Self-Correcting Localization Scheme for Vehicle to Vehicle Communication

Mageid, Salah Abdel

doi:10.22247/ijcna/2016/48829

Cited by 7 publications

(5 citation statements)

References 18 publications

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“…The simulation experiments of the proposed HCSGWOA-NLOS-PS and the benchmarked approaches are conducted and validated using EstiNet 8.1 Simulator. [37][38][39][40][41][42][43][44] The simulation parameters considered for implementing the proposed HCSGWOA-NLOS-PS and the benchmarked WI-CLOSPS-DVBA, 23 CS-NLOSSL-CIC, 25 WDHP-NLOS-PS, 22 and CVN-NLOS-PS 21 schemes are kept constant throughout the simulation. 17,[45][46][47][48][49] They are implemented with the same environment, traffic condition and mobility model.…”

Section: Simulation Results and Discussionmentioning

confidence: 99%

A Hybrid Crow Search and Gray Wolf Optimization Algorithm‐based Reliable Non‐Line‐of‐Sight Node Positioning Scheme for Vehicular Ad hoc Networks

Malar¹,

Priya²,

Janakiraman³

2020

Int J Communication

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Summary Vehicular Ad hoc NETwork (VANET) facilitates ubiquitous connectivity for establishing Vehicle‐to‐Vehicle (V2V) communication and supporting Intelligent Transportation Systems (ITSs). This vehicle communication requires complete coverage within the target range for ensuring reliable message dissemination. High density of vehicles in the intersections introduces challenges due to obstacles such as buildings, foliage, and other moving vehicles, preventing exchange of information about location and message update between vehicles. Non‐Line‐of‐Sight (NLOS) nodes also introduce broadcasting storm problem leading to congestion that prevents emergency messages from reaching the target vehicular nodes. Integration of meta‐heuristic Crow Search Algorithm (CSA) and Gray Wolf Optimization Algorithm (GWOA) minimizes the objective function of NLOS localization problem without the solution being trapped into local optima. In this paper, a Hybrid Crow Search and GWOA‐based NLOS Positioning Scheme (HCSGWOA‐NLOS‐PS) is proposed to handle the issue of broadcast storm and facilitate reliability in emergency message delivery. The proposed HCSGWOA‐NLOS‐PS utilizes the benefits of Time of Arrival (ToA) and geographical information‐based cooperative localization agent for attaining efficient NLOS node positioning in the network. It uses the benefits of CSA and GWOA for positioning the NLOS nodes based on the intelligence derived from the crows' conduit and the social attacking behavior of gray wolves that are ideal for balancing the tradeoff between exploration and exploitation. The simulation results of the proposed HCSGWOA‐NLOS‐PS confirm a mean emergency message delivery of 11.82%, neighborhood awareness of 12.38% with reduced localization error rate of 2.36% and minimized delay of 8.64% when compared to the baseline approaches.

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Section: Simulation Results and Discussionmentioning

confidence: 99%

A Hybrid Crow Search and Gray Wolf Optimization Algorithm‐based Reliable Non‐Line‐of‐Sight Node Positioning Scheme for Vehicular Ad hoc Networks

Malar¹,

Priya²,

Janakiraman³

2020

Int J Communication

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“…Though three RNs are discovered, a small measurement error due to rapid change in the network topology leads to poor localization accuracy. The work in [15] has studied the effect of vehicular ad-hoc network topology in free space environments on node localization. Connectivity based localization (i.e., Monte Carlo localization) can solve those problems.…”

Section: Research Articlementioning

confidence: 99%

“…The centroid of filtered samples that represents the estimate position of VN(j) at the current t is determined. Two values are stored for the next time slot, the value of estimated location and the current speed reading as shown in Lines (15,16). In what follows, simulation results are introduced which the performance of COPO system is compared to existing Monte Carlo schemes such as MCL [16] and VMCB [21].…”

Section: Explanation Of Remark 44mentioning

confidence: 99%

Connectivity Based Positioning System for Underground Vehicular Ad Hoc Networks

Mageid¹

2017

ijcna

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-Underground vehicular ad-hoc networks are indorsing wireless networks because they can realize many goals such as improving the driving safety and monitoring the emergency alerts in underground environments (i.e., road tunnels). It is necessary for vehicular nodes to recognize their positions to achieve these goals. However, Global Positioning System (GPS) devices cannot operate in underground environments; furthermore, the signal propagation faces many effects such as attenuation, multipath and shadow fading. Traditional distance measurement techniques are inadequate to estimate vehicular node locations in underground environments because the expected measurement errors lead to poor positioning. In this paper, the network connectivity is exploited to estimate vehicular node positions instead of radio ranging methods. This work investigates one of the most important techniques that are based on the network connectivity (i.e., Monte Carlo) and proposes new heuristics that achieve an appropriate position estimation accuracy for vehicular nodes. As the underlying method is predictable, it enables these nodes to know their positions all the time inside underground environments. In addition, an efficient deployment strategy is proposed in this work to well organize reference nodes (i.e., fixed nodes that their positions are preconfigured) inside a road tunnel. The proposed scheme performance is verified by NS2 simulator and compared with the current Monte Carlo localization schemes where the simulation results indicate the superiority of the proposed scheme.

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“…Nowadays, vehicular ad-hoc networks (VANET) take place in research topics [1][2][3][4][5][6]. Mobility management is an important issue in VANET.…”

Section: Introductionmentioning

confidence: 99%

“…While handoff latency in HI-NEMO includes the time from notifying MR at AR 1 till recognition of MR in SW, that is suitable for the vehicle path. HO_NEMO = T l2 +T l3(1) As shown in Figure3, L3 handover delay consists of: Movement Detection delay T MD ; which equal 2 , Duplicate Address Detection delay T DAD and Registration delay T REG[15,16].…”

mentioning

confidence: 99%

Mobility Management Scheme Based on Smart Buffering for Vehicular Networks

Mohammed¹,

El-Moafy²,

Abdel-Mageid³

et al. 2017

ijcna

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Mobility management in vehicular networks is our case study is to provide internet connectivity without any interruption and with no packet loss, even in V2I (Vehicular to Infrastructure) or V2V (Vehicular to Vehicular) communications. Handover delay is one of critical parameters in QoS measurements in addition to packet loss, throughput and data transmission delay. In this paper, the idea of Smart Buffering is proposed to enhance HI-NEMO protocol. In this extension of NEMO, the combining cross-layer mechanism and resource allocation have been performed. It is used to reduce latency and packet loss during handovers with high performance in its proactive mode. However, it is noticed that packets loss exists in its reactive mode during the period of link down in small coverage cell radius of base station during vehicle movement. Smart Buffering mechanism mostly prevents packet loss by buffering lost candidate packets in Root FMA (Foreign Mobile Agent), forwarding and reordering it in new FMA. It also performs redundant packet removing in Root FMA. Mathematical analysis proves that Enhanced HI-NEMO protocol prevents packet loss during reactive handover and gives optimal throughput with supporting high velocity vehicles.

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Self-Correcting Localization Scheme for Vehicle to Vehicle Communication

Cited by 7 publications

References 18 publications

A Hybrid Crow Search and Gray Wolf Optimization Algorithm‐based Reliable Non‐Line‐of‐Sight Node Positioning Scheme for Vehicular Ad hoc Networks

A Hybrid Crow Search and Gray Wolf Optimization Algorithm‐based Reliable Non‐Line‐of‐Sight Node Positioning Scheme for Vehicular Ad hoc Networks

Connectivity Based Positioning System for Underground Vehicular Ad Hoc Networks

Mobility Management Scheme Based on Smart Buffering for Vehicular Networks

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