Using specification and description language for life cycle assesment in buildings

The definition of a Life Cycle Assesment (LCA) for a building or an urban area is a complex task due to the inherent complexity of all the elements that must be considered. Furthermore, a multidisciplinary approach is required due to the different sources of knowledge involved in this project. This multidisciplinary approach makes it necessary to use formal language to fully represent the complexity of the used models. In this paper, we explore the use of Specification and Description Language (SDL) to represent the LCA of a building and residential area. We also introduce a tool that uses this idea to implement an optimization and simulation mechanism to define the optimal solution for the sustainability of a specific building or residential.Peer ReviewedPostprint (published version

Overview on agent-based social modelling and the use of formal languages

Transdisciplinary Models and Applications investigates a variety of programming languages used in validating and verifying models in order to assist in their eventual implementation. This book will explore different methods of evaluating and formalizing simulation models, enabling computer and industrial engineers, mathematicians, and students working with computer simulations to thoroughly understand the progression from simulation to product, improving the overall effectiveness of modeling systems.Postprint (author's final draft

Heterogeneity, High Performance Computing, Self-Organization and the Cloud

application; blueprints; self-management; self-organisation; resource management; supply chain; big data; PaaS; Saas; HPCaa

Petri net modelling of a communications protocol

The Petri net is a formal modelling tool applicable to distributed systems and communication protocols. Two methods of analysis are applied to formal models of the "Alternating Bit Protocol". (i) A timed Petri net model is simulated to measure protocol performance. (ii) A modular numeric Petri net model is validated by reachability analysis. The simulation and validation tools are programmed in (i) "C" language and (ii) Prolog. A specification language "Needle" is developed. It describes the model system as a hierarchy of modular state transition networks. The model is searched for all possible event sequences, and the result displayed as a reachability tree. The specification language is capable of describing models which execute backwards in simulation time. The modular numeric Petri net is the basis of a powerful computer architecture, capable of parsing its own specification language to build complex models. Attention is drawn to the similarities between Petri net theory and quantum mechanics

Silicon compilation

Silicon compilation is a term used for many different purposes. In this paper we define silicon compilation as a mapping from some higher level description into layout. We define the basic issues in structural and behavioral silicon compilation and some possible solutions to those issues. Finally, we define the concept of an intelligent silicon compiler in which the compiler evaluates the quality of the generated design and attempts to improve it if it is not satisfactory

Heterogeneity, High Performance Computing, Self-Organization and the Cloud

application; blueprints; self-management; self-organisation; resource management; supply chain; big data; PaaS; Saas; HPCaa

High-Speed Performance, Power and Thermal Co-simulation For SoC Design

This dissertation presents a multi-faceted effort at developing standard System Design Language based tools that allow designers to the model power and thermal behavior of SoCs, including heterogeneous SoCs that include non-digital components. The research contributions made in this dissertation include: • SystemC-based power/performance co-simulation for the Intel XScale microprocessor. We performed detailed characterization of the power dissipation patterns of a variety of system components and used these results to build detailed power models, including a highly accurate, validated instruction-level power model of the XScale processor. We also proposed a scalable, efficient and validated methodology for incorporating fast, accurate power modeling capabilities into system description languages such as SystemC. This was validated against physical measurements of hardware power dissipation. • Modeling the behavior of non-digital SoC components within standard System Design Languages. We presented an approach for modeling the functionality, performance, power, and thermal behavior of a complex class of non-digital components — MEMS microhotplate-based gas sensors — within a SystemC design framework. The components modeled include both digital components (such as microprocessors, busses and memory) and MEMS devices comprising a gas sensor SoC. The first SystemC models of a MEMS-based SoC and the first SystemC models of MEMS thermal behavior were described. Techniques for significantly improving simulation speed were proposed, and their impact quantified. • Vertically Integrated Execution-Driven Power, Performance and Thermal Co-Simulation For SoCs. We adapted the above techniques and used numerical methods to model the system of differential equations that governs on-chip thermal diffusion. This allows a single high-speed simulation to span performance, power and thermal modeling of a design. It also allows feedback behaviors, such as the impact of temperature on power dissipation or performance, to be modeled seamlessly. We validated the thermal equation-solving engine on test layouts against detailed low-level tools, and illustrated the power of such a strategy by demonstrating a series of studies that designers can perform using such tools. We also assessed how simulation and accuracy are impacted by spatial and temporal resolution used for thermal modeling

Nouvelles approches pour la conception d'outils CAO pour le domaine des systèmes embarqués

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal