Providing Self-Healing Ability for Wireless Sensor Node by Using Reconfigurable Hardware

Yuan, Shenfang; Qiu, Lei; Gao, Shang; Yao, Tong; Yang, Weiwei

doi:10.3390/s121114570

Cited by 15 publications

(8 citation statements)

References 32 publications

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“…A number of approaches have been proposed to induce the capability to be self-healed to any link breakage. As per Yuan et al (2012), field-programmable analog array (FPAA)-/field-programmable gate array (FPGA)-based hardware solution is proposed so that wireless sensor nodes can self-diagnose the failures and recover to a normal state automatically. Vlajic and Moniz (2007) have proposed a solution for bridging a routing hole by means of a mobile robot.…”

Section: Introductionmentioning

confidence: 99%

Detection and self-healing of cluster breakages in mines and tunnels: an empirical investigation

et al. 2015

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Purpose -The study aims at providing a reliable system of real-time monitoring for underground mine and tunnels which detects any structural change in the network and reconfigures it for resuming the data delivery process. In high stress environments, e.g. underground mines and tunnels, real-time activity monitoring is an emerging issue. Wireless sensor networks (WSNs) play a key role in ensuring the safety of people working in underground mines and tunnels. WSN not only provide real-time monitoring of underground environment but also detects any structural change in the network itself. Design/methodology/approach -In this paper, results of empirical implementation of a re-configurable WSN, capable of self-healing approach, reconfigure the network connectivity upon failure or addition of nodes in the system. An open-source radio-frequency identification standard for WSN, named as DASH7, is used for practical implementation. The proposed system is capable of determining cluster breakage by sudden disruptions caused by roof falls, explosions and node failures, sensor coverage hole, node re-addition to the network and distress priority signal generation by the miner. Findings -The proposed platform contributes to re-attain network state for establishing a communication link with fusion center in terms of: instant and accurate detection of collapse holes, acceptable error rate, time to re-attain network state, rapid distress signal propagation and low deployment cost. This platform is deployed in four different environments of anechoic chamber, hallway, outdoor and underground mine environment, to test the aforementioned scenarios using DASH7-compatible Bitsense Sensor Motes operating at 433 MHz. The effectiveness of the proposed approach has been experimentally validated for the single and multiple adjacent and disjoint node failures in all the four environments. Originality/value -The number of monitoring systems was implemented for safety assurance in high stress environments before, but the novelty of our platform is long range, cost effectiveness, quick response to any structural change in the network, rapid and accurate data delivery using WSN operated on DASH7 protocol stack.

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Section: Introductionmentioning

confidence: 99%

Detection and self-healing of cluster breakages in mines and tunnels: an empirical investigation

et al. 2015

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“…The traditional approach to provide multi sensor capability for a WSN node is by employing several signal conditioning stages to the front end of the circuit where every sensor interface is dedicated to a certain sensor type. Compared to traditional hardware design topologies, reconfigurable hardware designs have shown a certain improvement of designing more flexible devices [2]. Field programmable gate array (FPGA) based designs are more popular for digital sensors, though they require additional components to facilitate multi sensing operation in mixed signal domain [3].…”

Section: Introductionmentioning

confidence: 99%

Reconfigurable Wireless Sensor Node with Improved Autonomous Linearization

Ranasinghe

2015

Int J on Adv. in ICT for Emerging Countries

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The usage of reconfigurable hardware in wireless sensor networks plays an important role which enables multi parameter estimation in complex environments. The need for vast sensor compatibility and sensor fusion will become crucial requirements as wireless sensor networks become autonomous and intelligent. Due to the non linear behaviour of sensors and analogue circuitry in the front end, such applications often require a rigorous software model to perform sensor linearization for best accuracy. This paper presents an implementation of a reconfigurable wireless sensor node based on a CMOS analogue multiplexer network supporting universal functions for different industrial sensors while being compact and energy efficient, which is conducive to wireless sensor networking. Further an accurate optimized and autonomous linearization technique based on rational interpolation is also presented in order to compensate non idealities of the sensor node. The concept, simulation results, prototype implementation with industrial components and the results of system integration are discussed in this paper to illustrate potential applications in mass scale data acquisition based on wireless sensor networks.

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“…Nowadays, WSNs are used in harsh environments, such as underground mines, oceans, tunnels and outer space [3,5,6]. Wireless communication in harsh environments has many challenges, such as channel (edge) failures, generally, as a consequence of the direct impact of the physical world.…”

Section: Introductionmentioning

confidence: 99%

Breadth-First Search-Based Single-Phase Algorithms for Bridge Detection in Wireless Sensor Networks

Akram

Dağdeviren

2013

Sensors

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Wireless sensor networks (WSNs) are promising technologies for exploring harsh environments, such as oceans, wild forests, volcanic regions and outer space. Since sensor nodes may have limited transmission range, application packets may be transmitted by multi-hop communication. Thus, connectivity is a very important issue. A bridge is a critical edge whose removal breaks the connectivity of the network. Hence, it is crucial to detect bridges and take preventions. Since sensor nodes are battery-powered, services running on nodes should consume low energy. In this paper, we propose energy-efficient and distributed bridge detection algorithms for WSNs. Our algorithms run single phase and they are integrated with the Breadth-First Search (BFS) algorithm, which is a popular routing algorithm. Our first algorithm is an extended version of Milic's algorithm, which is designed to reduce the message length. Our second algorithm is novel and uses ancestral knowledge to detect bridges. We explain the operation of the algorithms, analyze their proof of correctness, message, time, space and computational complexities. To evaluate practical importance, we provide testbed experiments and extensive simulations. We show that our proposed algorithms provide less resource consumption, and the energy savings of our algorithms are up by 5.5-times.

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Providing Self-Healing Ability for Wireless Sensor Node by Using Reconfigurable Hardware

Cited by 15 publications

References 32 publications

Detection and self-healing of cluster breakages in mines and tunnels: an empirical investigation

Detection and self-healing of cluster breakages in mines and tunnels: an empirical investigation

Reconfigurable Wireless Sensor Node with Improved Autonomous Linearization

Breadth-First Search-Based Single-Phase Algorithms for Bridge Detection in Wireless Sensor Networks

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