Opportunistic routing metrics: A timely one-stop tutorial survey

Abdollahi, Mostafa; Eshghi, Farshad; Kelarestaghi, Manoochehr; Bag-Mohammadi, Mozafar

doi:10.1016/j.jnca.2020.102802

Cited by 5 publications

(6 citation statements)

References 225 publications

(360 reference statements)

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“…Researchers have designed many routing metrics. Some of the popular are Expected Transmission Count (ETX) Metric [10], Expected Transmission Time (ETT) Metric [11], Weighted Cumulative Expected Transmission Time (WCETT) Metric [11], Load Aware Expected Transmission Time (LAETT) [14], Metric of Interference and Channel Switching (MIC) [12][13], Exclusive Expected Transmission Time (EETT) [15], Interference Load Aware (ILA) metric [16], Interference Aware Routing Metric (iAWARE) [17], Load Balancing Interference Aware Routing Metric (LBIARM) [18], Expected Dynamic Transmission Cost (EDTT) [19] and Physical layer Metric [20] for Internet of things [21] and Opportunistic routing metrics [22]. To evaluate the effect of routing metric on the performance of WMNs, we consider our metric with two popular metrics for our performance evaluation.…”

Section: Related Workmentioning

confidence: 99%

Impact Of Load Balancing Interference Routing Metric On Multi Channel Multi Radio Wireless Mesh Network

Siraj

Abbasi

2022

ITM Web Conf.

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Wireless Mesh Network (WMNs) is a promising technology that has been accepted favorably by the Internet Service Providers (ISPs). ISPs use it to provide last mile broadband Internet connectivity to the end users. This popularity arises from the fact, that it inter operates well with diverse wireless systems and provides robust fault tolerance with a high degree of redundancy and reliability. Routing metrics plays a crucial part in the performance of WMN. When routing protocols are implemented, the routing metric is assigned to different paths. It calculates the optimum path to predict the best routing path. These are integrated in routing protocols to improve WMNs efficiency in terms of reliability, latency, throughput, error rate and cost. This paper compares the impact of using load balancing interference aware routing metric (LBIARM) on the performance of Multi-Channel Multi Radio WMNs (MCMR WMNs). The performance of LBIARM was evaluated by comparing it with popular standard metrics weighted cumulative expected transmission time metric and Hop Count metric. OPNET Modeler 17.5 PL1 was used as a simulation tool for implementation. Simulation results show the effectiveness of using LBIARM metric on MCMR WMNs.

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Section: Related Workmentioning

confidence: 99%

Impact Of Load Balancing Interference Routing Metric On Multi Channel Multi Radio Wireless Mesh Network

Siraj

Abbasi

2022

ITM Web Conf.

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“…Because packets usually require multiple hops to reach the sink node, we calculate the multi-hop using the single-hop and the average of subsequent relay nodes. Therefore, if a sender node selects node in for data forwarding at time slot , the multihop is calculated by (11) as follows:…”

Section: B the Relay Set (Re)selection Stagementioning

confidence: 99%

“…The remaining nodes, that is, nodes 1, 2, and 3, constitute the actual forwarding set, . Then, the transmission cost for each node in is calculated by (11), and node 1 is assigned the highest priority for data forwarding because it obtains the smallest value of among all nodes in . In contrast to the sensor nodes in [12], which only adjust the transmission power at the end of each time slot, the sensor nodes in this study also adjust their transmission power and duty cycle, if necessary, in each time slot.…”

Section: B the Relay Set (Re)selection Stagementioning

confidence: 99%

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An Opportunistic Routing for Energy-Harvesting Wireless Sensor Networks With Dynamic Transmission Power and Duty Cycle

Ren

Yao

2022

IEEE Access

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Opportunistic routing (OR) is widely used in energy-harvesting wireless sensor networks (EH-WSNs). The transmission power of sensor nodes in EH-WSNs is usually adjusted dynamically to make full use of the harvested energy. Many OR algorithms with dynamic transmission power adjustment have been proposed for EH-WSNs. However, fewer studies consider the non-bidirectional communication and the increase in packet retransmission and delay caused by the heterogeneous transmission power/radii. To this end, we propose an opportunistic routing algorithm for EH-WSNs with dynamic transmission power and duty cycle (ORDPD). It adjusts the transmission power of the sensor nodes at the end of each time slot, according to the predicted available energy. It also adjusts the transmission power and duty cycle of the sensor nodes in time slots if the nodes receive packets from other nodes outside their current transmission range. ORDPD also adopts an improved transmission model and information exchange mechanism to dynamically update relay sets and forwarding paths. A series of experiments were conducted to verify the effectiveness of the proposed algorithm. The experimental results demonstrate that the proposed ORDPD reduces non-bidirectional communication and retransmission significantly and performs better than its corresponding competitors.

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“…The central control node, after receiving wireless nodes' reports, runs the NJS algorithm (subsection III-C) and compares the timeline of individual nodes using network topology information, such as transmission range and location of nodes, to infer jamming attacks. Similar to other well-known routing metrics in wireless networks [20], the reports could be delivered to the central node by flooding or unicasting methods in arbitrary time intervals (e.g. 0.5-1 minute).…”

Section: The Number Of Jammed Slots Metric a System Modelmentioning

confidence: 99%

An Efficient Metric for Physical-layer Jammer Detection in Internet of Things Networks

Abdollahi

Malekinasab

et al. 2021

2021 IEEE 46th Conference on Local Computer Networks (LCN)

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An active jammer could severely degrade the communication quality for wireless networks. Since all wireless nodes openly access the shared media, the harsh effects are exaggerated by retransmission attempts of affected devices. Fast and precise detection of the jammer is of vital importance for heterogeneous wireless environments such as the Internet of things (IoT). It could activate a series of corrective countermeasures to ensure the robust operation of the network. In this paper, we propose a local, straightforward, and numerical metric called the number of jammed slots (NJS), by which we can quickly detect the presence of a jammer and identify the jammed nodes at the software level in broadcast networks. NJS calculation is carried out by a central node which collects the MAC-layer statuses of all wireless nodes in a periodical fashion. Our simulation results indicate that NJS outperforms current detection methods in terms of accuracy and precision.

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Opportunistic routing metrics: A timely one-stop tutorial survey

Cited by 5 publications

References 225 publications

Impact Of Load Balancing Interference Routing Metric On Multi Channel Multi Radio Wireless Mesh Network

Impact Of Load Balancing Interference Routing Metric On Multi Channel Multi Radio Wireless Mesh Network

An Opportunistic Routing for Energy-Harvesting Wireless Sensor Networks With Dynamic Transmission Power and Duty Cycle

An Efficient Metric for Physical-layer Jammer Detection in Internet of Things Networks

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