Cargando…

Model-driven engineering for distributed real-time systems : MARTE modeling, model transformations and their usages /

Model-based development methods, and supporting technologies, can provide the techniques and tools needed to address the dilemma between reducing system development costs and time, and developing increasingly complex systems. This book provides the information needed to understand and apply model-dr...

Descripción completa

Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Babau, Jean-Philippe
Formato: Electrónico eBook
Idioma:Inglés
Publicado: London : Hoboken, NJ : Iste ; Wiley, 2010.
Temas:
Acceso en línea:Texto completo (Requiere registro previo con correo institucional)
Tabla de Contenidos:
  • Cover; Model-Driven Engineering for Distributed Real-Time Systems; Title Page; Copyright Page; Table of Contents; Chapter Summary; Chapter 1. Model Transformation: A Survey of the State of the Art; 1.1. Model-driven engineering; 1.2. Model transformation; 1.2.1. Definitions; 1.2.2. Taxonomy; 1.3. Model transformation languages; 1.4. Model transformation activities; 1.5. Conclusion; 1.6. Acknowledgements; 1.7. Bibliography; Chapter 2. Model-Based Code Generation; 2.1. Introduction; 2.2. The model-driven architecture (MDA) process; 2.3. The automated approach to code generation
  • 2.4. Domain modeling2.5. The executable UML (xUML) formalism; 2.6. System generation; 2.7. Executable UML to code mappings; 2.8. Conclusions; 2.9. Bibliography; Chapter 3. Testing Model Transformations: A Case for Test Generation from Input Domain Models; 3.1. Introduction; 3.2. Challenges for testing systems with large input domains; 3.2.1. Large set of input data; 3.2.2. Configurable systems; 3.2.3. Grammarware and model transformations; 3.2.4. Testing challenges; 3.3. Selecting test data in large domains; 3.3.1. Category partition; 3.3.2. Combinatorial interaction testing
  • 3.4. Metamodel-based test input generation3.4.1. Metamodel coverage criteria; 3.4.2. Model and object fragments for test adequacy criteria; 3.4.3. Discussion; 3.4.4. Automatic synthesis of test models; 3.5. Conclusion; 3.6. Acknowledgements; 3.7. Bibliography; Chapter 4. Symbolic Execution-Based Techniques for Conformance Testing; 4.1. Context; 4.1.1. Conformance testing: an introduction; 4.1.2. Conformance relation; 4.1.3. An overview of the approach; 4.2. Input output symbolic transition systems; 4.2.1. Data types; 4.2.2. Input/output symbolic transition systems; 4.2.3. Semantics
  • 4.3. Symbolic execution4.4. Conformance testing for IOSTS; 4.4.1. Test purposes; 4.4.2. Preliminary definitions and informal description; 4.4.3. Inference rules; 4.5. Concluding remarks; 4.5.1. Choosing test purposes; 4.5.2. Implementation issues; 4.6. Bibliography; Chapter 5. Using MARTE and SysML for Modeling Real-Time Embedded Systems; 5.1. Introduction; 5.2. Background; 5.2.1. UML profiling capabilities; 5.2.2. SysML and MARTE modeling capabilities; 5.3. Scenarios of combined usage; 5.3.1. Defining architecture frameworks; 5.3.2. Requirements engineering
  • 5.3.3. System-level design integration5.3.4. Engineering/quantitative analysis; 5.4. Combination Strategies; 5.4.1. Issues; 5.4.2. Strategies; 5.5. Related work; 5.6. Conclusion; 5.7. Acknowledgements; 5.8. Bibliography; Chapter 6. Software Model-based Performance Analysis; 6.1. Introduction; 6.2. Performance models; 6.2.1. Queuing network models; 6.2.2. Layered queuing network model; 6.3. Software model with performance annotations; 6.3.1. Performance domain model; 6.3.2. Source model example; 6.4. Mapping from software to performance model