An Overlay Gateway for the Integration of IP Multimedia Subsystem and Mobile Sink Based-Wireless Sensor Networks

RÉSUMÉ D'une part les Réseaux de Capteurs (WSN par ses sigles en anglais) constituent un domaine de recherche qui a reçu beaucoup d'attention de la part de la communauté scientifique grâce à ses avantages en différents domaines. Chaque réseau est généralement conçu à partir de périphériques de petite taille appelés capteurs qui peuvent capter, effectuer des calculs et communiquer entre eux. De plus, inclure des stations de base mobiles dans les réseaux de capteurs sans fils s'est avéré utile dans une large gamme de scénarios puisque ces derniers permettent d'améliorer la durée de vie globale du réseau et d'augmenter la capacité de transmission de données. D'autre part, le sous-système IP Multimédia (IMS) vise à fournir un accès aux réseaux cellulaires à l'ensemble des services Internet. Il s'agit d'une surcouche de contrôle implantée sur une couche IP dont les objectifs sont de fournir et maintenir une qualité de service (QoS) donnée, un schéma de chargement équitable et des services intégrés; le tout en utilisant des interfaces standards. Combiner les fonctionnalités d‟IMS et l‟ensemble d'informations contextuelles capturées par les stations de base des réseaux de capteurs sans fils ouvre la porte à une nouvelle gamme de services multimédias. Cette dissertation propose une architecture de surcouche pour l'intégration des IMS avec les réseaux de capteurs sans fils. Le service "présence" sert de point d'entrée au domaine des IMS. La passerelle, qui constitue le coeur de notre architecture, est une couche de recouvrement construite sur les mêmes téléphones mobiles qui agissent également en tant que canaux mobiles, publicateurs / écouteurs de présence et périphériques utilisateurs. ----------ABSTRACT On one hand, Wireless Sensor Networks (WSNs) are a research area that has been gaining attention from the research community. They are made up of small scale devices called sensors that can sense, compute and communicate. Moreover, including mobile sinks in WSNs has shown to be useful in a wide range of scenarios since they can improve the overall network lifetime and increase data capacity. On the other hand, the IP Multimedia Subsystem (IMS) aims to provide cellular access to all Internet services. It is an overlay control layer on top of an IP layer whose goals is based in provisioning of Quality of Service (QoS), a fair charging scheme and integrated services through standard interfaces. Combining the capabilities of IMS with the rich set of contextual information captured by mobile sink WSNs opens the door to a wide range of novel multimedia services. This dissertation proposes an overlay architecture for the integration of IMS with mobile sink-based WSN. The Presence service is used as entry point to the IMS world. The gateway which is the heart of our architecture is an overlay built on top of the very same mobile phones that act as mobile sinks, presence publishers / watchers, and end-user devices

An Architecture for M2M Enabled Social Networks

Social Networks (SNs), such as Facebook, Twitter, Google+, are becoming more and more popular nowadays. People are now more connected than before. They share information, pictures, videos and news with their family and friends. However, sharing physical phenomena in SNs is still a manual process done by people themselves. For instance, people would like to share current health status, feelings, thoughts, weather or riding information with friends. The sharing of ambient information automatically in SNs can promote independent living. Moreover, it can enhance the autonomy and confidence of elderly people via continuous monitoring and health support. A set of biometric sensors, for example, placed within a patient body can inform a doctor about patient’s health status; hence the doctor can perform a remote diagnosis. Nowadays people are surrounded by devices like smartphone, sensors, cameras, computers and many other devices known as machines. These devices can automatically collect contextual information from the neighborhood. This thesis proposes an architecture for posting contextual information in SNs to support the automatic sharing of physical phenomena. In the proposed architecture, machines collect the contextual data through an overlay-based gateway to support scalability in terms of number of devices. Considering the resource-constrained devices, the architecture makes use of the Constrained Application Protocol (CoAP), a lightweight standard protocol. An SN processes that data into shareable information and disseminates it as appropriate within the users’ Community of Interests (COIs) (e.g., family, friends). A proof of concept prototype is developed to verify the feasibility of the proposed architecture and its performance has been partially evaluated

Cloud Based IP Multimedia Subsystem (IMS) Architecture to Integrate Vehicular Ad Hoc Network (VANET) and IMS

RÉSUMÉ Les réseaux Ad Hoc véhiculaires (VANET) représentent une technologie spéciale, dans la catégorie des réseaux ad hoc sans fils. Ils visent la sécurité routière, une plus grande efficacité et une meilleure organisation au sein des systèmes de transport. Ils favorisent l’avènement de nouvelles applications relatives à l’ingénierie, la gestion de trafic, la dissémination d’informations d’urgence pour éviter les situations critiques, le confort et le divertissement, ainsi que plusieurs autres «applications utilisateur». Le sous-système multimédia IP (IP Multimedia Subsystem, IMS), a été standardisé par le projet «Third Generation Partnership Project» (3GPP) pour les réseaux hétérogènes avec un support de la qualité de service. Cette plateforme a été proposée dans le but d’offrir aux utilisateurs finaux des services multimédia tels que la voix, les données et la vidéo, la facturation ainsi que l’intégration des services tout-IP. Avec l’avènement de IMS, il est désirable d’offrir aux utilisateurs des réseaux véhiculaires (VANET), un accès aux services de ce sous-système. Cependant, les caractéristiques de ces réseaux posent des difficultés majeures pour le contrôle des performances des services IMS. Par ailleurs, le «réseau cœur » de IMS présente aussi des limitations telles que le contrôle centralisé, la faible efficacité et une faible évolutivité au niveau des équipements du réseau cœur en comparaison aux infrastructures de réseau utilisant le Cloud Computing. Le Cloud Computing est un nouveau paradigme des technologies de l’information, offrant des ressources extensibles dynamiquement, souvent au moyen de machines virtuelles et accessibles en tant que services sur Internet. La migration de l’IMS au sein du Cloud peut permettre d’améliorer les performances de l’infrastructure IMS. Ce projet propose une architecture novatrice d’intégration des réseaux VANET, IMS et le Cloud Computing.----------ABSTRACT Vehicular Ad Hoc network (VANET) is a special technology in wireless ad hoc networks. It can be used to provide road safety, efficiency and traffic organization in transportation system. Thus, new applications arise in several fields such as traffic engineering, traffic management, dissemination of emergency information in order to avoid critical situations, comfort, entertainment and other user applications. IP multimedia Subsystem (IMS) is a subsystem, standardized with Third Generation Partnership Project (3GPP). The IMS supports heterogeneous networking with Quality-of-Service (QoS) policy. The goal of this platform is to integrate All-IP services and to provide final user with multimedia services such as voice, data and video with appropriate billing mechanisms. With the advent of the IP Multimedia Subsystem, it is desirable to provide VANET end-users with IMS services. However, characteristics of VANET cause major challenges to control the performance of IMS services. On the other hand, the traditional IMS core network faces a set of problems such as centralized control, low efficiency and poor scalability of core equipment, compared with the IT environment using Cloud Computing. Cloud Computing is an emerging paradigm in the field of information technology. In this new paradigm, dynamically scalable and often virtualized resources are provided as services over the Internet. The migration of IMS to cloud can improve its performance. This project proposes an innovative architecture in order to integrate VANET, IMS and Cloud Computing

Application Layer Architectures for Disaster Response Systems

Traditional disaster response methods face several issues such as limited situational awareness, lack of interoperability and reliance on voice-oriented communications. Disaster response systems (DRSs) aim to address these issues and assist responders by providing a wide range of services. Since the network infrastructure in disaster area may become non-operational, mobile ad-hoc networks (MANETs) are the only alternative to provide connectivity and other network services. Because of the dynamic nature of MANETs the applications/services provided by DRSs should be based on distributed architectures. These distributed application/services form overlays on top of MANETs. This thesis aims to improve three main aspect of DRSs: interoperability, automation, and prioritization. Interoperability enables the communication and collaboration between different rescue teams which improve the efficiency of rescue operations and avoid potential interferences between teams. Automation allows responders to focus more on their tasks by minimizing the required human interventions in DRSs. Automation also allows machines to operate in areas where human cannot because of safety issues. Prioritization ensures that emergency services (e.g. firefighter communications) in DRSs have higher priority to receive resources (e.g. network services) than non-emergency services (e.g. new reporters’ communications). Prioritizing vital services in disaster area can save lives. This thesis proposes application layer architectures that enable three important services in DRSs and contribute to the improvement of the three aforementioned aspects of DRSs: overlay interconnection, service discovery and differentiated quality of service (QoS). The overlay interconnection architecture provides a distributed and scalable mechanism to interconnect end-user application overlays and gateway overlays in MANETs. The service discovery architecture is a distributed directory-based service discovery mechanism based on the standard Domain Name System (DNS) protocol. Lastly, a differentiated QoS architecture is presented that provides admission control and policy enforcement functions based on a given prioritization scheme. For each of the provided services, a motivation scenario is presented, requirements are derived and related work is evaluated with respect to these requirements. Furthermore, performance evaluations are provided for each of the proposed architectures. For the overlay interconnection architecture, a prototype is presented along with performance measurements. The results show that our architecture achieves acceptable request-response delays and network load overhead. For the service discovery architecture, extensive simulations have been run to evaluate the performance of our architecture and to compare it with the Internet Engineering Task Force (IETF) directory-less service discovery proposal based on Multicast DNS. The results show that our architecture generates less overall network load and ensures successful discovery with higher probability. Finally, for the differentiated QoS architecture, simulations results show that our architecture not only enables differentiated QoS, it also improves overall QoS in terms of the number of successful overlay flows

A Presence-Based Architecture for a Gateway to Integrate Vehicular Ad-Hoc Networks (VANETs), the IP Multimedia Subsystems (IMS) and Wireless Sensor Networks (WSNs)

Résumé Le IP Multimedia Subsystems (IMS) est un sujet de recherche qui attire l’attention de la communauté de recherche. Il a comme but de fournir un accès mobile aux différents services internet. Il s’agit d’une architecture de contrôle au-dessus de la couche IP dont le but est de fournir une qualité de service, services intégrés et un système de tarification équitable à travers des interfaces standards. D’autre part, le réseau Ad-hoc de véhicules (VANETs) fournit un nouveau moyen de communication sans-fil entre les véhicules circulants à grande vitesse ainsi que les équipements installés tout au long des côtés de la route. Cette technologie ouvre la porte pour développer des applications diverses comme la génie de trafic, gestion du trafic, diffusion d’information en cas d’urgence pour éviter des situations critiques, divertissement et bien d’autres choses. VANETs forme une sous-classe des réseaux Ad-hoc mobile dont la performance est fortement liée au protocole de routage utilisé dans le réseau. L’intégration des deux technologies, IMS et VANET, permettra de mettre en œuvre de nouveaux services multimédias. Ce mémoire de maîtrise propose une architecture d’une passerelle incorporant ces deux technologies ensemble. Étant donné que les deux architectures utilisent des formats de communication différents, on a conçu un middleware afin d’adapter le format en fonction de la destination et de choisir la meilleur stratégie de livraison d’information entre eux. La passerelle, qui est le cœur de notre architecture, est une couche au-dessus du IMS et le VANET. ----------ABSTRACT On one hand, IP Multimedia Subsystems (IMS) are a research area that has been gaining attention from the research community. It aims to provide cellular access to all Internet services. It is a control architecture on the top of the IP layer whose goal is dependent on the provision of the Quality of Service (QoS), integrated services and fair charging scheme throughout standard interfaces. On the other hand, Vehicular Ad-hoc Networks (VANETs) are a new communication paradigm that enables the wireless communication between vehicles moving with high speeds, as well as the vehicles and the road side equipments found along the roads. This opened the door to develop several new applications like, traffic engineering, traffic management, dissemination of emergency information to avoid critical situations, comfort and entertainment and other user applications. Moreover, VANETs are a sub-class of mobile ad-hoc networks; the performance of the communication depends on how better the routing takes place in the network. Routing of data depends on the routing protocols being used in the network. Combining the capabilities of IMS world with the VANET world opens the door to deploy a wide range of novel multimedia services. This dissertation proposes a presence-based architecture for the integration of IMS with VANETs. The presence of the middleware is used to make an instantaneous awareness of the VANETs changes as well as of the IMS format and to select the best delivery strategy between the two architectures. The gateway which is the heart of our architecture is an overlay built on the top of the IMS as well as the VANETs