[99] | 1 | \begin{table}\leavevmode\center |
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| 2 | \begin{small}\begin{tabular}{|l|l|l|l|}\hline |
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| 3 | Segment & 2010 & 2011 & 2012 \\\hline\hline |
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| 4 | Communications & 1,867 & 1,946 & 2,096 \\ |
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| 5 | High end & 467 & 511 & 550 \\\hline |
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| 6 | Consumer & 550 & 592 & 672 \\ |
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| 7 | High end & 53 & 62 & 75 \\\hline |
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| 8 | Automotive & 243 & 286 & 358 \\ |
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| 9 | High end & - & - & - \\\hline |
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| 10 | Industrial & 1,102 & 1,228 & 1,406 \\ |
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| 11 | High end & 177 & 188 & 207 \\\hline |
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| 12 | Military/Aereo & 566 & 636 & 717 \\ |
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| 13 | High end & 56 & 65 & 82 \\\hline\hline |
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| 14 | Total FPGA/PLD & 4,659 & 5,015 & 5,583 \\ |
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| 15 | Total High-End FPGA & 753 & 826 & 914 \\\hline |
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| 16 | \end{tabular}\end{small} |
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| 17 | \caption{\label{fpga_market} Gartner estimation of worldwide FPGA/PLD consumption (Millions \$)} |
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| 18 | \end{table} |
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| 19 | % |
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[171] | 20 | Microelectronic components allow the integration of complex functions into products, increases |
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[38] | 21 | commercial attractivity of these products and improves their competitivity. |
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[97] | 22 | Multimedia and tele-communication sectors have taken advantage from microelectronics facilities |
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| 23 | thanks to the developpment of design methodologies and tools for embedded systems. |
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[171] | 24 | Unfortunately, the Non Recurring Engineering (NRE) costs involded in the design |
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[97] | 25 | and manufacturing ASICs is very high. |
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[38] | 26 | An IC foundry costs several billions of euros and the fabrication of a specific circuit |
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| 27 | costs several millions. For example a conservative estimate for a 65nm ASIC project is 10 |
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| 28 | million USD. |
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[171] | 29 | Consequently, it is more and more unaffordable to design and fabricate ASICs for low and medium |
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[97] | 30 | volume markets. |
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[99] | 31 | \parlf |
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[18] | 32 | Today, FPGAs become important actors in the computational domain that was originally dominated |
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[32] | 33 | by microprocessors and ASICs. Just like microprocessors, FPGA based systems can be reprogrammed |
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[97] | 34 | on a per-application basis. For many applications, FPGAs offer significant performance benefits over |
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| 35 | microprocessors implementation. There is still a performance degradation of one order |
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| 36 | of magnitude versus an equivalent ASIC implementations, but low cost |
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[171] | 37 | (500 euros to 10K euros), fast time-to-market and flexibility of FPGAs make them an attractive |
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[18] | 38 | choice for low-to-medium volume applications. |
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| 39 | Since their introduction in the mid eighties, FPGAs evolved from a simple, |
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[134] | 40 | low-capacity gate array to devices (\altera STRATIX III, \xilinx Virtex V) that |
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[18] | 41 | provide a mix of coarse-grained data path units, memory blocks, microprocessor cores, |
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| 42 | on chip A/D conversion, and gate counts by millions. This high logic capacity allows to implement |
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| 43 | complex systems like multi-processors platform with application dedicated coprocessors. |
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[32] | 44 | Table~\ref{fpga_market} shows the estimation of FPGA worldwide market in the next years in |
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[99] | 45 | various application domains. The ``high end'' lines concern only FPGA with high logic |
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| 46 | capacity for complex system implementations. |
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[18] | 47 | This market is in significant expansion and is estimated to 914\,M\$ in 2012. |
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[99] | 48 | The HPC market size is estimated today by FPGA providers at 214\,M\$. |
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| 49 | Using FPGA limits the NRE costs to the design cost. |
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| 50 | This boosts the developpment of automatic design tools and methodologies. |
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| 51 | % |
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| 52 | %Today, several companies (atipa, blue-arc, Bull, Chelsio, Convey, CRAY, DataDirect, DELL, hp, |
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| 53 | %Wild Systems, IBM, Intel, Microsoft, Myricom, NEC, nvidia etc) are making systems where demand |
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| 54 | %for very high performance (HPC) primes over other requirements. They tend to use the highest |
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| 55 | %performing devices like Multi-core CPUs, GPUs, large FPGAs, custom ICs and the most innovative |
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| 56 | %architectures and algorithms. These companies show up in different "traditional" applications and market |
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| 57 | %segments like computing clusters (ad-hoc), servers and storage, networking and Telecom, ASIC |
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| 58 | %emulation and prototyping, military/aereo etc. The HPC market size is estimated today by FPGA providers |
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| 59 | %at 214\,M\$. |
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| 60 | %%% |
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| 61 | \parlf |
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| 62 | This market is dominated by Multi-core CPUs and GPUs based solutions and the expansion |
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[171] | 63 | of FPGA-based solutions is limited by the lack of design automation. |
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[99] | 64 | Nowadays, there are neither commercial nor academic tools covering the whole design process |
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| 65 | from the system level specification to the bit stream generation. |
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| 66 | % IA to Alain: J'ai remis (et ameliore un peu) ca car sinon le Consequently 20 lignes |
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| 67 | % au dessous n'a pas de sens. |
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| 68 | % Deplus dans les demandes ANR de la section, il est demande: analyse de la concurrence |
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[171] | 69 | By using SOPC Builder~\cite{spoc-builder} from \altera, designers can select and |
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[99] | 70 | parameterize components from an extensive drop-down list of IP cores (I/O core, DSP, |
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| 71 | processor, bus core, ...) as well as incorporate their own IP. |
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| 72 | Designers can then generate a synthesized netlist, simulation test bench and custom |
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| 73 | software library that reflect the hardware configuration. |
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| 74 | %% Steven disagree : the C2H compiler bundled with SOPCBuilder does a pretty good job at this. |
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[134] | 75 | %% IA: ces lignes ont ete verifiees et corrigée pa \altera. De plus C2H est plutot limite. |
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[99] | 76 | Nevertheless, SOPC Builder does not provide any facilities to synthesize coprocessors and to |
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| 77 | simulate the platform at a high design level (systemC). |
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| 78 | In addition, SOPC Builder is proprietary and only works together with \altera's Quartus compilation |
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| 79 | tool to implement designs on \altera devices (Stratix, Arria, Cyclone). |
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[171] | 80 | PICO~\cite{pico} and CATAPULT-C~\cite{catapult-c} allow to synthesize |
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[99] | 81 | coprocessors from a C++ description. |
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| 82 | Nevertheless, they can only deal with data dominated applications and they do not handle |
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| 83 | the platform level. |
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| 84 | Similarly, the System Generator for DSP~\cite{system-generateur-for-dsp} is a plug-in to |
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| 85 | Simulink that enables designers to develop high-performance DSP systems for \xilinx FPGAs. |
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| 86 | Designers can design and simulate a system using MATLAB and Simulink. The tool will then |
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| 87 | automatically generate synthesizable Hardware Description Language (HDL) code mapped to |
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| 88 | \xilinx pre-optimized macro-cells. |
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| 89 | However, this tool targets only DSP based algorithms. |
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| 90 | \\ |
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| 91 | Consequently, a designer developping an embedded system needs to master four different |
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| 92 | design environments: |
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| 93 | \begin{enumerate} |
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[171] | 94 | \item a virtual prototyping environment for system level exploration, |
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[134] | 95 | \item an architecture compiler (such as SOPC Builder from \altera, or System generator |
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| 96 | from \xilinx) to define the hardware architecture, |
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[99] | 97 | \item one or several HLS tools (such as PICO~\cite{pico} or CATAPULT-C~\cite{catapult-c}) for |
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| 98 | coprocessor synthesis, |
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| 99 | \item and finally backend synthesis tools (such as Quartus or Synopsys) for the bit-stream generation. |
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| 100 | \end{enumerate} |
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| 101 | Furthermore, mixing these tools requires an important interfacing effort and this makes |
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| 102 | the design process very complex and achievable only by designers skilled in many domains. |
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| 103 | \begin{center}\begin{minipage}{.8\linewidth}\textit{ |
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[171] | 104 | The aim of the COACH project is to integrate all these design steps into a single design framework |
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[97] | 105 | and to allow \textbf{pure software} developpers to develop embedded systems. |
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[99] | 106 | }\end{minipage}\end{center} |
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| 107 | \parlf |
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| 108 | We believe that the combination of a design environment dedicated to software developpers |
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[171] | 109 | and FPGA targets, |
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| 110 | will allow small and even very small companies to propose embedded system and accelerating solutions |
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| 111 | for standard software applications with attractive and competitive prices. |
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[97] | 112 | This new market may explode in the same way as the micro-computer market in the eighties, |
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| 113 | whose success was due to the low cost of the first micro-processors (compared to main frames) |
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| 114 | and the advent of high level programming languages which allowed a high number of programmers |
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| 115 | to launch start-ups in software engineering. |
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