FTPASC: A Fault Tolerant Power Aware Protocol with Static Clustering for Wireless Sensor Networks

Khadivi, Alireza; Shiva, M.

doi:10.1109/wimob.2006.1696382

Cited by 25 publications

(27 citation statements)

References 6 publications

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“…FTPASC is a fault tolerance routing algorithm that maximizes the life time of sensor network and increase the reliability of the network through electing two nodes with good properties, one act as an organizer node and the other as a cluster-head [3], the role of the organizer and cluster-head will be described briefly in the new proposed algorithm.…”

Section: Low-energy Adaptive Clustering Hierarchy (Leach)mentioning

confidence: 99%

“…The application of WSNs are tremendous and is using for several purposes such as military monitoring, environmental observation, weather checking, traffic control application, detecting location of pollutants, home automation applications, security issues and it has been used in the healthcare to improve the quality of the provided care [2,3,4,6,12,27] and is widely using in Internet of Things (IoT) [26].…”

Section: Introductionmentioning

confidence: 99%

“…Sensor nodes are correlated with their neighbor nodes and the collected data aggregated before send it to the base station. This can increase reliability of the sensed parameter and decrease the overhead [3,28]. Regarding that data gathering (routing) protocols should be utilized in an efficient way which takes into consideration the power consumption criteria.…”

Section: Introductionmentioning

confidence: 99%

“…The paper enhanced an energy balanced routing protocols by adding the fault tolerant mechanism, this done by combining two publish protocols which are: Energy Balanced Clustering EBC [4] and the Fault Tolerance Power Aware protocol with Static Clustering FTPASC [3]. Combining may produce a better protocol that maximizes the network life.…”

Section: Introductionmentioning

confidence: 99%

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EEBFTC: Extended Energy Balanced with Fault Tolerance Capability Protocol for WSN

Jamjoom¹

2017

ijacsa

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Abstract-This paper proposes a new framework for wireless sensor networks (WSN) by combining two routing protocol algorithms. In the proposed framework two algorithms are taking into consideration the energy balanced clustering (EBC) protocol in WSN with fault tolerance capabilities. The organizer is automatically selected by the base station (BS) and then it selects the cluster head (CH). The mechanism of selecting the organizer node and the cluster head (CH) is based on the power, efficacy and energy balance load. In addition, the organizer is responsible to select a new CH in case of failure and vice versa. So, the energy balanced clustering and fault tolerance operations will prolong the node life time and thus the network will be efficient in data transmission and more reliable. The new framework after implementation is named Extended Energy Balanced with Fault Tolerance Capability (EEBFTC) protocol.

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Section: Low-energy Adaptive Clustering Hierarchy (Leach)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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EEBFTC: Extended Energy Balanced with Fault Tolerance Capability Protocol for WSN

Jamjoom¹

2017

ijacsa

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“…However, the sensor nodes deployed in the adverse or inaccessible circumstances could be easily destroyed or out of order to be failure. Thus, how to remain the network connectivity even in fault-induced environments is an important issue [8][9]. Therefore, in fault-induced environments, the fault tolerance performance which to keep the WSN 3-connectivity with the deployment variations will be studied in this paper.…”

Section: Introductionmentioning

confidence: 99%

Fault Tolerance of Connectivity Performance in CDMA-Based Wireless Sensor Networks

Huang

Chen

et al.

Frontiers of High Performance Computing and Networking ISPA 2007 Workshops

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Abstract. In this paper, we investigate the fault tolerance of connectivity probability for CDMA-based wireless sensor networks with variations of nodes deployment. The variations of deployment are modeled by 2D Gaussian distribution with zero-mean for the triangle, grid and hexagon topologies. Thus, the k-connectivity performance is studied through the outage probability of CDMA signal links. We evaluate the connectivity performance with SIR 0,3-con , the minimum requirement of SIR, SIR 0 for the 3-connectivity, when the nodes suffer a failure rate P f . Simulation results show that the hexagonal and grid topologies suffer a degradation of -2.4 and -0.5 dB, respectively, when the failure rate P f equals 0.1. However, the triangular topology shows robust fault tolerance with the failure rate P f below 0.5 and moderate variations of deployment.

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Joint consideration of energy‐efficiency and coverage‐preservation in microsensor networks

Amini¹,

Vahdatpour²,

Dabiri³

et al. 2011

Wireless Communications

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This paper presents an energy-efficient and coverage-preserving communication protocol which distributes a uniform energy load to the sensors in a wireless microsensor network. This protocol, called Distance-based Segmentation (DBS), is a cluster-based protocol that divides the entire network into equal-area segments and applies different clustering policies to each segment to (1) reduce total energy dissipation and (2) balance the energy load among the sensors. Therefore, it prolongs the lifetime of the network and improves the sensing coverage. Moreover, the proposed routing protocol does not need any centralized support from a certain node which is at odds with aiming to establish a scalable communication protocol. Results from extensive simulations on two different network configurations show that by lowering the number of wasteful transmissions in the network, the DBS can achieve as much as a 20% reduction in total dissipated energy as compared with current cluster-based protocols. In addition, this protocol is able to distribute energy load more evenly among the sensors in the network. Hence, it yields up to a 66% increase in the useful network lifetime. According to the simulation results, the sensing coverage degradation of the DBS is considerably slower than that of the other cluster-based protocols. Copyright

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FTPASC: A Fault Tolerant Power Aware Protocol with Static Clustering for Wireless Sensor Networks

Cited by 25 publications

References 6 publications

EEBFTC: Extended Energy Balanced with Fault Tolerance Capability Protocol for WSN

EEBFTC: Extended Energy Balanced with Fault Tolerance Capability Protocol for WSN

Fault Tolerance of Connectivity Performance in CDMA-Based Wireless Sensor Networks

Joint consideration of energy‐efficiency and coverage‐preservation in microsensor networks

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