Graphical Editor for Diagnostic Method Development

Ravi, Sudharshan, Vu, Quang

January 2014

The adage A picture is worth a thousand words conveys the notion that acomplex concept can be understood with just a single picture. Thus visualisingdata allows users to absorb and use large amounts of data quickly.Although textual programming is widely used, it is not best suited for allsituations. Some of these situations require a graphical way to programdata. This thesis investigates the dierent modeling frameworks available withinthe Eclipse ecosystem that allow the reuse of existing XML schema modelsand the creation as well as editing of diagnostic methods. The chosenframeworks were used to build a graphical editor that allows users to create,edit and use diagnostic methods graphically.

Graphical Editor

Eclipse Modeling Framework

Graphiti

XML

XSD

Ecore

Computer Engineering

Datorteknik

Nástroj pro návrh čipu v UML / Tool for Chip Design in UML

Srna, Pavol

January 2010

This paper deals with the creation of the tool for chip design in UML. The intention of this work is to present the news in the UML language version 2.0, that can be possibly used for modeling of embedded systems. Furthermore, it deals with the possibility and method of modeling in the Eclipse environment and it focuses on the Eclipse Modeling Framework. This work explains the principle of developing of graphical editors based on GMF used fully by developing tool. Finally, it discusses the chosen solution.

Model Interchange between ARIS and Eclipse EMF

Kern, Heiko, Kühne, Stefan

06 February 2019

The Architecture of integrated Information Systems (ARIS) is a technical space that is widely used in the area of business process management. The reuse of ARIS models in other working contexts is offered by ARIS-specific import and export interfaces. Nevertheless, the interoperability with other technical spaces is limited. In this paper, we explore ARIS language definition concepts and relate them to the Eclipse Modeling Framework (EMF). We describe an ARIS to EMF bridge which provides transformations of ARIS modeling languages and ARIS models to the EMF environment. Our bridge shows similarities and differences between the two approaches and provides technical interoperability that e.g. enables the processing of ARIS models in EMF-supporting tools (e.g. ATLAS Transformation Language).

info:eu-repo/classification/ddc/004

ddc:004

Creating An Editor For The Implementation of WorkFlow+: A Framework for Developing Assurance Cases

Chiang, Thomas

January 2021

As vehicles become more complex, the work required to ensure that they are safe increases enormously. This in turn results in a much more complicated task of testing systems, subsystems, and components to ensure that they are safe individually as well as when they are integrated. As a result, managing the safety engineering process for vehicle development is of major interest to all automotive manufacturers. The goal of this research is to introduce a tool that provides support for a new framework for modeling safety processes, which can partially address some of these challenges. WorkFlow+ is a framework that was developed to combine both data flow and process flow to increase traceability, enable users to model with the desired granularity safety engineering workflow for their products, and produce assurance cases for regulators and evaluators to be able to validate that the product is safe for the users and the public. With the development of an editor, it will bring WorkFlow+ to life. / Thesis / Master of Applied Science (MASc)

Assurance Case

Safety Engineering

Model-Driven Engineering

Domain Specific Language

ISO 26262

Workflow+

Sirius

Eclipse Modeling Framework

Ecore

Safety Case

Conceiving and Implementing a language-oriented approach for the design of automated learning scenarios

Moura, César

20 June 2007

Cette thèse a pour sujet la conception de scénarios pédagogiques destinés à l'e-formation. Afin de faciliter les échanges de matériaux décrivant des stratégies pédagogiques, la communauté s'est récemment mobilisée pour proposer un langage standard suffisamment générique pour permettre la représentation de n'importe quel scénario, indépendant même du paradigme éducationnel sous-jacent. Appelé génériquement Educational Modeling Language (EML), ce type de langage engendre une nouvelle façon de concevoir des EIAH, en s'éloignant du traditionnel Instructional System Design, une fois que, au lieu de proposer une application finie, les EML proposent un modèle conceptuel standard, une notation pour l'exprimer et des éditeurs et frameworks, laissant aux concepteurs finaux la tâche de créer leurs propres « applications ». Les EMLs permettent alors la création et exécution d'instances de scénarios, dans une approche plus ouverte et flexible, augmentant, ainsi, les possibilités d'adaptation des applications résultantes aux besoins des usagers.<br />Cette flexibilité reste pourtant limitée et, après quelques années de recherche, les EMLs commencent à montrer ses faiblesses. En fait, le langage choisi pour devenir le standard du domaine, le IMS-LD, s'est montré générique, certes, mais peu expressive, ne permettant pas une représentation fidèle des divers scénarios existants. C'est à dire, c'est aux usagers de s'adapter à la syntaxe et sémantique de cet standard.<br />Cette thèse part d'un constat quant aux difficultés du processus de conception lui-même, et aux risques de coupure qu'il peut y avoir entre pédagogues et développeurs de logiciels. Pour améliorer la capacité des équipes pédagogiques à pouvoir spécifier, et même implémenter, des scénarios pédagogiques, nous proposons une approche où c'est l'EML qui doit s'adapter aux besoins de l'usager. L'usager a la possibilité de créer son propre langage (ou ses propres langages), s'il en a besoin. En plus, un même scénario peut être décrit en même temps par des différents EMLs (ou modèles) respectant des différents perspectives - et même paradigmes - de chaque stake holder. <br />Cette approche, appelée multi-EML, est possible grâce aux avancées récentes du génie logiciel, telle l'Architecture Dirigée par les Modèles – l'implémentation la plus connue d'un nouvel paradigme de programmation surnommé Languages Oriented Programming (LOP), qui inclut encore d'autres implémentations. <br />Notre proposition réside dans la conception d'un environnement informatique « auteur », qui repose sur les principes des Languages Oriented Programming, en utilisant la plateforme ouverte ECLIPSE et, plus particulièrement son implémentation du LOP, l'Eclipse Modeling Framework (EMF). Ainsi, les concepteurs auront un outil qui leur permettra de créer des spécifications formelles décrivant les scénarios envisagés et d'en générer automatiquement des applications correspondantes, dans un processus qui démarre avec les descriptions informelles des experts du domaine.<br />Reconnaissant que les experts d'éducation - ceux qui mieux comprennent le domaine - ne sont pas nécessairement des informaticiens, l'environnement proposé, appelé MDEduc, fournit aussi un éditeur permettant de décrire un scénario dans une notation informelle, à savoir le pattern pédagogique, à partir de laquelle les modèles formels peuvent être dérivés. En plus, nous proposons de garder côte à côte et en coïncidence ces descriptions en langage informelles, et les descriptions plus formelles et normatives et d'offrir la possibilité d'effectuer des allers-retours à toutes les phases du cycle de vie du dispositif pédagogique.

informatique

e-formation

conception des EIAH

modélisation

scénario pédagogique

patrons de conception pédagogiques

ingénierie dirigée par les modèles

langages de descriptions

environnement de conception logiciel

génie logiciel

plate-forme ECLIPSE

Eclipse Modeling Framework

Component-Based Model-Driven Software Development

Johannes, Jendrik

07 January 2011

Model-driven software development (MDSD) and component-based software development are both paradigms for reducing complexity and for increasing abstraction and reuse in software development. In this thesis, we aim at combining the advantages of each by introducing methods from component-based development into MDSD. In MDSD, all artefacts that describe a software system are regarded as models of the system and are treated as the central development artefacts. To obtain a system implementation from such models, they are transformed and integrated until implementation code can be generated from them. Models in MDSD can have very different forms: they can be documents, diagrams, or textual specifications defined in different modelling languages. Integrating these models of different formats and abstraction in a consistent way is a central challenge in MDSD. We propose to tackle this challenge by explicitly separating the tasks of defining model components and composing model components, which is also known as distinguishing programming-in-the-small and programming-in-the-large. That is, we promote a separation of models into models for modelling-in-the-small (models that are components) and models for modelling-in-the-large (models that describe compositions of model components). To perform such component-based modelling, we introduce two architectural styles for developing systems with component-based MDSD (CB-MDSD). For CB-MDSD, we require a universal composition technique that can handle models defined in arbitrary modelling languages. A technique that can handle arbitrary textual languages is universal invasive software composition for code fragment composition. We extend this technique to universal invasive software composition for graph fragments (U-ISC/Graph) which can handle arbitrary models, including graphical and textual ones, as components. Such components are called graph fragments, because we treat each model as a typed graph and support reuse of partial models. To put the composition technique into practice, we developed the tool Reuseware that implements U-ISC/Graph. The tool is based on the Eclipse Modelling Framework and can therefore be integrated into existing MDSD development environments based on the framework. To evaluate the applicability of CB-MDSD, we realised for each of our two architectural styles a model-driven architecture with Reuseware. The first style, which we name ModelSoC, is based on the component-based development paradigm of multi-dimensional separation of concerns. The architecture we realised with that style shows how a system that involves multiple modelling languages can be developed with CB-MDSD. The second style, which we name ModelHiC, is based on hierarchical composition. With this style, we developed abstraction and reuse support for a large modelling language for telecommunication networks that implements the Common Information Model industry standard.

Modellgetriebene Softwareentwicklung

Komponentenbasierte Softwareentwicklung

Reuseware

Modellierung

Metamodellierung

Model-Driven Software Development

MDSD

MDA

Component-Based Software Development

Invasive Software Composition

ISC

Eclipse Modeling Framework

Reuseware

Eclipse

Meta-Object Facility

EMOF

Ecore

Modelling

Metamodelling

ddc:004

rvk:ST 230

Component-Based Model-Driven Software Development

Johannes, Jendrik

15 December 2010

Model-driven software development (MDSD) and component-based software development are both paradigms for reducing complexity and for increasing abstraction and reuse in software development. In this thesis, we aim at combining the advantages of each by introducing methods from component-based development into MDSD. In MDSD, all artefacts that describe a software system are regarded as models of the system and are treated as the central development artefacts. To obtain a system implementation from such models, they are transformed and integrated until implementation code can be generated from them. Models in MDSD can have very different forms: they can be documents, diagrams, or textual specifications defined in different modelling languages. Integrating these models of different formats and abstraction in a consistent way is a central challenge in MDSD. We propose to tackle this challenge by explicitly separating the tasks of defining model components and composing model components, which is also known as distinguishing programming-in-the-small and programming-in-the-large. That is, we promote a separation of models into models for modelling-in-the-small (models that are components) and models for modelling-in-the-large (models that describe compositions of model components). To perform such component-based modelling, we introduce two architectural styles for developing systems with component-based MDSD (CB-MDSD). For CB-MDSD, we require a universal composition technique that can handle models defined in arbitrary modelling languages. A technique that can handle arbitrary textual languages is universal invasive software composition for code fragment composition. We extend this technique to universal invasive software composition for graph fragments (U-ISC/Graph) which can handle arbitrary models, including graphical and textual ones, as components. Such components are called graph fragments, because we treat each model as a typed graph and support reuse of partial models. To put the composition technique into practice, we developed the tool Reuseware that implements U-ISC/Graph. The tool is based on the Eclipse Modelling Framework and can therefore be integrated into existing MDSD development environments based on the framework. To evaluate the applicability of CB-MDSD, we realised for each of our two architectural styles a model-driven architecture with Reuseware. The first style, which we name ModelSoC, is based on the component-based development paradigm of multi-dimensional separation of concerns. The architecture we realised with that style shows how a system that involves multiple modelling languages can be developed with CB-MDSD. The second style, which we name ModelHiC, is based on hierarchical composition. With this style, we developed abstraction and reuse support for a large modelling language for telecommunication networks that implements the Common Information Model industry standard.

info:eu-repo/classification/ddc/004

ddc:004