Modeling concurrency with partial orders
International Journal of Parallel Programming
Trace algebra for automatic verification of real-time concurrent systems
Trace algebra for automatic verification of real-time concurrent systems
CONCUR '00 Proceedings of the 11th International Conference on Concurrency Theory
Assume-Guarantee Reasoning for Hierarchical Hybrid Systems
HSCC '01 Proceedings of the 4th International Workshop on Hybrid Systems: Computation and Control
Masaccio: A Formal Model for Embedded Components
TCS '00 Proceedings of the International Conference IFIP on Theoretical Computer Science, Exploring New Frontiers of Theoretical Informatics
Overcoming Heterophobia: Modeling Concurrency in Heterogeneous Systems
ACSD '01 Proceedings of the Second International Conference on Application of Concurrency to System Design
Process spaces and formal verification of asynchronous circuits
Process spaces and formal verification of asynchronous circuits
A framework for comparing models of computation
IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems
Platform based design for wireless sensor networks
Mobile Networks and Applications
Research trends in real-time computing for embedded systems
ACM SIGBED Review - Special issue on major international initiatives on real-time and embedded systems
Refinement preserving approximations for the design and verification of heterogeneous systems
Formal Methods in System Design
Model-driven architecture for embedded software: A synopsis and an example
Science of Computer Programming
Exploring Multi-Paradigm Modeling Techniques
Simulation
Embedded Systems Design
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The methodologies that are in use today for software development rely on representations and techniques appropriate for the applications (compilers, business applications, CAD, etc.) that have been traditionally implemented on programmable processors. Embedded software is different: by virtue of being embedded in a surrounding system, the software must be able to continuously react to stimula in the desired way. Verifying the correctness of the system requires that the model of the software be transformed to include (refine) or exclude (abstract) information to retain only what is relevant to the task at hand. In this paper, we outline a framework that we inted to use for studying the problems of abstraction and refinement in the context of embedded software for hybrid systems.