work in 168 joint |
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31 | research project-teams. Many INRIA researchers are also professors and |
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32 | approximately 1 000 doctoral students work on theses as part of INRIA |
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33 | research project-teams. |
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34 | %\parlf |
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35 | %INRIA develops many partnerships with industry and fosters technology |
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36 | %transfer and company foundation in the field of ICST - some ninety |
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37 | %companies have been founded with the support of INRIA-Transfert, a |
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38 | %subsidiary of INRIA, specialized in guiding, evaluating, qualifying, |
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39 | %and financing innovative high-tech IT start-up companies. INRIA is |
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40 | %involved in standardization committees such as the IETF, ISO and the |
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41 | %W3C of which INRIA was the European host from 1995 to 2002. |
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42 | %\parlf |
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43 | %INRIA maintains important international relations and exchanges. In |
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44 | %Europe, INRIA is a member of ERCIM which brings together research |
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45 | %institutes from 19 European countries. INRIA is a partner in about 120 |
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46 | %FP6 actions and 40 FP7 actions, mainly in the ICST field. INRIA also |
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47 | %collaborates with numerous scientific and academic institutions abroad |
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48 | %(joint laboratories such as LIAMA, associated research teams, training |
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49 | %and internship programs). |
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50 | |
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51 | The CAIRN group of INRIA Rennes -- Bretagne Atlantique study reconfigurable |
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52 | system-on-chip, i.e. hardware systems whose configuration may change before or even during |
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53 | execution. To this end, CAIRN has 13 permanent researchers and a variable number of PhD |
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54 | students, post-docs and engineers. |
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55 | CAIRN intends to approach reconfigurable architectures from three |
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56 | angles: the invention of new reconfigurable platforms, the development |
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57 | of associated transformation, compilation and synthesis tools, and the |
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58 | exploration of the interaction between algorithms and architectures. |
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59 | CAIRN is a joint team with CNRS, University of Rennes 1 and ENS Cachan. |
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60 | |
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61 | \subsubsection{\lip/Compsys} |
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62 | The Compsys group of Ecole Normale Sup\'erieure de Lyon is a project-team |
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63 | of INRIA Rh\^one-Alpes and a part of Laboratoire de l'Informatique du |
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64 | Parall\'elisme (LIP), UMR 5668 of CNRS. It has four permanent researchers |
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65 | and a variable number of PhD students and post-docs. Its field of |
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66 | expertise is compilation for embedded system, optimizing compilers |
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67 | and automatic parallelization. Its members were among the initiators |
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68 | of the polyhedral model for automatic parallelization and program |
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69 | optimization generally. It has authored or contributed to |
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70 | several well known libraries for linear programming, polyhedra manipulation |
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71 | and optimization in general. It has strong industrial cooperations, notably |
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72 | with ST Microelectronics and \thales. |
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73 | |
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74 | |
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75 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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76 | \subsubsection{\tima} |
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77 | The TIMA laboratory ("Techniques of Informatics and Microelectronics |
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78 | for integrated systems Architecture") is a public research laboratory |
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79 | sponsored by Centre National de la Recherche Scientifique (CNRS, UMR5159), |
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80 | Grenoble Institute of Technology (Grenoble-INP) and Universit\'{e} Joseph Fourier |
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81 | (UJF). |
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82 | The research topics cover the specification, design, verification, test, |
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83 | CAD tools and design methods for integrated systems, from analog and |
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84 | digital components on one end of the spectrum, to multiprocessor |
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85 | Systems-on-Chip together with their basic operating system on the other end. |
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86 | \parlf |
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87 | Currently, the lab employs 124 persons among which 60 PhD candidates, and runs |
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88 | 32 ongoing French/European funded projects. |
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89 | Since its creation in 1984, TIMA funded 7 startups, patented 36 inventions |
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90 | and had 243 PhD thesis defended. |
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91 | \parlf |
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92 | The System Level Synthesis Group (25 people including PhDs) is |
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93 | involved in several FP6, FP7, CATRENE and ANR projects. |
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94 | Its field of expertise is in CAD and architecture for Multiprocessor |
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95 | SoC and Hardware/Software interface. |
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96 | |
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97 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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98 | \subsubsection{\ubs} |
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99 | |
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100 | The Lab-STICC (Laboratoire des Sciences et Techniques de l'Information, |
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101 | de la Communication, et de la Connaissance), is a French CNRS laboratory |
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102 | (UMR 3192) that groups 4 research centers in the west and south |
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103 | Brittany: the Universit\'e de Bretagne-Sud (UBS), the Universit\'e de |
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104 | Bretagne Occidentale (UBO), and Telecom Bretagne (ENSTB). |
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105 | The Lab-STICC is composed of three departments: Microwave and equipments (MOM), |
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106 | Digital communications, Architectures and circuits (CACS) and Knowledge, |
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107 | information and decision (CID). The Lab-STICC represents a staff of 279 |
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108 | peoples, including 115 researchers and 113 PhD students. |
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109 | The scientific production during the last 4 years represents 20 |
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110 | books, 200 journal publications, 500 conference publications, 22 |
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111 | patents, 69 PhDs diploma. |
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112 | \parlf |
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113 | The UBS/Lab-STICC laboratory is involved in several national research |
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114 | projects (e.g. RNTL : SystemC'Mantic, EPICURE - RNRT : MILPAT, ALIPTA, |
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115 | A3S - ANR : MoPCoM, SoCLib, Famous, RaaR, AFANA, Open-PEOPLE, ICTER ...), |
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116 | CMCU project (COSIP) and regional projects (e.g. ITR projects PALMYRE |
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117 | ...). It is also involved in European Project (e.g. ITEA/SPICES, |
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118 | IST/AETHER ...). These projects are conducted through tight cooperation |
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119 | with national and international companies and organizations (e.g. France |
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120 | Telecom CNET, MATRA, CEA, ASTRIUM, \thales Com., \thales Avionics, AIRBUS, |
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121 | BarCo, STMicroelectronics, Alcatel-Lucent ...). Results of those or former |
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122 | projects are for example the high-level synthesis tool GAUT, the UHLS |
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123 | syntax and semantics-oriented editor, the DSP power estimation tool |
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124 | Soft-explorer or the co-design framework Design Trotter. |
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125 | \parlf |
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126 | The CACS department of the Lab-STICC (also referred as UBS/Lab-STICC), |
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127 | located in Lorient, is involved in COACH. |
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128 | The UBS/Lab-STICC is working on the design of complex electronic systems |
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129 | and circuits, especially but not exclusively focussing on real-time |
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130 | embedded systems, power and energy consumption optimization, high-level |
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131 | synthesis and IP design, digital communications, hardware/software |
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132 | co-design and ESL methodologies. The application targeted by the |
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133 | UBS/Lab-STICC are mainly from telecommunication and multimedia domains |
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134 | which enclose signal, image, video, vision, and communication processing. |
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135 | |
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136 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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137 | \subsubsection{\upmc} |
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138 | |
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139 | University Pierre et Marie Curie (UPMC) is the largest university in France (7400 |
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140 | employees,38000 students). |
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141 | The Laboratoire d'Informatique de Paris 6 (LIP6) is the computer science laboratory of |
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142 | UPMC, hosting more than 400 researchers, under the umbrella of the CNRS (Centre National |
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143 | de la Recherche Scientifique). |
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144 | The \og System on Chip \fg Department of LIP6 consists of 80 people, including 40 PHD |
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145 | students. |
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146 | The research focuses on CAD tools and methods for VLSI and System on Chip design. |
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147 | \\ |
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148 | The annual budget is about 3 M{\texteuro}, and 1.5 M{\texteuro} are from research contracts. |
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149 | The SoC department has been involved in several european projects :IDPS, EVEREST, OMI-HIC, |
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150 | OMI-MACRAME, OMI-ARCHES, EUROPRO, COSY, Medea SMT, Medea MESA, Medea+ BDREAMS, Medea+ |
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151 | TSAR. |
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152 | \parlf |
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153 | The public domain VLSI CAD system ALLIANCE, developped at UPMC is installed in more than |
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154 | 200 universities worldwide. |
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155 | The LIP6 is in charge of the technical coordination of the SoCLib national project, and is |
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156 | hosting the SoCLib WEB server. |
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157 | The SoCLib DSX component was designed and developped in our laboratory. |
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158 | It allows design space exploration and will the base of the $CSG$ COACH tools. |
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159 | Moreover, the LIP6 developped during the last 10 years the UGH tool for high level |
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160 | synthesis of control-dominated coprocessors. |
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161 | This tool will be modified to be integrated in the COACH design flow. |
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162 | \parlf |
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163 | Even if the preferred dissemination policy for the COACH design flow will be the free |
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164 | software policy, the SoC department is ready to support start-ups : |
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165 | Six startup companies have been created by former |
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166 | researchers from the SoC department of LIP6 between 1997 and 2002. |
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167 | |
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168 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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169 | \subsubsection{\mdslong} |
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170 | |
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171 | Magillem Design Services has been established by a team of seasoned engineers and a |
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172 | group of business angels in the fall of 2006. The company has inherited Magillem, a |
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173 | robust and innovative technology worth 120 man years. The Magillem environment is |
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174 | dedicated to the design, verification and flow management of complex HW/SW based on IP-XACT. |
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175 | In the service area, we audit the existing industrial flows and propose a work plan to |
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176 | adapt them to IP-XACT, we validate and verify the full compatibility of tools interfaces |
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177 | into a flow testbench, we test the IP deliverables against a benchmark for compliance |
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178 | using our IP-XACT packager, and check IP integration properties onto a test system. |
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179 | Magillem's tools are used in the most advanced production flows of integrated circuit |
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180 | manufacturers (ST, NXP, TI, Qualcomm, etc.) and are linked with the research work of |
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181 | the best laboratories of the domain (LIP6, TIMA, Fhg, OFFIS, etc.). Our participation |
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182 | to leading European collaborative projects (e.g. IST COMPLEX, SPRINT, ICODES, etc.) |
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183 | allow us to maintain a high level of innovation around our core technology: SoC design |
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184 | methodologies at ESL, design and verification in AMS domain, HW/SW co-design, safety |
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185 | and security of systems. |
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186 | Beyond this core technology domain, Magillem has evolved with the tool suite called |
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187 | Revenge, answering to wider assembly issues for large heterogeneous systems. |
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188 | |
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189 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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190 | \subsubsection{\bull} |
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191 | |
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192 | \bull designs and develops servers and software for an open environment, integrating the |
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193 | most advanced technologies. It brings to its customers its expertise and know-how to help |
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194 | them in the transformation of their information systems and to optimize their IT |
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195 | infrastructure and their applications. |
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196 | \parlf |
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197 | \bull is particularly present in the public sector, banking, finance, telecommunication |
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198 | and industry sectors. Capitalizing on its wide experience, the Group has a thorough |
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199 | understanding of the business and specific processes of these sectors, thus enabling it to |
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200 | efficiently advise and to accompany its customers. Its distribution network spreads to |
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201 | over 100 countries worldwide. |
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202 | \parlf |
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203 | The team participating to the COACH project is from the Server Development Department |
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204 | based in Les Clayes-sous-Bois, France. The SD Department is in charge of developing |
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205 | hardware for open servers (e.g. NovaScale) and HPC solutions. Its main activities range |
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206 | from architecture specification, ASIC design/verification/prototyping to board design and |
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207 | include also specific EDA development to complement standard tools. |
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208 | |
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209 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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210 | \subsubsection{\thales} |
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211 | |
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212 | \thales is a world leader for mission critical information systems, with activities in 3 |
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213 | core businesses: aerospace (with all major aircraft manufacturers as customers), defence, |
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214 | and security (including ground transportation solutions). It employs 68000 people |
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215 | worldwide, and is present in 50 countries. \thales Research \& Technology operates at the |
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216 | corporate level as the technical community network architect, in charge of developing |
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217 | upstream and \thales-wide R \& T activities, with vision and visibility. In support of |
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218 | \thales applications, TRT's mission is also to anticipate and speed up technology transfer |
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219 | from research to development in Divisions by developing collaborations in R\&T. \thales is |
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220 | international, but Europe-centered. Research \& Development activities are disseminated, |
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221 | and corporate Research and Technology is concentrated in Centres in France, the United |
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222 | Kingdom and the Netherlands. A key mission of our R\&T centres is to have a bi-directional |
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223 | transfer, or "impedance matching" function between the scientific research network and the |
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224 | corresponding businesses. The TRT's Information Science and Technology Group is able to |
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225 | develop innovative solutions along the information chain exploiting sensors data, through |
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226 | expertise in: computational architectures in embedded systems, typically suitable for |
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227 | autonomous system environments, mathematics and technologies for decision involving |
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228 | information fusion and cognitive processing, and cooperative technologies including man |
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229 | system interaction. |
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230 | \parlf |
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231 | The Embedded System Laboratory (ESL) of TRT involved in the COACH project is part of the |
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232 | Information Science and Technology Group. Like other labs of TRT, ESL is in charge of |
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233 | making the link between the needs from \thales business units and the emerging |
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234 | technologies, in particular through assessment and de-risking studies. It has a long |
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235 | experience on parallel architectures design, in particular on SIMD architectures used for |
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236 | image processing and signal processing applications and on reconfigurable architectures. |
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237 | ESL is also strongly involved in studies on programming tools for these types of |
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238 | architectures and has developed the SpearDE tool used in this project. The laboratory had |
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239 | coordinated the FP6 IST MORPHEUS project on reconfigurable technology, being highly |
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240 | involved in the associated programming toolset. The team is also involved in the FP6 IST |
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241 | FET AETHER project on self-adaptability technologies and coordinates national projects on |
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242 | MPSoC architecture and tools like the Ter\verb+@+ops project (P\^{o}le de |
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243 | Comp\'{e}titivit\'{e} System\verb+@+tic) dedicated to the design of a MPSoC for intensive |
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244 | computing embedded systems. |
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245 | |
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