Wireless Sensor Network Modeling and Deployment Challenges in Oil and Gas Refinery Plants

Savazzi, Stefano; Guardiano, Sergio; Spagnolini, Umberto

doi:10.1155/2013/383168

Cited by 41 publications

(34 citation statements)

References 41 publications

(78 reference statements)

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“…Looking at the dual problem of optimal wireless node deployment, different strategies have been considered in the literature for targeting connectivity, coverage, node lifetime, and/or QoS [2]. However, the majority of published work on sensor network deployment limits its focus on simplified and analytically tractable 1D and 2D environments where connectivity can be considered as a primary/secondary objective or as a constraint in the deployment problem [6].…”

Section: Related Workmentioning

confidence: 99%

“…Although several models have been proposed in the literature, e.g., see [17] for reviewing, these cannot fully capture the unique propagation characteristics of industrial environments. In addition, most of conventional ray-tracing tools turn out not to be practical to process the high number of structures and their complexity in large industrial sites [2]. This motivates the development of accurate site-specific channel models based on a set of measurements taken in typical industrial sites.…”

Section: Modeling Of Short-range Propagationmentioning

confidence: 99%

“…It adopts the propagation model proposed in [2], which suggests using the 3D model of the plant to classify the links based on the number and the density of the surrounding obstructions. The paper also discusses how the coexistence of different wireless networks might affect this model.…”

mentioning

confidence: 99%

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Network design and planning of wireless embedded systems for industrial automation

Souza

Savazzi

Becker

2015

Des Autom Embed Syst

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The widespread adoption of wireless systems for industrial automation calls for the development of efficient tools for virtual planning of network deployments similarly as done for conventional Fieldbus and wired systems. In industrial sites the radio signal propagation is subject to blockage due to highly dense metallic structures. Network planning should therefore account for the number and the density of the 3D obstructions surrounding each link. In this paper we address the problem of wireless node deployment in wireless industrial networks, with special focus on WirelessHART IEC 62591 and ISA SP100 IEC 62734 standards. The goal is to optimize the network connectivity and develop an effective tool that can work in complex industrial sites characterized by severe obstructions. The proposed node deployment approach is validated through a case study in an oil refinery environment. It includes an ad-hoc simulation environment (RFSim tool) that implements the proposed network planning approach using 2D models of the plant, providing connectivity information based on user-defined deployment configurations. Simulation results obtained using the proposed simulation environment were validated by on-site measurements.

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Section: Related Workmentioning

confidence: 99%

Section: Modeling Of Short-range Propagationmentioning

confidence: 99%

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Network design and planning of wireless embedded systems for industrial automation

Souza

Savazzi

Becker

2015

Des Autom Embed Syst

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“…The configuration of the primary routing path is optimized as it is based on radio planning. In complex environments like refinery or power plants, the use of the 3D model during the design phase is also crucial to maximize radio-planning accuracy in order to limit any rework to a percentage which is in line with a regular installation of a wired system [15].…”

Section: Medium Access Control Sublayermentioning

confidence: 99%

“…Today, commercial battery-operated systems are based on the IEEE 802. 15.4 standard and enable data to be transmitted at a typical rate of 250 kbit/s (and scaling up to 2 Mbit/s by disabling direct-sequence spread spectrum functions), with up to a maximum of 10 dBm output RF power to meet the RF regulations for hazardous environments. The IEEE 802.15.4 physical layer also constitutes the basis for the wireless HART [7] and ISA100.11a [8] industry standard protocols.…”

Section: Introductionmentioning

confidence: 99%

Wireless Virtual Multiple Antenna Networks for Critical Process Control: Protocol Design and Experiments

Savazzi

2013

International Journal of Distributed Sensor Networks

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Wireless telemetry systems for remote monitoring and control of industrial processes are now becoming a relevant topic in the field of networked control. Wireless closed-loop control systems have stricter delay and link reliability requirements compared to conventional sensor networks for open-loop monitoring and call for the development of advanced network architectures. By following the guidelines introduced by recent standardization, this paper focuses on the most recent technological advances to enable wireless networked control for tight closed-loop applications with cycle times below 100 ms. The cooperative network paradigm is indicated as the key technology to enable cable replacing even in critical control applications. A cooperative communication system enables wireless devices placed at geographically separated locations to act as a virtual ensemble of antennas that creates a virtual multiple-antenna-distributed system. A proprietary link-layer protocol/based on the IEEE 802.15.4 physical layer has been developed and tested in an indoor environment characterized by non-line-of-sight (NLOS) propagation and dense obstacles. The measurements obtained from the testbed evaluate experimentally the benefits (and the limitations) of cable replacing in critical process control.

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Aerial Robotic System for Complete Bridge Inspections

Viguria

Caballero

Petrus

et al. 2022

Sustainable Civil Infrastructures

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Bridge inspections have a large variety of procedures to ensure the safety of its facilities and personnel, and at the same time tightly budget constraints. These procedures involve extensive inspections, most of which should be performed at height and using both cameras and other sensors that require to be in contact with the surfaces being inspected. Then, bridge inspections traditionally require access to specific inspection points using man-lifts, cranes, scaffolds, or ropeaccess techniques, which increments importantly the costs of these inspections. This work will present a system formed by two drones that will perform complete inspection operations in bridges in less time, reducing costs, improving quality of the inspection, and increasing safety of operators. The first one is an aerial robot that can obtain pictures of the overall bridge fully autonomously thanks to a GPS-free navigation system. The second one is the AeroX drone platform, a novel solution for inspection of difficult access areas. The AeroX can perform contact inspection due to its robotic contact device, which is equipped with an end-effector. Finally, both drones will be presented with videos of the validation experiments.

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Wireless Sensor Network Modeling and Deployment Challenges in Oil and Gas Refinery Plants

Cited by 41 publications

References 41 publications

Network design and planning of wireless embedded systems for industrial automation

Network design and planning of wireless embedded systems for industrial automation

Wireless Virtual Multiple Antenna Networks for Critical Process Control: Protocol Design and Experiments

Aerial Robotic System for Complete Bridge Inspections

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