A stochastic vehicle mobility model with environmental condition adaptation capability

Momen, Amir Reza; Azmi, Paeiz

doi:10.1002/wcm.664

Cited by 6 publications

(4 citation statements)

References 13 publications

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“…2) Vehicular Mobility Model (VMM): V2X communications have great potential to enable future intelligent applications, such as smart cities and intelligent transport systems, and exploiting vehicle mobility is of great importance in designing efficient V2X protocols and applications [80], [83], [103], [104]. By now, researchers have understood the main features in various V2X scenarios and have built novel VMMs [79], [105], [106]. Based on the characteristics of models and the priorities of different applications, VMMs can be categorized into the following cases.…”

Section: Ship Mobility Modelmentioning

confidence: 99%

“…However, these models are capable of capturing the stochastic nature of traffic arrivals as well as the complicated movements of vehicles in an ITS [107]. The stochastic vehicle mobility model of [105] considered the direction and velocity of the user mobility and was capable of adapting to the traffic condition and type of the street. The work [108] emulated the network throughput with the Manhattan model, and the study [109] leveraged a stochastic VMM in the dynamic optimization of D2D communications.…”

Section: Ship Mobility Modelmentioning

confidence: 99%

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Mobility Support for Millimeter Wave Communications: Opportunities and Challenges

Li¹,

Niu²,

Wu³

et al. 2022

Preprint

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Millimeter-wave (mmWave) communication technology offers a potential and promising solution to support 5G and B5G wireless networks in dynamic scenarios and applications. However, mobility introduces many challenges as well as opportunities to mmWave applications. To address these problems, we conduct a survey of the opportunities and technologies to support mmWave communications in mobile scenarios. Firstly, we summarize the mobile scenarios where mmWave communications are exploited, including indoor wireless local area network (WLAN) or wireless personal area network (WPAN), cellular access, vehicle-to-everything (V2X), high speed train (HST), unmanned aerial vehicle (UAV), and the new space-airground-sea communication scenarios. Then, to address users' mobility impact on the system performance in different application scenarios, we introduce several representative mobility models in mmWave systems, including human mobility, vehicular mobility, high speed train mobility and ship mobility. Next we survey the key challenges and existing solutions to mmWave applications, such as channel modeling, channel estimation, antiblockage, and capacity improvement. Lastly, we discuss the open issues concerning mobility-aware mmWave communications that deserve further investigation. In particular, we highlight future heterogeneous mobile networks, dynamic resource management, artificial intelligence (AI) for mobility and integration of geographical information, deployment of large intelligent surface and reconfigurable antenna technology, and finally, the evolution to Terahertz (THz) communications.

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Section: Ship Mobility Modelmentioning

confidence: 99%

Section: Ship Mobility Modelmentioning

confidence: 99%

Mobility Support for Millimeter Wave Communications: Opportunities and Challenges

Li¹,

Niu²,

Wu³

et al. 2022

Preprint

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“…The most common car mobility models were classified into four categories in Reference 31: stochastic models (vehicles movement follows casual paths in the grid at randomly chosen speed), traffic stream models (traffic seen from a macroscopic point of view and modeled by fluid dynamics equations), car‐following models (the position, speed, and acceleration of vehicles are determined by the state of surrounding vehicles), flows‐interaction models (extending any of the previous models with specific behavior at intersections, e.g., considering the effects of traffic lights and crossing streams). We may add cellular automata models , such as the one recently proposed in Reference 32, or multi‐level models 33, which do not fall in these categories. The impact of the mobility model on connectivity metrics, such as link duration , nodal degree , size of clusters , and clustering coefficient (ratio of the effective number of links in the cluster over the number of links in the corresponding complete graph), was studied in Reference 31 for several models from the four above categories.…”

Section: Modeling Vehicular Networkmentioning

confidence: 99%

Communication protocols for vehicular ad hoc networks

Casteigts¹,

Nayak²,

Stojmenović³

2011

Wireless Communications

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SummaryVehicular networks are envisioned for large scale deployment, and standardization bodies, car manufacturers and academic researchers are solving a variety of related challenges. After a brief description of intelligent transportation system architectures and the main already-established low-level standards, this tutorial elaborates on four particular aspects of vehicular networks, which are i) the potential for a large set of innovative applications, ii) a review of the main modeling approaches used for both roads and traffic, and finally two important communication primitives, that are iii) data dissemination via broadcasting/geocasting, and iv) routing in both highway and urban environments. A particular emphasis is on recent protocols that realistically consider the inherently complex nature of vehicular mobility, such as intermittent connectivity, speed variability, and the impact of intersections.

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“…Prioritization method for combining bandwidth borrowing and reservation with mentoring the rate-adaptiveness of ongoing calls in cell [6] and an efficient channel allocation scheme for mobile cellular networks can be performed [7][8]. Stochastic vehicle mobility with environmental condition adaption capability analysis in [9], and dynamic optimiz-ing the QoS of high speed moving terminals and handoff calls in cellular networks was discussed in [10]. The effect of different mobility patterns on the handoff probability was studied in [11].The purpose of this paper is to present evaluation of handoff probabilities of traffic in next generation of high speed wireless mobile networks.…”

Section: Introductionmentioning

confidence: 99%

An Analytical Approach for Mobility Load Balancing in Wireless Networks

Musa

Mir

2011

CIT

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Management of mobility especially balancing the load of handoff for wireless networks is an essential parameter for wireless network design and traffic study. In this paper, we present analytical mobility management in high speed wireless mobile networks focusing on factors such as the number of channel slots and offered load. We demonstrate the performance of handoffs with mobility consideration using several metrics including the alteration of states prior to reaching a cell boundary, the speed of mobile terminal, and the distance between a mobile terminal and a cell boundary. We mainly focus on the performance evaluation for the factor of mobility with taking into account the high speed status of a user.

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A stochastic vehicle mobility model with environmental condition adaptation capability

Cited by 6 publications

References 13 publications

Mobility Support for Millimeter Wave Communications: Opportunities and Challenges

Mobility Support for Millimeter Wave Communications: Opportunities and Challenges

Communication protocols for vehicular ad hoc networks

An Analytical Approach for Mobility Load Balancing in Wireless Networks

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