12,041 research outputs found

    Modeling Networks-on-Chip at System Level with the MARTE UML profile

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    International audienceThe study of Networks on Chips (NoCs) is a research field that primarily addresses the global communication in Systems-on-Chip (SoCs). The selected topology and the routing algorithm play a prime role in the performance of NoC architectures. In order to handle the design complexity and meet the tight time-to-market constraints, it is important to automate most of these NoC design phases. The extension of the UML language called UML profile for MARTE (Modeling and Analysis of Real-Time and Embedded systems) specifies some concepts for model-based design and analysis of real time and embedded systems. This paper presents a MARTE based methodology for modeling concepts of NoC based architectures. It aims at improving the effectiveness of the MARTE standard by clarifying some notations and extending some definitions in the standard, in order to be able to model complex architectures like NoCs

    MARTE based modeling approach for Partial Dynamic Reconfigurable FPGAs

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    International audienceAs System-on-Chip (SoC) architectures become pivotal for designing embedded systems, the SoC design complexity continues to increase exponentially necessitating the need to find new design methodologies. In this paper we present a novel SoC co-design methodology based on Model Driven Engineering using the MARTE (Modeling and Analysis of Real-time and Embedded Systems) standard. This methodology is utilized to model fine grain reconfigurable architectures such as FPGAs and extends the standard to integrate new features such as Partial Dynamic Reconfiguration supported by modern FPGAs. The goal is to carry out modeling at a high abstraction level expressed in UML (Unified Modeling Language) and following transformations of these models, automatically generate the code necessary for FPGA implementation

    High level modeling of Partially Dynamically Reconfigurable FPGAs based on MDE and MARTE

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    International audienceSystem-on-Chip (SoC) architectures are becoming the preferred solution for implementing modern embedded systems. However their design complexity continues to augment due to the increase in integrated hardware resources requiring new design methodologies and tools. In this paper we present a novel SoC co-design methodology based on aModel Driven Engineering framework while utilizing the MARTE (Modeling and Analysis of Real-time and Embedded Systems) standard. This methodology permits us to model fine grain reconfigurable architectures such as FPGAs and allows to extend the standard for integrating new features such as Partial Dynamic Reconfiguration supported by modern FPGAs. The overall objective is to carry out modeling at a high abstraction level expressed in a graphical language like UML (Unified Modeling Language) and afterwards transformations of these models, automatically generate the necessary specifications required for FPGA implementation

    From MARTE to Reconfigurable NoCs: A model driven design methodology

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    Due to the continuous exponential rise in SoC's design complexity, there is a critical need to find new seamless methodologies and tools to handle the SoC co-design aspects. We address this issue and propose a novel SoC co-design methodology based on Model Driven Engineering and the MARTE (Modeling and Analysis of Real-Time and Embedded Systems) standard proposed by Object Management Group, to raise the design abstraction levels. Extensions of this standard have enabled us to move from high level specifications to execution platforms such as reconfigurable FPGAs. In this paper, we present a high level modeling approach that targets modern Network on Chips systems. The overall objective: to perform system modeling at a high abstraction level expressed in Unified Modeling Language (UML); and afterwards, transform these high level models into detailed enriched lower level models in order to automatically generate the necessary code for final FPGA synthesis

    From MARTE to dynamically reconfigurable FPGAs : Introduction of a control extension in a model based design flow

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    System-on-Chip (SoC) can be considered as a particular case of embedded systems and has rapidly became a de-facto solution for implement- ing these complex systems. However, due to the continuous exponential rise in SoC's design complexity, there is a critical need to find new seamless method- ologies and tools to handle the SoC co-design aspects. This paper addresses this issue and proposes a novel SoC co-design methodology based on Model Driven Engineering (MDE) and the MARTE (Modeling and Analysis of Real-Time and Embedded Systems) standard proposed by OMG (Object Management Group), in order to raise the design abstraction levels. Extensions of this standard have enabled us to move from high level specifications to execution platforms such as reconfigurable FPGAs; and allow to implement the notion of Partial Dy- namic Reconfiguration supported by current FPGAs. The overall objective is to carry out system modeling at a high abstraction level expressed in UML (Unified Modeling Language); and afterwards, transform these high level mod- els into detailed enriched lower level models in order to automatically generate the necessary code for final FPGA synthesis

    A Model based design flow for Dynamic Reconfigurable FPGAs

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    International audienceAs System-on-Chip (SoC) based embedded systems have become a de-facto industry standard, their overall design complexity has increased exponentially in recent years, necessitating the introduction of new seamless methodologies and tools to handle the SoC co-design aspects. This paper presents a novel SoC co-design methodology based on Model Driven Engineering and the MARTE (Modeling and Analysis of Real-Time and Embedded Systems) standard, permitting us to raise the abstraction levels and allows to model fine grain reconfigurable architectures such as FPGAs. Extensions of this methodology have enabled us to integrate new features such as Partial Dynamic Reconfiguration supported by Modern FPGAs. The overall objective is to carry out system modeling at a high abstraction level expressed in a graphical language like UML (Unified Modeling Language) and afterwards transformation of these models, automatically generate the necessary code for FPGA synthesis

    System level modeling methodology of NoC design from UML-MARTE to VHDL

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    International audienceThe evolution of the semiconductor technology caters for the increase in the System-on-Chip (SoC) complexity. In particular, this complexity appears in the communication infrastructures like the Network-on-Chips (NoCs). However many complex SoCs are becoming increasingly hard to manage. In fact, the design space, which represents all the concepts that need to be explored during the SoC design, is becoming dramatically large and difficult to explore. In addition, the manipulation of SoCs at low levels, like the Register Transfer Level (RTL), is based on manual approaches. This has resulted in the increase of both time-to-market and the development costs. Thus, there is a need for developing some automated high level modeling environments for computer aided design in order to handle the design complexity and meet tight time-to-market requirements. The extension of the UML language called UML profile for MARTE (Modeling and Analysis of Real-Time and Embedded systems) allows the modeling of repetitive structures such as the NoC topologies which are based on specific concepts. This paper presents a new methodology for modeling concepts of NoC-based architectures, especially the modeling of topology of the interconnections with the help of the repetitive structure modeling (RSM) package of MARTE profile. This work deals with the ways of improving the effectiveness of the MARTE standard by clarifying and extending some notations in order to model complex NoC topologies. Our contribution includes a description of how these concepts may be mapped into VHDL. The generated code has been successfully evaluated and validated for several NoC topologies

    Verifying service continuity in a satellite reconfiguration procedure: application to a satellite

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    The paper discusses the use of the TURTLE UML profile to model and verify service continuity during dynamic reconfiguration of embedded software, and space-based telecommunication software in particular. TURTLE extends UML class diagrams with composition operators, and activity diagrams with temporal operators. Translating TURTLE to the formal description technique RT-LOTOS gives the profile a formal semantics and makes it possible to reuse verification techniques implemented by the RTL, the RT-LOTOS toolkit developed at LAAS-CNRS. The paper proposes a modeling and formal validation methodology based on TURTLE and RTL, and discusses its application to a payload software application in charge of an embedded packet switch. The paper demonstrates the benefits of using TURTLE to prove service continuity for dynamic reconfiguration of embedded software

    IEEE Standard 1500 Compliance Verification for Embedded Cores

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    Core-based design and reuse are the two key elements for an efficient system-on-chip (SoC) development. Unfortunately, they also introduce new challenges in SoC testing, such as core test reuse and the need of a common test infrastructure working with cores originating from different vendors. The IEEE 1500 Standard for Embedded Core Testing addresses these issues by proposing a flexible hardware test wrapper architecture for embedded cores, together with a core test language (CTL) used to describe the implemented wrapper functionalities. Several intellectual property providers have already announced IEEE Standard 1500 compliance in both existing and future design blocks. In this paper, we address the problem of guaranteeing the compliance of a wrapper architecture and its CTL description to the IEEE Standard 1500. This step is mandatory to fully trust the wrapper functionalities in applying the test sequences to the core. We present a systematic methodology to build a verification framework for IEEE Standard 1500 compliant cores, allowing core providers and/or integrators to verify the compliance of their products (sold or purchased) to the standar

    TURTLE-P: a UML profile for the formal validation of critical and distributed systems

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    The timed UML and RT-LOTOS environment, or TURTLE for short, extends UML class and activity diagrams with composition and temporal operators. TURTLE is a real-time UML profile with a formal semantics expressed in RT-LOTOS. Further, it is supported by a formal validation toolkit. This paper introduces TURTLE-P, an extended profile no longer restricted to the abstract modeling of distributed systems. Indeed, TURTLE-P addresses the concrete descriptions of communication architectures, including quality of service parameters (delay, jitter, etc.). This new profile enables co-design of hardware and software components with extended UML component and deployment diagrams. Properties of these diagrams can be evaluated and/or validated thanks to the formal semantics given in RT-LOTOS. The application of TURTLE-P is illustrated with a telecommunication satellite system
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