[289] | 1 | \anrdoc{Preciser:\begin{itemize} |
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| 2 | \item positionnement du projet par rapport au contexte developpe precedemment : |
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| 3 | vis- a-vis des projets et recherches concurrents, complementaires ou |
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| 4 | anterieurs, des brevets et standards... |
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| 5 | \item indiquer si le projet s'inscrit dans la continuite de projet(s) anterieurs |
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| 6 | deja finances par l'ANR. Dans ce cas, presenter brievement les resultats acquis, |
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| 7 | \item positionnement du projet par rapport aux axes thematiques de l'appel a projets, |
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| 8 | \item positionnement du projet aux niveaux europeen et international. |
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| 9 | \end{itemize}} |
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| 10 | |
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| 11 | % Relevance of the proposal |
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| 12 | %The COACH proposal addresses directly the \emph{Embedded Systems} item of |
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| 13 | %the ARPEGE program. |
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| 14 | |
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| 15 | %PC => IA et ALain |
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| 16 | %J'aui déplacé le pargraphe ci dessous en conclusion de la section précédente 2.1 |
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| 17 | |
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| 18 | %It aims to propose solutions to the societal/economical challenges by |
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| 19 | %providing SMEs novel design capabilities enabling them to increase their |
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| 20 | %design productivity with design exploration and synthesis methods that are placed on top |
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| 21 | %of the state-of-the-art methods. |
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| 22 | %This project proposes an open-source framework for mapping multi-tasks software applications |
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| 23 | %on Field Programmable Gate Array circuits (FPGA). |
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| 24 | %%% |
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[356] | 25 | \subsubsection*{Positioning in regards with the economical and social context} |
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[289] | 26 | COACH will contribute to build an open design and run-time |
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| 27 | environment, including communication middleware and tools to support |
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[356] | 28 | developers in the production of embedded software, through all phases of the software life cycle, |
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[319] | 29 | from requirements analysis down to deployment and maintenance. |
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[289] | 30 | More specifically, COACH focuses on: |
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| 31 | \begin{itemize} |
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[356] | 32 | \item High level methods and concepts (esp. Requirements and architectural level) for system |
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[289] | 33 | design, development and integration, addressing complexity aspects and modularity. |
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| 34 | \item Open and modular design environments, enabling flexibility and extensibility by |
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| 35 | means of new or sector-specific tools and ensuring consistency and traceability along the |
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[356] | 36 | development life cycle. |
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[289] | 37 | \item Light/agile methodologies and adaptive workflow providing a dynamic and adaptive |
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| 38 | environment, suitable for co-operative and distributed development. |
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[356] | 39 | \item Integration of the solutions and engines being developed into a state of the art SoC and system |
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[315] | 40 | design flow, using the IP-XACT IEEE 1685 standard |
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[289] | 41 | \end{itemize} |
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[339] | 42 | The COACH results will contribute to strengthen Europe's competitive position by developing |
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[289] | 43 | technologies and methodologies for product design, focusing (in compliance with the |
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| 44 | %scope of the above program) on technologies, engineering methodologies, novel tools, |
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| 45 | %methods which facilitate resource use efficiency. The approaches and tools to be developed |
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| 46 | %in COACH will enable new and emerging information technologies for the development, |
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| 47 | %methods which facilitate resource use efficiency. The COACH approaches and tools |
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| 48 | scope of the above program) on technologies, engineering methodologies, novel tools |
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| 49 | which facilitate resource use efficiency. The COACH approaches and tools |
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| 50 | will enable new and emerging information technologies for the development, |
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| 51 | manufacturing and integration of devices and related software into end-products. |
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| 52 | %%% |
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[356] | 53 | \subsubsection*{Positioning and continuity with other projects} |
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[289] | 54 | The COACH project will benefit from a number of previous recent projects: |
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| 55 | \begin{description} |
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| 56 | \item[SOCLIB] |
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[297] | 57 | The SoCLib ANR platform (2007-2009) is an open infrastructure |
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| 58 | that supports system level virtual prototyping of shared memory, multi-processors |
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[289] | 59 | architectures, and provides tools to map multi-tasks software application on these |
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| 60 | architectures, for reliable performance evaluation. |
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| 61 | The core of this platform is a library of SystemC simulation models for |
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[297] | 62 | general purpose IP cores. |
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| 63 | It provides also embedded operating systems and software/hardware |
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[289] | 64 | communication middleware. |
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[335] | 65 | \item[ROMA] The ROMA ANR project (2007-2010) \cite{roma,RAFFIN:2010:INRIA-00539874:1} |
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[289] | 66 | involving IRISA (CAIRN team), LIRMM, CEA List, THOMSON France R\&D, |
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| 67 | proposes to develop a reconfigurable processor, exhibiting high |
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| 68 | silicon density and power efficiency, able to adapt its computing |
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[339] | 69 | structure to computation patterns that can be faster or more |
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[289] | 70 | power efficient. %The ROMA project study a pipeline of |
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| 71 | %evolved low-power coarse grain reconfigurable operators to avoid |
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| 72 | %traditional overhead, in reconfigurable devices, related to the |
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| 73 | %interconnection network. |
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| 74 | The project will borrow from the ROMA |
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| 75 | ANR project and the ongoing joint INRIA-STMicro |
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| 76 | Nano2012 project to adapt existing pattern extraction algorithms |
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| 77 | and datapath merging techniques to ASIP synthesis. |
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| 78 | % and datapath merging techniques to the synthesis of customized |
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| 79 | % ASIP processors. |
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| 80 | \item[TSAR] |
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| 81 | The TSAR MEDEA+ project (2008-2010) involving BULL, THALES and \upmc targets the design of a |
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| 82 | % The TSAR MEDEA+ project (2008-2010) targets the design of a |
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| 83 | scalable, coherent shared memory, multi-cores processor architecture, and uses the SoCLib |
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[356] | 84 | platform for virtual prototyping. COACH will benefit from the synthesizable VHDL |
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| 85 | models developed in the framework of TSAR (MIPS32 processor core, and RING interconnect). |
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[289] | 86 | \item[BioWic] |
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| 87 | On the HPC application side, we also hope to benefit from the experience in |
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| 88 | hardware acceleration of bioinformatic algorithms/workfows gathered by the |
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[383] | 89 | CAIRN group (ANR BioWic project 2009-2011), so as to |
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[289] | 90 | be able to validate the framework on real-life HPC applications. |
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[307] | 91 | |
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| 92 | \item[SoCket] |
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| 93 | The design flow defined in this project targets the design of critical embedded systems. |
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| 94 | It covers important steps as system architecture exploration, and the definition of virtual |
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| 95 | prototypes at different levels of abstraction to support early embedded software development, |
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| 96 | verification of hardware blocks, and preparation of certification activities. |
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| 97 | COACH solutions and engines will be specified to be integrated into this standard flow. |
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| 98 | MDS, Thales TRT, TIMA are already collaborating in this project. |
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| 99 | |
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| 100 | \item[HOSPI] |
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| 101 | The objective of this project (with TIMA and MDS) was to define innovative methods, and implement the associated tools, to ease |
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| 102 | the mapping of data-streaming applications on heterogeneous platforms. COACH will use the abstracted description |
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| 103 | format based on IP-XACT for hardware platforms and the results concerning the integration of code generators into a standard design flow. |
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| 104 | |
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| 105 | \item[SoftSoC] |
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[383] | 106 | TIMA and MDS are involved in this project which aims at the |
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| 107 | definition and generation of Hardware Dependent Software layers of a |
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| 108 | system. |
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| 109 | Crucial extensions of the IP-XACT standard will be reused from this |
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| 110 | project, as well as code generation techniques based on them. |
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[307] | 111 | |
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[289] | 112 | \end{description} |
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| 113 | %%% |
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[297] | 114 | The partners involved in the COACH project have a well established expertise |
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| 115 | in the following domains: |
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[289] | 116 | \begin{itemize} |
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| 117 | \item |
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| 118 | In the field of High Level Synthesis (HLS), the project |
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| 119 | leverages on know-how acquired over the last 15 years with the GAUT~\cite{gaut08} project |
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[297] | 120 | developed by the \ubs laboratory, and with the UGH~\cite{ugh08} project developed |
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[289] | 121 | by the \upmc and \tima laboratories. |
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| 122 | \item |
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| 123 | Regarding system level architecture, the project is based on the know-how |
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| 124 | acquired by \upmc and \tima in the framework of various projects |
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| 125 | in the field of communication architectures for shared memory multi-processors systems |
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| 126 | (COSY~\cite{cosy}, DISYDENT~\cite{disydent05} or DSPIN~\cite{dspin08} of MEDEA-MESA). |
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| 127 | As an example, the DSPIN project is now used in the TSAR project. |
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| 128 | \item |
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| 129 | Regarding Application Specific Instruction Processor (ASIP) design, the |
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| 130 | CAIRN group at INRIA Rennes -- Bretagne Atlantique benefits from several years of |
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| 131 | expertise in the domain of retargetable compiler |
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| 132 | (Armor/Calife~\cite{CODES99} since 1996, and the Gecos |
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| 133 | compilers~\cite{ASAP05} since 2002). |
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[297] | 134 | \item |
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[289] | 135 | In the field of compilers, the \lip Compsys group was founded in 2002 |
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| 136 | by several senior researchers with experience in |
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| 137 | high performance computing and automatic parallelization. They have been |
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| 138 | among the initiators of the polyhedral model, a theory which serve to |
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| 139 | unify many parallelism detection and exploitation techniques for regular |
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[356] | 140 | programs. It is expected that the techniques developed by \lip for |
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[289] | 141 | parallelism detection, scheduling \cite{Feau:92aa,Feau:92bb}, |
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| 142 | process construction \cite{Feau:96} and memory management \cite{bee} |
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| 143 | will be very useful as a front-end for HLS tools. |
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[297] | 144 | \item |
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[307] | 145 | Regarding industrial flow integration \mds will bring its strong expertise |
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[378] | 146 | in IEEE 1685 (IP-XACT) standard. The \mds team is involved and contributes actively |
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| 147 | to it since 2003 and the Magillem tool suite is used for its validation. Magillem is used in |
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[307] | 148 | industrial production flows of ST, NXP, TI, Qualcomm, and system integrators like Thales, |
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[319] | 149 | Astrium, Thomson, etc. This guarantees a strong alignement on customers needs and enhanced results exploitation. |
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[307] | 150 | |
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[289] | 151 | \end{itemize} |
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| 152 | %%% |
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[307] | 153 | \subsubsection*{Relevance to the call axis} |
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[315] | 154 | This project answer to the global statement of the call "INGENIERIE NUMERIQUE ET SECURITE (INS)" by proposing |
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[339] | 155 | methods and tools for the design of application to be run on platforms of the next generation. |
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[356] | 156 | Improvements can be expected for productivity, |
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| 157 | time-to-market (automation and code generation) and reliability (management of high level specifications down to implementation). |
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[315] | 158 | In this call, the COACH project totally fulfills the objectives of the axis 2 "METHODES, |
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[297] | 159 | OUTILS ET TECHNOLOGIES POUR LES SYSTEMES EMBARQUES". |
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[289] | 160 | COACH will address new embedded systems architectures by allowing the design of |
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| 161 | Multi-Core Systems-on-Chip (possibly heterogeneous) on FPGA according to the design |
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| 162 | constraints and objectives (real-time, low-power). It will permit designing complex SoC |
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| 163 | based on IP cores (memory, peripherals...), |
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| 164 | running Embedded Software, as well as an Operating System with associated middleware and |
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[319] | 165 | API and using automatically generated hardware accelerators. It will also permit to use |
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[289] | 166 | efficiently different dynamic system management techniques and re-configuration mechanisms. |
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[315] | 167 | The results will be tailored in order to be integrated in standard design flow of critical systems. |
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[297] | 168 | \\ |
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[289] | 169 | COACH will address High-Performance Computing (HPC) by helping designers to accelerate an |
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| 170 | application running on a PC. |
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| 171 | By providing tools that translate high level language programs to FPGA |
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| 172 | configurations, COACH will allow to easily migrate critical parts into an FPGA plugged to the |
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| 173 | PC bus (through a communication link like PCI/X). |
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[297] | 174 | \parlf |
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[315] | 175 | The COACH project has been also shaped to answer to the axis 5 "USAGES". |
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[289] | 176 | COACH will address robotic and control applications by |
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| 177 | allowing to design complex systems based on MPSoC architecture. |
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| 178 | Like in the consumer electronics domain, future control applications |
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| 179 | will employ more and more SoC for safety and security applications. |
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| 180 | Application domains for such systems are for example automotive |
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| 181 | or avionics domains (e.g. collision-detection, intelligent navigation...). |
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| 182 | Manufacturing technology will also increasingly need high-end vision analysis and high-speed |
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| 183 | robot control. |
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[297] | 184 | % |
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[289] | 185 | The results of the COACH project will help users to build cryptographic secure systems implemented in |
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[339] | 186 | in a combination of hardware and software in an effective way, substantially enhancing the |
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| 187 | productivity of the field, improving the |
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[289] | 188 | quality and reducing the design time and the cost of synthesised cryptographic devices. |
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[307] | 189 | % |
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[364] | 190 | COACH will contribute to enhance the safety in design of critical system for two main reasons: |
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| 191 | \begin{itemize} |
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| 192 | \item by providing a way to automate the mapping of application onto MPSoC |
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| 193 | architecture; code generators of the tool chain will be subject to |
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| 194 | certification. |
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| 195 | \item by relaying on design flow defined by SoCKET, which is dedicated to |
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| 196 | safety of critical systems, COACH will benefit from features related to |
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| 197 | requirements traceability. |
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| 198 | \end{itemize} |
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| 199 | % |
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[356] | 200 | \subsubsection*{European and international positioning} |
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[307] | 201 | % |
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[378] | 202 | Finally, it is worth noting that this project covers priorities defined by the commission |
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[356] | 203 | experts in the field of Information Technologies Society (IST) for Embedded |
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[289] | 204 | Systems: \textit{ $<<$Concepts, methods and tools for designing systems dealing with systems complexity |
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| 205 | and allowing to apply efficiently applications and various products on embedded platforms, |
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| 206 | considering resources constraints (delays, power, memory, etc.), security and quality |
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| 207 | services$>>$}. |
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