This book addresses mechanisms for reducing model heterogeneity induced by the absence of explicit semantics expression in the formal techniques used to specify design models. More precisely, it highlights the advances in handling both implicit and explicit semantics in formal system developments, and discusses different contributions expressing different views and perceptions on the implicit and explicit semantics. The book is based on the discussions at the Shonan meeting on this topic held in 2016, and includes contributions from the participants summarising their perspectives on the problem and offering solutions. Divided into 5 parts: domain modelling, knowledge-based modelling, proof-based modelling, assurance cases, and refinement-based modelling, and offers inspiration for researchers and practitioners in the fields of formal methods, system and software engineering, domain knowledge modelling, requirement analysis, and explicit and implicit semantics of modelling languages.
Les mer
Chapter 1: Modelling an e-voting domain for the formal development of a Software Product Line.- Chapter 2: Domain-specific Developments using Rodin Theories.- Chapter 3: Integrating Domain Knowledge in Formal Requirements Engineering.- Chapter 4: Operations over Lightweight Ontologies and their Implementation.- Chapter 5: Formal Ontological Analysis for Medical Protocol.- Chapter 6: Deriving Implicit Security Requirements in Safety-Explicit Formal Development of Control Systems.- Chapter 7: Towards an Integration of Probabilistic and Knowledge-Based Data Analysis Using Probabilistic Knowledge Patterns.- Chapter 8: An Explicit Semantics for Event-B Refinements.- Chapter 9: Contextual Dependency in State-based Modelling.- Chapter 10: Configuration of complex systems.- Chapter 11: Towards Making Safety Case Arguments Explicit, Precise, and Well Founded.- Chapter 12: The Indefeasibility Criterion for Assurance Cases.- Chapter 13: An Event-B development process for the distributed BIPframework.- Chapter 14: Explicit Exploration of Refinement Design in Proof-based Approach.- Chapter 15: Constructing Rigorous Sketches for Refinement-based Formal Development.
Les mer
This book addresses mechanisms for reducing model heterogeneity induced by the absence of explicit semantics expression in the formal techniques used to specify design models. More precisely, it highlights the advances in handling both implicit and explicit semantics in formal system developments, and discusses different contributions expressing different views and perceptions on the implicit and explicit semantics. The book is based on the discussions at the Shonan meeting on this topic held in 2016, and includes contributions from the participants summarising their perspectives on the problem and offering solutions. Divided into 5 parts: domain modelling, knowledge-based modelling, proof-based modelling, assurance cases, and refinement-based modelling, and offers inspiration for researchers and practitioners in the fields of formal methods, system and software engineering, domain knowledge modelling, requirement analysis, and explicit and implicit semantics of modelling languages.
Les mer
Provides an introduction to formal techniques for domain knowledge and formal system modelling Summarises the latest studies in handling explicit and implicit semantics in formal system development Reviews various approaches and lessons learnt in formal domain knowledge modelling in formal system formal developments
Les mer

Produktdetaljer

ISBN
9789811550539
Publisert
2020-07-28
Utgiver
Vendor
Springer Verlag, Singapore
Høyde
235 mm
Bredde
155 mm
Aldersnivå
Research, P, 06
Språk
Product language
Engelsk
Format
Product format
Innbundet

Biographical note

Yamine Ait Ameur is a professor at Toulouse National Polytechnique Institute and a member of the TCNRS IRIT Research Institute in Computer Science. His research topics concern 1) Formal methods for validation and verification, 2) Ontology-based modelling and domain knowledge explicitation, and 3) Application domains: embedded systems, interactive systems, semantic web, cyber-physical systems, and related topics. Two main important aspects characterize his research activities. On the one hand the fundamental aspects are studied through the use of formal modelling techniques based on refinement and proof (in particular, using Event-B), explicit formalisation of semantics employing formal ontology models. On the other hand, practical aspects are addressed through the development of operational applications, allowing validation of the proposed approaches. Embedded systems in avionics and railway systems, engineering, interactive systems, CO2 capture, and cyber physical systems are some of the application domains targeted by his work. He is the author of several research papers published in international journals and in the proceedings of international conferences. He is one of the main editors of the ISO 13584 International Standard Series, commonly known as PLib (Parts Libraries) for ontologies in system engineering.

Shin Nakajima is a professor at the National Institute of Informatics, Tokyo; an adjunct professor at the Graduate University for Advanced Studies; and a visiting professor at the Open University of Japan. His research topics concern formal methods, automated verification, assuring the quality of deep neural networks software, cyber-physical systems, and software-enabled innovation management. He has authored six books on those subjects.

Dominique Méry has been a full professor of computing science at the University of Lorraine since 1993 and is teaching in the School of Engineering in Information Technology TELECOM Nancy.  He isleading the research group MOSEL on formal methods and applications in LORIA, jointly with CNRS, INRIA, and the University of Lorraine. He has been a junior member of the Institut Universitaire de France IUF (1995–2000) and is a member of the IFIP WG 1.3 on foundations of specifications.  His current scientific activities a focus on proof-based development of distributed algorithms using the refinement, as well as modelling, of cyber physical systems as medical devices. His research uses mainly the modelling language B/Event-B and related platforms. He has led the IMPEX ANR project dealing with the integration of the explicit semantics in the proof-based development of software systems. Finally, his research explores the extension of the scope of discrete modelling techniques to handle the design and modelling of hybrid systems.