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27 results on '"Soua, Ahmed"'

1. Broadcast-based Directional Routing in Vehicular Ad-Hoc Networks

Author

Soua, Ahmed, Ameur, Walid Ben, and Afifi, Hossam

Subjects
Computer Science - Networking and Internet Architecture
Abstract

An optimized broadcast protocol is proposed for VANETs. It is based on two key information: the direction to the destination and the beamforming angle {\theta}. The efficiency of this technique is demonstrated in terms of packet delivery, bandwidth gain and probability of transmission success. An analytical model is developed to calculate the transmission area. This model allows capturing the propagation shape of the forwarding area. Comparisons with simulations show that the analytical model is precise.

Published
2012

2. Connected and Automated Mobility Services in 5G Cross-Border Environments: Challenges and Prospects

Author

Katsaros, Konstantinos V., Amditis, Angelos J., Trichias, Konstantinos, Shagdar, Oyunchimeg, Soua, Ahmed, Costa Requena, Jose, Santa, Jose, Kakes, Geerd, Almeida, João, Sousa, Emanuel, Cruz, Nuno, Velez, Gorka, Sari, Tahir, Jáuregui Cortizo, Daniel, Correia, Fernando, Kountche, Djibrilla Amadou, Rommel, Simon, Nikolitsa, Eftychia, Demestichas, Panagiotis, Katsaros, Konstantinos V., Amditis, Angelos J., Trichias, Konstantinos, Shagdar, Oyunchimeg, Soua, Ahmed, Costa Requena, Jose, Santa, Jose, Kakes, Geerd, Almeida, João, Sousa, Emanuel, Cruz, Nuno, Velez, Gorka, Sari, Tahir, Jáuregui Cortizo, Daniel, Correia, Fernando, Kountche, Djibrilla Amadou, Rommel, Simon, Nikolitsa, Eftychia, and Demestichas, Panagiotis

Abstract

The next generation of mobile networks, namely 5G, promises significant qualitative and quantitative advances for multiple vertical domains. However, most studies and investigations assess these advances under the implicit assumption of a single network service provider, with typical national coverage. In this article, we take a close look at the automotive sector and highlight a series of challenges emerging in the context of its inherent (inter)national mobility and the corresponding importance of cross-border and/or multioperator environments. Our target is to pinpoint the key influential factors affecting the transition toward seamless (cooperative) connected and automated mobility services within and across national borders. To this end, we identify and analyze a series of challenges in the areas of, networking, application, security, and regulation. We further present and discuss a series of corresponding solutions investigated in the pragmatic context of our experimental activities.

Published
2023

3. Connected and Automated Mobility Services in 5G Cross-Border Environments: Challenges and Prospects

Author

Katsaros, Konstantinos V., primary, Amditis, Angelos J., additional, Trichias, Konstantinos, additional, Shagdar, Oyunchimeg, additional, Soua, Ahmed, additional, Requena, Jose Costa, additional, Santa, José, additional, Kakes, Geerd, additional, Almeida, João, additional, Sousa, Emanuel, additional, Cruz, Nuno, additional, Velez, Gorka, additional, Sari, Tahir, additional, Cortizo, Daniel Jáuregui, additional, Correia, Fernando, additional, Kountche, Djibrilla Amadou, additional, Rommel, Simon, additional, Nikolitsa, Eftychia, additional, and Demestichas, Panagiotis, additional

Published
2023
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9. Survey on radio resource allocation in long‐term evolution‐vehicle.

Author

Allouch, Mariem, Kallel, Sondes, Soua, Ahmed, Shagdar, Oyunchimeg, and Tohme, Samir

Subjects
RESOURCE allocation, RADIO resource management, LONG-Term Evolution (Telecommunications), INTELLIGENT transportation systems, ROAD users, QUALITY of service, ROAD safety measures
Abstract

The main goal behind radio resource management (RRM), in any conventional wireless networks, is to efficiently utilize the available resources. Critical and safety communications have very stringent quality of service requirements on reliability and availability. Consequently, the efficient use of resources becomes more compelling when it deals with this type of application. In this context, cellular vehicle‐to‐everything (C‐V2X) communications, enabled by cellular device‐to‐device (D2D), have recently drawn much attention. This is due to their applicability to road safety and traffic efficiency applications, which require information exchange among road users and road‐side entities. This emerging technology, referred hereinafter as LTE‐V or C‐V2X, supports two different communication modes: 3 and 4. Both of the two modes enable direct vehicle‐to‐vehicle (V2V) communications via PC5 interface. However, they differ on how the radio resources are allocated. Several approaches and algorithms are proposed in the literature to address the resource allocation issue. In this paper, a state of the art of the radio resource allocation strategies was made for LTE‐V technology and a qualitative description was carried out of these different schemes. We proposed a classification of these strategies into different categories. This classification identified the different strengths and weaknesses of each proposal. Up to our knowledge, several surveys concerning resource allocation are published in the context of LTE but very few of them focuses on both RRM and vehicular networks. [ABSTRACT FROM AUTHOR]

Published
2022
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14. Public Safety Communications: How to Maintain Connectivity and Improve Resiliency?

Author

GOLMIE, Nada, Cintrón, Fernando, Garey, Wesley, Gentile, Camillo, Griffith, David, Ben Mosbah, Aziza, ROUIL, Richard, Soua, Ahmed, Ben-Mosbah, Aziza, National Institute of Standards and Technology [Gaithersburg] (NIST), Services répartis, Architectures, MOdélisation, Validation, Administration des Réseaux (SAMOVAR), Institut Mines-Télécom [Paris] (IMT)-Télécom SudParis (TSP), and Centre National de la Recherche Scientifique (CNRS)

Subjects
[INFO.INFO-NI]Computer Science [cs]/Networking and Internet Architecture [cs.NI], [INFO.INFO-NI] Computer Science [cs]/Networking and Internet Architecture [cs.NI]
Abstract

International audience; Emergency personnel operating in highly stressed environments may find themselves unable to connect to traditional network access points such as cell towers. In such a situation, the ability to maintain communication services when outside of network coverage and in the event of widespread network failures is essential. The Public Safety Communication Research (PSCR) program has been developing modeling and simulation tools to evaluate different functionalities such as the use of high power transmission and device-to-device (D2D) communications. This talk presents key findings associated D2D communications in a public safety context. In addition, we will show strategies to maintain network coverage in the case of equipment failures or infrastructure loss and what traffic can be sustained in this case.

Published
2015

15. Réseaux véhiculaires : dissémination, routage et collecte de données : modèles et algorithmes

Author

Soua, Ahmed, Département Réseaux et Services de Télécommunications (RST), Institut Mines-Télécom [Paris] (IMT)-Télécom SudParis (TSP), Services répartis, Architectures, MOdélisation, Validation, Administration des Réseaux (SAMOVAR), Centre National de la Recherche Scientifique (CNRS), Institut National des Télécommunications, Hossam Afifi, and Walid Ben Ameur

Subjects
Transmission power adjustment, Ajustement de la puissance de transmission, [INFO.INFO-OH]Computer Science [cs]/Other [cs.OH], Congestion control, Réseaux véhiculaires, Vehicular adhoc networks, [SHS.ECO]Humanities and Social Sciences/Economics and Finance, Framework analytique, Contrôle de congestion, Safety applications, Dissemination protocol, Collecte de données, Data collection, Protocole de dissémination, Analytical framework, Applications de sécurité routière
Abstract

Each day, Humanity loses thousands of persons on roads when they were traveling to work, to study or even to distract. The financial cost of these injuries is also terrifying: Some statistics evaluate the financial cost of vehicle accidents at 160 billion Euro in Europe each year. These alarming figures have driven researchers, automotive companies and public governments to improve the safety of our transportation systems and communication technologies aiming at offering safer roads and smooth driving to human beings. In this context, Vehicular Adhoc Networks, where vehicles are able to communicate with each others and with existent road side units, emerge as a promising wireless technology able to enhance the vision of drivers and offer larger telematic horizon. VANETs promising applications are not only restricted to road safety but span from vehicle trafficoptimization like flow congestion control to commercial applications like file sharing and internet access. Safety applications require that their alert information is propagated to the concerned vehicles (located in the hazardous zone) with little delay and high reliability. For these reasons, this category of applications is considered as delay sensitive and broadcast-oriented nature. While classical blind flooding is rapid, its major drawback is its huge bandwidth utilization. In this thesis, we are interested on enhancing vehicular communications under different scenarios and optimizations: First, We focus on deriving a new solution (EBDR) to disseminate alert messages among moving vehicles while maintaining it efficient and rapid. Our proposal is based on directional antennas to broadcast messages and a route guidance algorithm to choose the best path for the packets. Findings confirmed the efficiency of our approach in terms of probability of success and end-to-end delays. Moreover, in spite of the broadcast nature of the proposed technique, all transmissions stop very soon after the arrival of a packet to its destination representing a strong feature in the conception of EBDR. Second, we propose a novel mathematical framework to evaluate the performance of EBDR analytically. Although most of the proposed techniques present in literature use experimental or simulation tools to defend their performance, we rely here on mathematical models to confirm our achieved results. Our proposed framework allows to derive meaningful performance metrics including the probability of transmission success and the required number of hops to reach thefinal destination. Third, we refine our proposed broadcast-based routing EBDR to provide more efficient broadcasting by adjusting the transmission range of each vehicle based on its distance to the destination and the local node density. This mechanism allows better minimization of interferences and bandwidth's saving. Furthermore, an analytical model is derived to calculate thetransmission area in the case of a simplified node distribution. Finally, we are interested on data collection mechanisms as they make inter-vehicle communications more efficient and reliable and minimize the bandwidth utilization. Our technique uses Q-learning to collect data among moving vehicles in VANETs. The aim behind using the learning technique is to make the collecting operation more reactive to nodes mobility and topology changes. For the simulation part, we compare it to a non-learning version to study the effect of the learning technique. Findings show that our technique far outperforms other propositions and achieves a good trade off between delay and collection ratio. In conclusion, we believe that the different contributions presented in this Thesis will improve the efficiency of inter-vehicle communications in both dissemination and data collection directions. In addition, our mathematical contributions will enrich the literature in terms of constructing suitable models to evaluate broadcasting techniques in urban zones; Chaque jour, l'humanité perd des milliers de personnes sur les routes pendant qu'ils se rendaient à travailler, à étudier ou même à se distraire. Ce nombre alarmant s'accumule avec le coût financier terrifiant de ces décès: Certaines statistiques évaluent le coût à 160 milliards d'euros par an en Europe. Dans ce contexte, les réseaux véhiculaires (VANETs) émergent comme une technologie sans fil prometteuse capable d'améliorer la vision des conducteurs et ainsi offrir un horizon télématique plus vaste. Les applications de sécurité routière exigent que le message d'alerte soit propagé de proche en proche par les véhicules jusqu'à arriver à la zone concernée par l'alerte tout en respectant les délais minimaux exigés par ce type d'applications et la grande fiabilité des transmissions. Dans cette thèse, nous nous intéressons à l'amélioration de l'efficacité des communications inter-véhiculaires sous différents scénarios: tout d'abord, nous nous concentrons sur le développement d'une nouvelle solution, appelée EBDR, pour disséminer les informations d'alertes dans un réseau VANET tout en assurant des courts délais de bout en bout et une efficacité pour les transmissions. Notre proposition est basée sur des transmissions dirigées effectuées à l'aide des antennes directionnelles pour la diffusion des messages et un algorithme de guidage d'itinéraire afin de choisir le meilleur chemin pour le paquet. En dépit de son fonctionnement en diffusion, les transmissions de notre technique s'arrêtent très rapidement après l'arrivée du paquet à la destination finale ce qui représente une caractéristique fondamentale dans la conception d’EBDR. Deuxièmement, nous proposons un framework mathématique ayant pour objectif l'évaluation des performances d’EBDR analytiquement. Nos modèles analytiques permettent de dériver des métriques de performances significatives à savoir la probabilité de succès et le nombre de sauts requis pour atteindre la destination finale. En outre, nous proposons une amélioration de notre protocole EBDR dans le but de fournir une diffusion plus efficace. Pour cela, nous nous basons sur l'ajustement de la puissance de transmission de chaque véhicule en fonction de la distance qui le sépare de la destination et la densité locale des nœuds. Ce mécanisme de contrôle de congestion permet de mieux minimiser les interférences et économiser de la bande passante. En plus, un modèle mathématique a été élaboré pour calculer la surface de la zone de transmission dans le cas d'une distribution uniforme des nœuds. Finalement, nous nous sommes intéressés aux mécanismes de collecte de données dans les réseaux véhiculaires. Notre approche est basée sur l'utilisation du principe du Q-learning pour la collecte des données des véhicules en mouvement. L'objectif de l'utilisation de ce mécanisme d'apprentissage est de rendre l'opération de collecte mieux adaptée à la mobilité des nœuds et le changement rapide de la topologie du réseau. Notre technique a été comparée à des méthodes n'utilisant pas du "learning", afin d'étudier l'effet du mécanisme d'apprentissage. Les résultats ont montré que notre approche dépasse largement les autres propositions en terme de performances et réalise un bon compromis entre le taux de collecte et les délais de bout en bout. Pour conclure, nous pensons que nos différentes contributions présentées tout le long de cette thèse permettront d'améliorer l'efficacité des communications sans fil inter-véhiculaires dans les deux directions de recherches ciblées par cette thèse à savoir : la dissémination des messages et la collecte des données. En outre, nos contributions de modélisation mathématique enrichiront la littérature en termes de modèles analytiques capables d'évaluer les techniques de transmission des données dans un réseau véhiculaire

Published
2013

16. Vehicular ad hoc networks : dissemination, data collection and routing : models and algorithms

Author

Soua, Ahmed, STAR, ABES, Département Réseaux et Services de Télécommunications (RST), Institut Mines-Télécom [Paris] (IMT)-Télécom SudParis (TSP), Services répartis, Architectures, MOdélisation, Validation, Administration des Réseaux (SAMOVAR), Centre National de la Recherche Scientifique (CNRS), Institut National des Télécommunications, Hossam Afifi, and Walid Ben Ameur

Subjects
Transmission power adjustment, Ajustement de la puissance de transmission, [INFO.INFO-OH]Computer Science [cs]/Other [cs.OH], Congestion control, Réseaux véhiculaires, [SHS.ECO]Humanities and Social Sciences/Economics and Finance, Vehicular adhoc networks, Framework analytique, [INFO.INFO-OH] Computer Science [cs]/Other [cs.OH], Contrôle de congestion, Safety applications, Dissemination protocol, Collecte de données, Data collection, Protocole de dissémination, [SHS.ECO] Humanities and Social Sciences/Economics and Finance, Analytical framework, Applications de sécurité routière
Abstract

Each day, Humanity loses thousands of persons on roads when they were traveling to work, to study or even to distract. The financial cost of these injuries is also terrifying: Some statistics evaluate the financial cost of vehicle accidents at 160 billion Euro in Europe each year. These alarming figures have driven researchers, automotive companies and public governments to improve the safety of our transportation systems and communication technologies aiming at offering safer roads and smooth driving to human beings. In this context, Vehicular Adhoc Networks, where vehicles are able to communicate with each others and with existent road side units, emerge as a promising wireless technology able to enhance the vision of drivers and offer larger telematic horizon. VANETs promising applications are not only restricted to road safety but span from vehicle trafficoptimization like flow congestion control to commercial applications like file sharing and internet access. Safety applications require that their alert information is propagated to the concerned vehicles (located in the hazardous zone) with little delay and high reliability. For these reasons, this category of applications is considered as delay sensitive and broadcast-oriented nature. While classical blind flooding is rapid, its major drawback is its huge bandwidth utilization. In this thesis, we are interested on enhancing vehicular communications under different scenarios and optimizations: First, We focus on deriving a new solution (EBDR) to disseminate alert messages among moving vehicles while maintaining it efficient and rapid. Our proposal is based on directional antennas to broadcast messages and a route guidance algorithm to choose the best path for the packets. Findings confirmed the efficiency of our approach in terms of probability of success and end-to-end delays. Moreover, in spite of the broadcast nature of the proposed technique, all transmissions stop very soon after the arrival of a packet to its destination representing a strong feature in the conception of EBDR. Second, we propose a novel mathematical framework to evaluate the performance of EBDR analytically. Although most of the proposed techniques present in literature use experimental or simulation tools to defend their performance, we rely here on mathematical models to confirm our achieved results. Our proposed framework allows to derive meaningful performance metrics including the probability of transmission success and the required number of hops to reach thefinal destination. Third, we refine our proposed broadcast-based routing EBDR to provide more efficient broadcasting by adjusting the transmission range of each vehicle based on its distance to the destination and the local node density. This mechanism allows better minimization of interferences and bandwidth's saving. Furthermore, an analytical model is derived to calculate thetransmission area in the case of a simplified node distribution. Finally, we are interested on data collection mechanisms as they make inter-vehicle communications more efficient and reliable and minimize the bandwidth utilization. Our technique uses Q-learning to collect data among moving vehicles in VANETs. The aim behind using the learning technique is to make the collecting operation more reactive to nodes mobility and topology changes. For the simulation part, we compare it to a non-learning version to study the effect of the learning technique. Findings show that our technique far outperforms other propositions and achieves a good trade off between delay and collection ratio. In conclusion, we believe that the different contributions presented in this Thesis will improve the efficiency of inter-vehicle communications in both dissemination and data collection directions. In addition, our mathematical contributions will enrich the literature in terms of constructing suitable models to evaluate broadcasting techniques in urban zones, Chaque jour, l'humanité perd des milliers de personnes sur les routes pendant qu'ils se rendaient à travailler, à étudier ou même à se distraire. Ce nombre alarmant s'accumule avec le coût financier terrifiant de ces décès: Certaines statistiques évaluent le coût à 160 milliards d'euros par an en Europe. Dans ce contexte, les réseaux véhiculaires (VANETs) émergent comme une technologie sans fil prometteuse capable d'améliorer la vision des conducteurs et ainsi offrir un horizon télématique plus vaste. Les applications de sécurité routière exigent que le message d'alerte soit propagé de proche en proche par les véhicules jusqu'à arriver à la zone concernée par l'alerte tout en respectant les délais minimaux exigés par ce type d'applications et la grande fiabilité des transmissions. Dans cette thèse, nous nous intéressons à l'amélioration de l'efficacité des communications inter-véhiculaires sous différents scénarios: tout d'abord, nous nous concentrons sur le développement d'une nouvelle solution, appelée EBDR, pour disséminer les informations d'alertes dans un réseau VANET tout en assurant des courts délais de bout en bout et une efficacité pour les transmissions. Notre proposition est basée sur des transmissions dirigées effectuées à l'aide des antennes directionnelles pour la diffusion des messages et un algorithme de guidage d'itinéraire afin de choisir le meilleur chemin pour le paquet. En dépit de son fonctionnement en diffusion, les transmissions de notre technique s'arrêtent très rapidement après l'arrivée du paquet à la destination finale ce qui représente une caractéristique fondamentale dans la conception d’EBDR. Deuxièmement, nous proposons un framework mathématique ayant pour objectif l'évaluation des performances d’EBDR analytiquement. Nos modèles analytiques permettent de dériver des métriques de performances significatives à savoir la probabilité de succès et le nombre de sauts requis pour atteindre la destination finale. En outre, nous proposons une amélioration de notre protocole EBDR dans le but de fournir une diffusion plus efficace. Pour cela, nous nous basons sur l'ajustement de la puissance de transmission de chaque véhicule en fonction de la distance qui le sépare de la destination et la densité locale des nœuds. Ce mécanisme de contrôle de congestion permet de mieux minimiser les interférences et économiser de la bande passante. En plus, un modèle mathématique a été élaboré pour calculer la surface de la zone de transmission dans le cas d'une distribution uniforme des nœuds. Finalement, nous nous sommes intéressés aux mécanismes de collecte de données dans les réseaux véhiculaires. Notre approche est basée sur l'utilisation du principe du Q-learning pour la collecte des données des véhicules en mouvement. L'objectif de l'utilisation de ce mécanisme d'apprentissage est de rendre l'opération de collecte mieux adaptée à la mobilité des nœuds et le changement rapide de la topologie du réseau. Notre technique a été comparée à des méthodes n'utilisant pas du "learning", afin d'étudier l'effet du mécanisme d'apprentissage. Les résultats ont montré que notre approche dépasse largement les autres propositions en terme de performances et réalise un bon compromis entre le taux de collecte et les délais de bout en bout. Pour conclure, nous pensons que nos différentes contributions présentées tout le long de cette thèse permettront d'améliorer l'efficacité des communications sans fil inter-véhiculaires dans les deux directions de recherches ciblées par cette thèse à savoir : la dissémination des messages et la collecte des données. En outre, nos contributions de modélisation mathématique enrichiront la littérature en termes de modèles analytiques capables d'évaluer les techniques de transmission des données dans un réseau véhiculaire

Published
2013

26. Broadcast-based Directional Routing in Vehicular Ad-Hoc Networks

Author

Hossam Afifi, Walid Ben-Ameur, Ahmed Soua, Services répartis, Architectures, MOdélisation, Validation, Administration des Réseaux (SAMOVAR), Institut Mines-Télécom [Paris] (IMT)-Télécom SudParis (TSP), Centre National de la Recherche Scientifique (CNRS), Département Réseaux et Services Multimédia Mobiles (RS2M), and Soua, Ahmed

Subjects
FOS: Computer and information sciences, Dynamic Source Routing, Wireless ad hoc network, Computer science, Wireless Routing Protocol, 02 engineering and technology, Angle of transmission, Computer Science - Networking and Internet Architecture, [INFO.INFO-NI]Computer Science [cs]/Networking and Internet Architecture [cs.NI], Bandwidth, 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, Computer Science::Networking and Internet Architecture, Destination-Sequenced Distance Vector routing, Broadcast radiation, Probability of success, Computer Science::Information Theory, Broadcast, Networking and Internet Architecture (cs.NI), Vehicular ad hoc network, [INFO.INFO-NI] Computer Science [cs]/Networking and Internet Architecture [cs.NI], business.industry, IEEE, IFIP, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, 020302 automobile design & engineering, 020206 networking & telecommunications, Ad hoc wireless distribution service, Optimized Link State Routing Protocol, Vehicular Ad Hoc Networks (VANETs), Area of transmission, business, Computer network
Abstract

6 pages; International audience; An optimized broadcast protocol is proposed for VANETs. It is based on two key information: the direction to the destination and the beamforming angle θ. The efficiency of this technique is demonstrated in terms of packet delivery, bandwidth gain and probability of transmission success. An analytical model is developed to calculate the transmission area. This model allows capturing the propagation shape of the forwarding area. Comparisons with simulations show that the analytical model is precise.

Published
2012

27. Enhancing Broadcast Vehicular Communications Using Beamforming Technique

Author

Walid Ben-Ameur, Ahmed Soua, Hossam Afifi, Soua, Ahmed, Services répartis, Architectures, MOdélisation, Validation, Administration des Réseaux (SAMOVAR), Institut Mines-Télécom [Paris] (IMT)-Télécom SudParis (TSP), Centre National de la Recherche Scientifique (CNRS), Département Réseaux et Services Multimédia Mobiles (RS2M), Méthodes et modèles pour les réseaux (METHODES-SAMOVAR), Institut Mines-Télécom [Paris] (IMT)-Télécom SudParis (TSP)-Institut Mines-Télécom [Paris] (IMT)-Télécom SudParis (TSP), and Réseaux, Systèmes, Services, Sécurité (R3S-SAMOVAR)

Subjects
Routing protocol, Beamforming, Computer science, 02 engineering and technology, Data_CODINGANDINFORMATIONTHEORY, Angle of transmission, Implicated nodes, Probability of success, [INFO.INFO-NI]Computer Science [cs]/Networking and Internet Architecture [cs.NI], Bandwidth, 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, Bandwidth (computing), Electronic engineering, Computer Science::Networking and Internet Architecture, Computer Science::Information Theory, Broadcast, WSDMA, [INFO.INFO-NI] Computer Science [cs]/Networking and Internet Architecture [cs.NI], business.industry, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, 020302 automobile design & engineering, 020206 networking & telecommunications, IEEE, Transmission (telecommunications), Vehicular Ad Hoc Networks (VANETs), Key (cryptography), Area of transmission, Routing (electronic design automation), business, Computer network
Abstract

6 pages; International audience; A beamforming-based broadcast technique is proposed here for VANETs. It is based on two key information: the direction to the destination and the beamforming angle θ . Simulations demonstrate the efficiency of our proposal in terms of probability of transmission success, ratio of implicated nodes and bandwidth gain. An analytical model is derived to calculate the forwarding transmission area. Simulation results match very well the mathematical expressions and show that the analytical model is precise.

Published
2012

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