Ubiquitous robust communications for emergency response using multi-operator heterogeneous networks

A number of disasters in various places of the planet have caused an extensive loss of lives, severe damages to properties and the environment, as well as a tremendous shock to the survivors. For relief and mitigation operations, emergency responders are immediately dispatched to the disaster areas. Ubiquitous and robust communications during the emergency response operations are of paramount importance. Nevertheless, various reports have highlighted that after many devastating events, the current technologies used, failed to support the mission critical communications, resulting in further loss of lives. Inefficiencies of the current communications used for emergency response include lack of technology inter-operability between different jurisdictions, and high vulnerability due to their centralized infrastructure. In this article, we propose a flexible network architecture that provides a common networking platform for heterogeneous multi-operator networks, for interoperation in case of emergencies. A wireless mesh network is the main part of the proposed architecture and this provides a back-up network in case of emergencies. We first describe the shortcomings and limitations of the current technologies, and then we address issues related to the applications and functionalities a future emergency response network should support. Furthermore, we describe the necessary requirements for a flexible, secure, robust, and QoS-aware emergency response multi-operator architecture, and then we suggest several schemes that can be adopted by our proposed architecture to meet those requirements. In addition, we suggest several methods for the re-tasking of communication means owned by independent individuals to provide support during emergencies. In order to investigate the feasibility of multimedia transmission over a wireless mesh network, we measured the performance of a video streaming application in a real wireless metropolitan multi-radio mesh network, showing that the mesh network can meet the requirements for high quality video transmissions

Suporte de mobilidade em redes WIMAX

O desenvolvimento crescente da Internet, com novos serviços e aplicações que requerem elevadas exigências a nível de qualidade de serviço, como por exemplo, o VoIP e IPTV, a crescente necessidade de um utilizador estar sempre contactável em qualquer sítio e a qualquer momento, torna necessária a integração actual da Internet com as redes móveis da próxima geração. A tecnologia IEEE 802.16 surge como uma tecnologia de banda larga sem fios que pode ter um papel fundamental num ambiente de próxima geração. Devido aos seus baixos custos de instalação e à possibilidade de chegar facilmente a zonas rurais ou a zonas de difícil acesso, torna-se um sério candidato para suprir as necessidades dos utilizadores. A necessidade de mobilidade pelo utilizador, para aceder a diversos serviços em diferentes sítios ou ser identificado remotamente para a posterior recepção de informação também é um desejo futuro. O protocolo IEEE 802.21 surge como um meio que providencia a optimização de handover entre diferentes tecnologias de acesso, quer sejam elas WiFi, WiMAX, 3GGP ou 3GPP2, no sentido de proporcionar ao utilizador a utilização de diferentes serviços de uma forma transparente à tecnologia de acesso, quando em situações de mobilidade. Esta dissertação apresenta a arquitectura desenvolvida para proporcionar a correcta avaliação da atribuição de QoS e mobilidade transparente, num ambiente real de próxima geração. Serão também efectuados testes com o equipamento WiMAX disponível, no sentido de mostrar o seu correcto comportamento na atribuição de QoS fim-a-fim em cenários ponto-a-ponto e ponto-a-multiponto com serviços com características de tempo real. A integração do software da primeira fase do projecto WEIRD e o seu correcto comportamento em ambientes de atribuição de QoS também vai ser estudado. A implementação dos diferentes módulos, em especial a implementação da unidade central da arquitectura de IEEE 802.21 (MIHF), vai ser descrita, no sentido de avaliar o desempenho do WiMAX e do protocolo IEEE 802.21 numa rede real no âmbito da segunda fase do projecto WEIRD. Os resultados obtidos demonstram que a arquitectura desenvolvida consegue fornecer QoS fim-a-fim com suporte de mobilidade entre redes heterogéneas. ABSTRACT: The growing development of the Internet, with new services and applications that require a high level of quality of service, such as, VoIP and IPTV, the increasing need for a user to be always reachable anywhere and at anytime, motivates the integration of current Internet with the next generation of mobile networks. The IEEE 802.16 technology emerges as a technology for broadband wireless access that may have a key role in a next generation environment. Due to its low costs of installation and its ability to easily reach rural areas or areas with difficult access, it becomes a serious candidate to supply the needs of users. The mobility’s necessity by the user, to access to several services in different locations or be identified remotely for subsequent receipt of information, is also a future desire. The IEEE 802.21 protocol provides the optimization of handover between heterogeneous networks, such as WiFi, WiMAX, 3GGP or 3GPP2, to offer the user different services in a transparent manner to his access technology, when in situations of mobility. This Thesis presents the architecture developed to provide the correct integration of QoS and seamless mobility, in a real next generation environment. It will also present tests carries out with the available WiMAX equipment, to show its correct behaviour in the allocation of end-to-end QoS in point-to-point and point-to-multipoint scenarios with real-time services. The integration of software from the first phase of the WEIRD project and its correct behaviour in environments of QoS allocation will also be studied. The implementation of the various modules, in particular the implementation of the central unit of IEEE 802.21 architecture (MIHF), will be described, to evaluate the performance of WiMAX and IEEE 802.21 protocol in a real network provided by the second phase of the WEIRD project. The obtained results show that the developed architecture is able to provide end-toend QoS with seamless mobility support over heterogeneous networks

Réseaux de capteurs ubiquitous dans l'environnement NGN

Ubiquités Sensor Network (USN) is a conceptual network built over existing physical networks. It makes use of sensed data and provides knowledge services to anyone, anywhere and at anytime, and where the information is generated by using context awareness. Smart wearable devices and USNs are emerging rapidly providing many reliable services facilitating people life. Those very useful small end terminals and devices require a global communication substrate to provide a comprehensive global end user service. In 2010, the ITU-T provided the requirements to support USN applications and services in the Next Génération Network (NGN) environment to exploit the advantages of the core network. One of the main promising markets for the USN application and services is the e-Health. It provides continuous patients’ monitoring and enables a great improvement in medical services. On the other hand, Vehicular Ad-Hoc NETwork (VANET) is an emerging technology, which provides intelligent communication between mobile vehicles. Integrating VANET with USN has a great potential to improve road safety and traffic efficiency. Most VANET applications are applied in real time and they are sensitive to delay, especially those related to safety and health. In this work, we propose to use IP Multimedia Subsystem (IMS) as a service controller sub-layer in the USN environment providing a global substrate for a comprehensive end-to-end service. Moreover, we propose to integrate VANETs with USN for more rich applications and facilities, which will ease the life of humans. We started studying the challenges on the road to achieve this goalUbiquitous Sensor Network (USN) est un réseau conceptuel construit sur des réseaux physiques existantes. Il se sert des données détectées et fournit des services de connaissances à quiconque, n'importe où et à tout moment, et où l'information est générée en utilisant la sensibilité au contexte. Dispositifs et USN portables intelligents émergent rapidement en offrant de nombreux services fiables facilitant la vie des gens. Ces petits terminaux et terminaux très utiles besoin d'un substrat de communication globale pour fournir un service complet de l'utilisateur final global. En 2010, ITU -T a fourni les exigences pour supporter des applications et services USN dans le Next Generation Network (NGN) de l'environnement d'exploiter les avantages du réseau de base. L'un des principaux marchés prometteurs pour l'application et les services USN est la e- santé. Il fournit le suivi des patients en continu et permet une grande amélioration dans les services médicaux. D'autre part, des Véhicules Ad-hoc NETwork (VANET) est une technologie émergente qui permet une communication intelligente entre les véhicules mobiles. Intégrer VANET avec USN a un grand potentiel pour améliorer la sécurité routière et la fluidité du trafic. La plupart des applications VANET sont appliqués en temps réel et ils sont sensibles à retarder, en particulier ceux liés à la sécurité et à la santé. Dans ce travail, nous proposons d'utiliser l'IP Multimédia Subsystem (IMS) comme une sous- couche de contrôle de service dans l'environnement USN fournir un substrat mondiale pour un service complet de bout en bout. De plus, nous vous proposons d'intégrer VANETs avec USN pour des applications et des installations riches plus, ce qui facilitera la vie des humains. Nous avons commencé à étudier les défis sur la route pour atteindre cet objecti