Anytime, anywhere: modal logics for mobile ambients
Proceedings of the 27th ACM SIGPLAN-SIGACT symposium on Principles of programming languages
Theoretical Computer Science
Formal Methods Application: An Empirical Tale of Software Development
IEEE Transactions on Software Engineering
Model checking mobile ambients
Theoretical Computer Science
Rewriting-Based Techniques for Runtime Verification
Automated Software Engineering
Event-based runtime verification of java programs
WODA '05 Proceedings of the third international workshop on Dynamic analysis
Combining test case generation and runtime verification
Theoretical Computer Science - Abstract state machines and high-level system design and analysis
Using formal specifications to support testing
ACM Computing Surveys (CSUR)
Formal specification of wireless and pervasive healthcare applications
ACM Transactions on Embedded Computing Systems (TECS)
Introduction to special section on formal methods in pervasive computing
ACM Transactions on Autonomous and Adaptive Systems (TAAS) - Special section on formal methods in pervasive computing, pervasive adaptation, and self-adaptive systems: Models and algorithms
Journal of Ambient Intelligence and Smart Environments - A software engineering perspective on smart applications for AmI
Formal verification of context and situation models in pervasive computing
Pervasive and Mobile Computing
A federated interoperability architecture for health information systems
International Journal of Internet Protocol Technology
Journal of Ambient Intelligence and Smart Environments
Knowledge-enabled decision making for robotic system utilizing ambient service components
Journal of Ambient Intelligence and Smart Environments - Ambient and Smart Component Technologies for Human Centric Computing
| Hi-index | 0.00 |
This article presents a methodology to formally express requirements in safety-critical ubiquitous and pervasive applications in order to achieve a higher degree of dependability. In particular, it will be shown how it is possible to formalize and constrict mobility characteristics by combining and extending several formal methods. The article also discusses some issues concerning both static and dynamic verification.