Abstract
We consider the distributed channel access problem for a system consisting of multiple control subsystems that close their loop over a shared wireless network. We propose a distributed method for providing deterministic channel access without requiring explicit information exchange between the subsystems. This is achieved by utilizing timers for prioritizing channel access with respect to a local cost which we derive by transforming the control objective cost to a form that allows its local computation. This property is then exploited for developing our distributed deterministic channel access scheme. A framework to verify the stability of the system under the resulting scheme is then proposed. Next, we consider a practical scenario in which the channel statistics are unknown. We propose learning algorithms for learning the parameters of imperfect communication links for estimating the channel quality and, hence, define the local cost as a function of this estimation and control performance. We establish that our learning approach results in collision-free channel access. The behavior of the overall system is exemplified via a proof-of-concept illustrative example, and the efficacy of this mechanism is evaluated for large-scale networks via simulations.
Highlights
Modern control environments involve various control loops, each containing numerous spatially distributed smart devices with sensing, actuating and computing capabilities
In Wireless Networked Control Systems (WNCSs), the wireless medium is used for information exchange between these devices, which greatly facilitates fast and easy deployments at lower installation and maintenance cost than their wired counterparts
The results presented are obtained by considering homogeneous WNCSs consisting of identical twowheeled balancing robots
Summary
Modern control environments involve various control loops, each containing numerous spatially distributed smart devices with sensing, actuating and computing capabilities. In Wireless Networked Control Systems (WNCSs), the wireless medium is used for information exchange between these devices, which greatly facilitates fast and easy deployments at lower installation and maintenance cost than their wired counterparts. Incorporating wireless channels in control loops introduces new challenges that need to be addressed for realizing the full potential of WNCSs [2]. One of the key challenges of WNCSs is the unreliable nature of wireless communication which leads to packet dropouts. In the seminal work [3], the impact of lossy communication links in control loops was thoroughly investigated. It was shown that the certainty equivalence principle holds as long as the adopted network protocols guarantee packet acknowledgements/negativeacknowledgements (ACK/NACKs).
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