Abstract
In novel collaborative systems, cooperative entities collaborate services to achieve local and global objectives. With the growing pervasiveness of cyber-physical systems, however, such collaboration is hampered by differences in the operations of the cyber and physical objects, and the need for the dynamic formation of collaborative functionality given high-level system goals has become practical. In this paper, we propose a cross-layer automation and management model for cyber-physical systems. This models the dynamic formation of collaborative services pursuing laid-down system goals as an ontology-oriented hierarchical task network. Ontological intelligence provides the semantic technology of this model, and through semantic reasoning, primitive tasks can be dynamically composed from high-level system goals. In dealing with uncertainty, we further propose a novel bridge between hierarchical task networks and Markov logic networks, called the Markov task network. This leverages the efficient inference algorithms of Markov logic networks to reduce both computational and inferential loads in task decomposition. From the results of our experiments, high-precision service composition under uncertainty can be achieved using this approach.
Highlights
Cyber-physical systems (CPSs) [1,2] currently offer the gateway to achieving synergy between the digital and physical worlds
In dealing with uncertainty, we propose a novel bridge between hierarchical task network (HTN) and Markov logic networks (MLN) [16] called the Markov task network (MTN)
In dealing with uncertainty in the datasets, we assumed a lack of certainty about the timing and nature of contexts from which high-level system goals are elicited
Summary
Cyber-physical systems (CPSs) [1,2] currently offer the gateway to achieving synergy between the digital and physical worlds. A cross-layer automation and management framework, which can represent both the cyber and physical components with high fidelity, is urgently needed. It is against this background that researchers in this field have made attempts towards new abstractions and architectures that can spur on novel techniques in the development and implementation of CPSs. Existing service-oriented architectures (SOAs) can achieve interoperable models that represent both the cyber and physical components [4,5]. As the components of CPSs increasingly grow apart, Sensors 2016, 16, 1542; doi:10.3390/s16091542 www.mdpi.com/journal/sensors
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