347 research outputs found
Non-null Infinitesimal Micro-steps: a Metric Temporal Logic Approach
Many systems include components interacting with each other that evolve with
possibly very different speeds. To deal with this situation many formal models
adopt the abstraction of "zero-time transitions", which do not consume time.
These however have several drawbacks in terms of naturalness and logic
consistency, as a system is modeled to be in different states at the same time.
We propose a novel approach that exploits concepts from non-standard analysis
to introduce a notion of micro- and macro-steps in an extension of the TRIO
metric temporal logic, called X-TRIO. We use X-TRIO to provide a formal
semantics and an automated verification technique to Stateflow-like notations
used in the design of flexible manufacturing systems.Comment: 20 pages, 2 figures, submitted to the conference "FORMATS: Formal
Modelling and Analysis of Timed Systems" 201
Discrete Simulation of Behavioural Hybrid Process Calculus
Hybrid systems combine continuous-time and discrete behaviours. Simulation is one of the tools to obtain insight in dynamical systems behaviour. Simulation results provide information on performance of system and are helpful in detecting potential weaknesses and errors. Moreover, the results are handy in choosing adequate control strategies and parameters. In our contribution we report a work in progress, a technique for simulation of Behavioural Hybrid Process Calculus, an extension of process algebra that is suitable for the modelling and analysis of hybrid systems
Simulator Semantics for System Level Formal Verification
Many simulation based Bounded Model Checking approaches to System Level
Formal Verification (SLFV) have been devised. Typically such approaches exploit
the capability of simulators to save computation time by saving and restoring
the state of the system under simulation. However, even though such approaches
aim to (bounded) formal verification, as a matter of fact, the simulator
behaviour is not formally modelled and the proof of correctness of the proposed
approaches basically relies on the intuitive notion of simulator behaviour.
This gap makes it hard to check if the optimisations introduced to speed up the
simulation do not actually omit checking relevant behaviours of the system
under verification.
The aim of this paper is to fill the above gap by presenting a formal
semantics for simulators.Comment: In Proceedings GandALF 2015, arXiv:1509.0685
Refinement-based verification of sequential implementations of Stateflow charts
Simulink/Stateflow charts are widely used in industry for the specification
of control systems, which are often safety-critical. This suggests a need for a
formal treatment of such models. In previous work, we have proposed a technique
for automatic generation of formal models of Stateflow blocks to support
refinement-based reasoning. In this article, we present a refinement strategy
that supports the verification of automatically generated sequential C
implementations of Stateflow charts. In particular, we discuss how this
strategy can be specialised to take advantage of architectural features in
order to allow a higher level of automation.Comment: In Proceedings Refine 2011, arXiv:1106.348
A temporal logic for micro- and macro-step-based real-time systems: Foundations and applications
Many systems include components interacting with each other that evolve at possibly very different speeds. To deal with this situation many formal models adopt the abstraction of āzero-time transitionsā, which do not consume time. These, however, have several drawbacks in terms of naturalness and logic consistency, as a system is modeled to be in different states at the same time. We propose a novel approach that exploits concepts from non-standard analysis and pairs them with the traditional ānextā operator of temporal logic to introduce a notion of micro- and macro-steps; our approach is enacted in an extension of the TRIO metric temporal logic, called X-TRIO. We study the expressiveness and decidability properties of the new logic. Decidability is achieved through translation of a meaningful subset of X-TRIO into Linear Temporal Logic, a traditional way to support automated verification. We illustrate the usefulness and the generality of our approach by applying it to provide a formal semantics of timed Petri nets, which allows for their automated verification. We also give an overview of a formal semantics of Stateflow/Simulink diagrams, defined in terms of X-TRIO, which has been applied to the automated verification of a robotic cell
Model Based Analysis and Test Generation for Flight Software
We describe a framework for model-based analysis and test case generation in the context of a heterogeneous model-based development paradigm that uses and combines Math- Works and UML 2.0 models and the associated code generation tools. This paradigm poses novel challenges to analysis and test case generation that, to the best of our knowledge, have not been addressed before. The framework is based on a common intermediate representation for different modeling formalisms and leverages and extends model checking and symbolic execution tools for model analysis and test case generation, respectively. We discuss the application of our framework to software models for a NASA flight mission
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