A Semantically Enhanced UPnP Control Point for Sharing Multimedia Content

The Universal Plug and Play (UPnP) protocol lets users share multimedia content across devices and display it in multimedia renderers in homebased LANs. However, UPnP doesn’t support sharing this content between homes (for example, with friends, relatives, or workmates), and content can be difficult to find. A UPnP extension provides uniform access to multimedia content belonging to different homes, such as content from a user’s Facebook friends. In addition, an extended UPnP control point lets users add semantic annotations to their multimedia resources and link them to the linked data cloud to facilitate their discovery by others

Remote service discovery and control for ubiquitous service environments in next-generation networks

Doktorgradsavhandling i informasjons- og kommunikasjonsteknologi, Universitetet i Agder, Grimstad, 201

Remote service discovery and control for ubiquitous service environments in next-generation networks

Doktorgradsavhandling i informasjons- og kommunikasjonsteknologi, Universitetet i Agder, Grimstad, 201

Architectures de réseaux pour la délivrance de services à domicile

Avec l’omniprésence au quotidien du numérique et de l’informatique, de plus en plus d’utilisateurs souhaitent avoir accès à Internet et à leurs applications via n’importe quel périphérique, de n’importe où et n’importe quand. Les appareils domestiques intelligents se développant, les besoins d’échanger des données au domicile même se font de plus en plus sentir. C’est dans ce contexte, celui des services à domicile avec besoin d’interconnexion que se situe notre étude. Ce type de service est qualifié de Home Service (HS) alors que le réseau à domicile est nommé Home Network (HN). La problématique pour les opérateurs est alors de concevoir des architectures appropriées à l’interconnexion des HN de manière sécurisée tout en permettant un déploiement facile et à grande échelle. Dans la première étape, nous considérons la livraison de services sécurisés à travers un réseau de nouvelle génération (NGN) : IMS (IP Multimedia Subsystem). IMS étant l’architecture de référence pour son caractère réseau NGN des opérateurs, diverses architectures peuvent être développées comme support aux HS. Nous avons choisi d'analyser et de mettre en place une architecture P2P centralisée et de le comparer à l’architecture de référence. Plusieurs mécanismes d'authentification sont mis en place autour du P2P centralisé afin de sécuriser la prestation de services. La modélisation et l’évaluation de notre proposition ont permis d’identifier sa relation à l’IMS mais aussi des problèmes inhérents aux solutions centralisées : la protection des données personnelles, l’impact de la taille sur réseau sur les performances, l’existence d’un point de faiblesse unique face aux attaques et la congestion au niveau du serveur centralisé. Par conséquent, nous nous sommes tournés vers les solutions distribuées pour résoudre ces problèmes. Dans la deuxième étape, nous considérons l’architecture P2P non-structurée, qualifiée de pur P2P. La cryptographie basée sur l'identité (IBC) est ajoutée au P2P pur afin d’authentifier les utilisateurs et de protéger leurs communications. Pour chacune des solutions une analyse du coût de signalisation est effectuée révélant une faiblesse en ce qui concerne l’étape de recherche. Dans un déploiement à grande échelle, le coût de cette phase est trop élevé. Aussi, nous examinons le P2P structuré basé sur les Dynamic Hash Tables, une autre solution distribuée. Cette architecture est étudiée par l'IETF en tant qu’une des dernières générations de P2P: REsource LOcation And Discovery (RELOAD) Base Protocol. Nous proposons son utilisation dans le cadre des HSs. Comme preuve du concept, cette solution a été implantée et déployée sur un petit réseau en utilisant TLS/SSL comme mécanisme de sécurité. Cette plateforme nous a permis d’étudier les délais et les coûts de cette solution. Pour terminer, un bilan est établi sur toutes les solutions proposées En outre, nous introduisons d’autres types de HS et leurs possibilités de déploiement futur. ABSTRACT : With digital life enhancement, more users would like to get seamless Internet and information with any devices, at any time and from anywhere. More and more home devices need to exchange data or to control other devices. The type of services is labelled Home Service (HS) and it is deployed though a Home Network (HN). Some users need to use their HS outside their HN, some others need to interconnect other HN. Operators have to provide suitable network architectures to ensure this interconnection and to provide at the same time, scalability, remote access, easy deployment and security. Here is the topic of our work. In the fist step, we consider a practical illustration around the Next-Generation Network (NGN) and the secured services. It is the IMS (IP Multimedia Subsystem) approach for the management of services that is generally supported by the NGN network operators. However, various network operator architectures can be developed to support these services. An alternative way is the P2P architectures. We choose to analyze and implement a centralized P2P and we compare it with the IMS solution. Several authentication mechanisms are introduced to secure the centralized P2P. An evaluation of these architectures is conducted. Since the previous solutions present some issues due to their centralized feature, we consider distributed solutions in a second step. The non-structured P2P, called pure P2P, can also support HS. Identity Based Crytography (IBC) is added to these architectures in order to offer authentication and protection to user communications. The different solutions are compared through their signaling and transmission cost. The study shows that searching step in this architecture is really costly, facing a scalability problem. Thus, we propose to use a structured P2P (called Dynamic Hash Table) for delivering HS between HN. This type of architecture is studied by IETF with the REsource Location And Discovery (RELOAD) Base Protocol. This solution is implanted and deployed here to be a proof of the concept. This test-bed enables the study of delay and security overhead in a real system. Eventually, the presented solutions are recaptured in order to see their advantages/ disadvantages. In addition, we introduce other perspectives in terms of HSs and network interconnection

Network and service monitoring in heterogeneous home networks

Home networks are becoming dynamic and technologically heterogeneous. They consist of an increasing number of devices which offer several functionalities and can be used for many different services. In the home, these devices are interconnected using a mixture of networking technologies (for example, Ethernet, Wifi, coaxial cable, or power-line). However, interconnecting these devices is often not easy. The increasing heterogeneity has led to significant device- and service-management complexity. In addition, home networks provide a critical "last meters" access to the public telecom and Internet infrastructure and have a dramatic impact on to the end-to-end reliability and performance of services from these networks. This challenges service providers not only to maintain a satisfactory quality of service level in such heterogeneous home networks, but also to remotely monitor and troubleshoot them. The present thesis work contributes research and several solutions in the field of network and service monitoring in home networks, mainly in three areas: (1) providing automatic device- and service-discovery and configuration, (2) remote management, and (3) providing quality of service (QoS). With regard to the first area, current service discovery technology is designed to relieve the increasing human role in network and service administration. However, the relevant Service Discovery Protocols (SDPs) are lacking crucial features namely: (1) they are not platform- and network-independent, and (2) they do not provide sufficient mechanisms for (device) resource reservation. Consequently, devices implementing different SDPs cannot communicate with each other and share their functionalities and resources in a managed way, especially when they use different network technologies. As a solution to the first problem, we propose a new proxy server architecture that enables IP-based devices and services to be discovered on non-IP based network and vice versa. We implemented the proxy architecture using UPnP respectively Bluetooth SDP as IP- and non-IP-based SDPs. The proxy allows Bluetooth devices and UPnP control points to discover, access, and utilize services located on the other network. Validation experiments with the proxy prototype showed that seamless inter-working can be achieved keeping all proxy functionalities on a single device, thus not requiring modification of currently existing UPnP and Bluetooth end devices. Although the proxy itself taxes the end-to-end performance of the service, it is shown to be still acceptable for an end user. For mitigating resource conflicts in SDPs, we propose a generic resource reservation scheme with properties derived from common SDP operation. Performance studies with a prototype showed that this reservation scheme significantly improves the scalability and sustainability of service access in SDPs, at a minor computational cost. With regard to the second area, it is known that the end-to-end quality of Internet services depends crucially on the performance of the home network. Consequently, service providers require the ability to monitor and configure devices in the home network, behind the home gateway (HG). However, they can only put limited requirements to these off-the-shelf devices, as the consumer electronics market is largely outside their span of control. Therefore they have to make intelligent use of the given device control and management protocols. In this work, we propose an architecture for remote discovery and management of devices in a highly heterogeneous home network. A proof-of-concept is developed for the remote management of UPnP devices in the home with a TR-069/UPnP proxy on the HG. Although this architecture is protocol specific, it can be easily adapted to other web-services based protocols. Service providers are also asking for diagnostic tools with which they can remotely troubleshoot the home networks. One of these tools should be able to gather information about the topology of the home network. Although topology discovery protocols already exist, nothing is known yet about their performance. In this work we propose a set of key performance indicators for home network topology discovery architectures, and how they should be measured. We applied them to the Link-Layer Topology Discovery (LLTD) protocol and the Link-Layer Discovery Protocol (LLDP). Our performance measurement results show that these protocols do not fulfill all the requirements as formulated by the service providers. With regard to the third area, current QoS solutions are mostly based on traffic classification. Because they need to be supported by all devices in the network, they are relatively expensive for home networks. Furthermore, they are not interoperable between different networking technologies. Alternative QoS provision techniques have been proposed in the literature. These techniques require end-user services to pragmatically adapt their properties to the actual condition of the network. For this, the condition of the home network in terms of its available bandwidth, delay, jitter, etc., needs to be known in real time. Appropriate tools for determining the available home network resources do not yet exist. In this work we propose a new method to probe the path capacity and available bandwidth between a server and a client in a home network. The main features of this method are: (a) it does not require adaptation of existing end devices, (b) it does not require pre-knowledge of the link-layer network topology, and (c) it is accurate enough to make reliable QoS predictions for the most relevant home applications. To use these predictions for effective service- or content-adaptation or admission control, one should also know how the state of the home network is expected to change immediately after the current state has been probed. However, not much is known about the stochastic properties of traffic in home networks. Based on a relatively small set of traffic observations in several home networks in the Netherlands, we were able to build a preliminary model for home network traffic dynamics

De-ossifying the Internet Transport Layer : A Survey and Future Perspectives

ACKNOWLEDGMENT The authors would like to thank the anonymous reviewers for their useful suggestions and comments.Peer reviewedPublisher PD

Smart PIN: performance and cost-oriented context-aware personal information network

The next generation of networks will involve interconnection of heterogeneous individual networks such as WPAN, WLAN, WMAN and Cellular network, adopting the IP as common infrastructural protocol and providing virtually always-connected network. Furthermore, there are many devices which enable easy acquisition and storage of information as pictures, movies, emails, etc. Therefore, the information overload and divergent content’s characteristics make it difficult for users to handle their data in manual way. Consequently, there is a need for personalised automatic services which would enable data exchange across heterogeneous network and devices. To support these personalised services, user centric approaches for data delivery across the heterogeneous network are also required. In this context, this thesis proposes Smart PIN - a novel performance and cost-oriented context-aware Personal Information Network. Smart PIN's architecture is detailed including its network, service and management components. Within the service component, two novel schemes for efficient delivery of context and content data are proposed: Multimedia Data Replication Scheme (MDRS) and Quality-oriented Algorithm for Multiple-source Multimedia Delivery (QAMMD). MDRS supports efficient data accessibility among distributed devices using data replication which is based on a utility function and a minimum data set. QAMMD employs a buffer underflow avoidance scheme for streaming, which achieves high multimedia quality without content adaptation to network conditions. Simulation models for MDRS and QAMMD were built which are based on various heterogeneous network scenarios. Additionally a multiple-source streaming based on QAMMS was implemented as a prototype and tested in an emulated network environment. Comparative tests show that MDRS and QAMMD perform significantly better than other approaches

Developing a Solution for Multimedia Home Networking

In recent years, the rapid development of electronics and computer science has enabled home networking devices to become more affordable and more powerful. Several widely used multimedia-streaming solutions have become available in the market. However, as a result of their different technical designs, these standards naturally experience serious compatibility issues. Thus, end users can have several multimedia devices, with each one using a distinctive, unique protocol, making it challenging or even impossible sometimes to share media between those devices. These compatibility issues have motivated the need to determine the technological features common to the existing multimedia-streaming standards and to develop a more easy-to-use multimedia home networking solution. This thesis compares the modern solutions for multimedia home networking (MHN), including AirPlay, Miracast, Chromecast, and especially the Digital Living Network Alliance (DLNA) standard due to its wide adoption. By conducting research on the features and capabilities of these existing solutions, a suitable mobile solution for MHN, which takes advantage of AirPlay, Discovery and Launch (DIAL), and DLNA, is proposed for the Android platform. The corresponding system architectures, features, and analysis methodologies are also analyzed to demonstrate the competitiveness of this application. In terms of practical contribution, an online channel proxy was integrated to the application to fulfill the target of streaming online channels, such as YouTube. By implementing this online channel proxy, home networking and Internet resources can be effectively connected. Since its first release on the Google Play Store, the application received over one million downloads from 225 countries. According to the statistics, this solution has proved to be competitive and successful. In addition, this thesis discusses possible further development of this solution, and the future trends of multimedia home networking