103 research outputs found
Wireless IP network mobility management: advancing from mobile IP to HIP-based network
Wireless networking introduces a whole range of challenges to the traditional TCP/IP network. In particular, IP address the issue of overloading because IP addresses are used as a network locator and an end point identity in the different layers in an OSI model. Even though Mobile IP is widely deployed, it has significant problems relating to performance and security. The Host Identity Protocol (HIP) provides secure mobility management by solving the IP address overloading from another angle. It restructures the TCP/IP model and introduces a new layer and a new namespace. The performance of HIP has proven to be better than Mobile IP and also opens a range of new research opportunities. This dissertation proposes and analyses a new step-stone solution from the Mobile IP-based network into a HIP-based network. The main advantage of this new solution is that much less change is required to the operating system kernel of the end point compared to a full HIP implementation. The new step-stone solution allows Mobile IP to use some HIP features to provide better security and handover performance. This dissertation also proposes several new and novel HIP-based wireless communication network architectures. An HIP-based heterogeneous wireless network architecture and handover scheme has been proposed and analysed. These schemes limit the HIP signalling in the wireless network if no communication to external networks is needed. Beside the network architecture modification, the hybrid Session Initial Protocol (SIP) and HIP-based Voice over IP (VoIP) scheme is proposed and analysed. This novel scheme improves the handover latency and security. This dissertation also proposes and analyses a new and novel extension to HIP, a HIP-based micro-mobility management, micro-HIP (mHIP). mHIP provides a new secure framework for micro-mobility management. It is a more complete HIP-based micro-mobility solution than any other proposed in existing studies. mHIP improves the intra-domain handover performance, the security, and the distribution of load in the intra-domain handover signalling. The new work presented opens up a number of very interesting research opportunities
Mobility and Handoff Management in Wireless Networks
With the increasing demands for new data and real-time services, wireless
networks should support calls with different traffic characteristics and
different Quality of Service (QoS)guarantees. In addition, various wireless
technologies and networks exist currently that can satisfy different needs and
requirements of mobile users. Since these different wireless networks act as
complementary to each other in terms of their capabilities and suitability for
different applications, integration of these networks will enable the mobile
users to be always connected to the best available access network depending on
their requirements. This integration of heterogeneous networks will, however,
lead to heterogeneities in access technologies and network protocols. To meet
the requirements of mobile users under this heterogeneous environment, a common
infrastructure to interconnect multiple access networks will be needed. In this
chapter, the design issues of a number of mobility management schemes have been
presented. Each of these schemes utilizes IP-based technologies to enable
efficient roaming in heterogeneous network. Efficient handoff mechanisms are
essential for ensuring seamless connectivity and uninterrupted service
delivery. A number of handoff schemes in a heterogeneous networking environment
are also presented in this chapter.Comment: 28 pages, 11 figure
Addressing Devices in Mobile Networks
Mobiilterminalide arengust tingitud vhenenud energiakulu, sisseehitatud sensorite kasutusvimalus, suurenenud ttlusjudlus ja mlumaht vimaldavad mobiilide laialdase kasutuse erinevates domeenides nagu mobiilne sotsiaalvrgustik, mobiilne pilvandmettlus ja Internet of Things (IoT). Selleks, et antud seadmeid oleks vimalik edukalt informatsiooni pakkumise ja ttlemise vahenditena kasutada, on vaja identitseerimiseks ja adresseerimiseks lesandele kohaseid vahendeid, mis vimaldaksid ligipsu seadmetele ja teenustele ka vljaspool mobiilsidevrku. Enamuse ajast, kui kasutajad kasutavad Internetiga hendamiseks mobiilivrke, paiknevad kasutajate seadmed tulemride ja vrguaadressi translaatorite (NAT ehk Network Address Translator) taga, mis takistavad otsese henduse loomist.
Kasutajate hendamist mobiilsetes vrkudes on aastaid phjalikult uuritud ja selle tulemusena on leitud mitmeid lahendusi. IP-aadress, mis on levinuim adresseerimise mehhanism Internetis, on htlasi laialdaselt kasutusel mobiilivrkudes (3G/4G), kuid sellel on omad piirangud: ajutine kttesaadavus, piiratud kasutus ainult mobiilioperaatorite vrkudes ja vrguaadresside tlkimine (NAT). Nende piirangute krvaldamiseks pakume vlja mned teistsugused lhenemised: Session Initiation Protocol (SIP), Rendezvous serveri toel toimiv UDP/TCP Hole Punching ja UDP/TCP Relaying. Neidsaab kasutada erinevate mobiilsidevrkude tpide puhul. Kesolevas magistrits ksitletakse praktilist paigaldust, testide tulemusi ja iga lhenemise nrku ning tugevaid klgi.The emergence of mobile terminals with enhanced features like high processing power, more memory, inbuilt sensors, low power consumption, etc. have led to their extensive usage in different domains like mobile social networking, mobile cloud and Internet of Things (IoT). However, to successfully utilize these devices as information providing/processing entities, we need proper means of identification and addressing, so that the devices and their offered data/services are accessible also from outside the mobile network. But most of the times, when the peers connecting to the internet through cellular networks, peer devices locate behind the common components like firewalls and Network Address Translators (NATs) that prevent establishing direct connections. Setting up connection between peers in mobile networks has been examined extensively over the years and there are several solutions one can conceive. However, the most popular and widely used addressing mechanism for internet, IP address, is also being extensively used in mobile data networks (3G/4G) but ends up with barriers like their temporarily availability, known only within the mobile operators network, Network Address Translation (NAT) etc. To address such kind of limitations we proposed few different approaches such as Session Initiation Protocol (SIP), UDP/TCP hole punching with help from the Rendezvous server and UDP/TCP Relaying those can be applied to different types of mobile networks. In this thesis we discuss practical implementation, test results and evaluation of strengths and limitations of each approach
MOBILITY SUPPORT ARCHITECTURES FOR NEXT-GENERATION WIRELESS NETWORKS
With the convergence of the wireless networks and the Internet and the booming
demand for multimedia applications, the next-generation (beyond the third generation, or
B3G) wireless systems are expected to be all IP-based and provide real-time and non-real-time
mobile services anywhere and anytime. Powerful and efficient mobility support is
thus the key enabler to fulfil such an attractive vision by supporting various mobility
scenarios. This thesis contributes to this interesting while challenging topic.
After a literature review on mobility support architectures and protocols, the thesis
starts presenting our contributions with a generic multi-layer mobility support framework,
which provides a general approach to meet the challenges of handling comprehensive
mobility issues. The cross-layer design methodology is introduced to coordinate the
protocol layers for optimised system design. Particularly, a flexible and efficient cross-layer
signalling scheme is proposed for interlayer interactions. The proposed generic
framework is then narrowed down with several fundamental building blocks identified to
be focused on as follows.
As widely adopted, we assume that the IP-based access networks are organised into
administrative domains, which are inter-connected through a global IP-based wired core
network. For a mobile user who roams from one domain to another, macro (inter-domain)
mobility management should be in place for global location tracking and effective handoff
support for both real-time and non-real-lime applications. Mobile IP (MIP) and the Session
Initiation Protocol (SIP) are being adopted as the two dominant standard-based macro-mobility
architectures, each of which has mobility entities and messages in its own right.
The work explores the joint optimisations and interactions of MIP and SIP when utilising
the complementary power of both protocols. Two distinctive integrated MIP-SIP
architectures are designed and evaluated, compared with their hybrid alternatives and other
approaches. The overall analytical and simulation results shown significant performance
improvements in terms of cost-efficiency, among other metrics.
Subsequently, for the micro (intra-domain) mobility scenario where a mobile user
moves across IP subnets within a domain, a micro mobility management architecture is
needed to support fast handoffs and constrain signalling messaging loads incurred by intra-domain
movements within the domain. The Hierarchical MIPv6 (HMIPv6) and the Fast
Handovers for MIPv6 (FMIPv6) protocols are selected to fulfil the design requirements.
The work proposes enhancements to these protocols and combines them in an optimised
way. resulting in notably improved performances in contrast to a number of alternative
approaches
Vertical handover management with quality of service support
For mobile usage of the Internet, new preferences might be desired when considering connectivity and handover between overlapped heterogeneous wireless networks. This work presents a cross-layer vertical handover framework, which includes modules for: multi-criteria decisions that support QoS, soft switching between the multiple interfaces of a mobile device, and a light weight signaling scheme for address resolution. The handover decisions are based on user's configuration, network attributes, and node's context information. A connection is transferred onto a new interface only when it is associated to the newly selected network and ready to take over the traffic. The identity of the mobile node is maintained by leveraging the well-known and widely employed NAT for the purpose of mobility management in a new version that we call Dynamic index NAT. DiNAT supports local and global mobility through hierarchical deployment of anchor points. The network simulator OMNeT++ is used to model the system and test its feasibility.Neue Anwendungen und Dienste steigern die Attraktivität der mobilen Nutzung
des Internets und fordern die Beibehaltung der Konnektivität auch beim Wechsel
zwischen heterogenen drahtlosen Zugangsnetzen, wobei viele Informationen unterschiedlicher
Quellen berücksichtigt werden müssen. Auf Basis dieser Informationen
müssen Handover-Entscheidungen getroffen werden, die ein Umschalten zwischen den
drahtlosen Schnittstellen bewirken und die Identifikation des mobilen Knotens aktualisieren.
Die vorliegende Arbeit stellt ein Rahmenwerk für vertikalen Handover
vor, das zudem eine Mobilitätsunterstützung beinhaltet. Es verwendet Algorithmen
zur multikriteriellen Entscheidung, die eine breite Reihe von Parametern betrachtet,
um so die Kommunikationsdienstgüte (Quality of Service, QoS) für Echtzeitanwendungen
bereitzustellen. Darüber hinaus wurde eine Strategie für die stabile und
weiche Umschaltung zwischen verschiedenen Schnittstellen des mobilen Geräts entwickelt
und eine leichtgewichtige Signalisierung für die Adressauflösung zur schnellen
Wiederaufnahme der Datenübertragung vorgeschlagen. Die Dissertation beschreibt
den schichtenübergreifenden Handover-Ansatz in drei Modulen, deren Konzept und
Funktionalität detailliert diskutiert werden. Handover-Entscheidungen werden auf
Grundlage von Benutzerpräferenzen, Netzwerkeigenschaften und Kontextinformationen
des mobilen Endgeräts getroffen. Eine Verbindung wird nur dann auf eine neue
Schnittstelle umgestellt, wenn diese mit dem neu gewählten Netzwerk in Verbindung
steht und entsprechend konfiguriert ist. Für die Aktualisierung der Identität des
mobilen Knotens wird der bekannte Mechanismus „Network Address Translation“
(NAT) wesentlich erweitert, was als Dynamic index NAT (DiNAT) bezeichnet wird.
Sowohl lokale als auch globale Mobilität werden durch eine hierarchische Bereitstellung
von DiNAT-fähigen Knoten unterstützt, ohne dass hierzu ein Vorwissen oder
die Kooperation der Nachbar-Netzwerke notwendig ist. Viele solcher Knoten können
zur Lastverteilung installiert werden, da die Dissertation einen AuswahlmechanismusWith a variety of new applications and services offered for mobile users of the Internet,
new usage plans and preferences in connectivity to wireless networks might
be desired. Connectivity anywhere and anytime through switching between heterogeneous
wireless networks became common communication scenarios for many users.
To maintain the connectivity for mobile nodes and the continuity of their running
sessions, handover decisions, a proper switching scheme between the wireless interfaces
of the communication device, and the identification of mobile nodes must be
managed. This work presents a vertical handover framework including a mobility
management solution as well. It employs multi-criteria decision algorithms that consider
a wide range of parameters, mainly to support Quality of Service (QoS) for
real-time applications, applies a strategy for stable and soft switching between the
multiple interfaces of the mobile device, and presents a light weight signaling scheme
for address resolution to quickly recover running sessions. The handover decisions are
based on user’s configuration, network attributes, and node’s context information.
A connection is transferred onto a new interface only when it is associated to the
newly selected network and ready to take over the traffic. The identity of the mobile
node is maintained by leveraging the well-known and widely employed Network Address
Translation (NAT) for the purpose of mobility management in a new version
that we call Dynamic index NAT (DiNAT). Local and global mobility are supported
through hierarchical deployment of DiNAT-enabled anchor points, with no need for
pre-knowledge or cooperation of neighbor networks. Many such nodes can be deployed
globally for load sharing and route optimization, where a selection mechanism is used
to choose a suitable anchor node for each session of a mobile node. The dissertation
introduces the proposed approach as a cross-layer system composed of three modules
that handle the mentioned tasks, and provides details on the concept of each. The
network simulator OMNeT++ is used to model the system and test its feasibility, as
compared to a widely adopted solution for mobility management, running real-time
applications while moving
A cross-layer mobility management framework for next-generation wireless roaming
Word processed copy.Includes bibliographical references (leaves 62-64).This thesis proposes a mobility management framework that aims to provide a framework for advanced mobility algorithms that allows the challenges of next-generation roaming to be met. The framework features tools that gather context and content information, guarantee low-level QoS, provide security, and offer link and handoff management. The framework aims to be scalable and reliable for all-IP heterogeneous wireless networks whilst conforming to 4G service requirements
A Seamless Vertical Handoff Protocol for Enhancing the Performance of Data Services in Integrated UMTS/WLAN Network
The Next Generation Wireless Network (NGWN) is speculated to be a unified network composed of several existing wireless access networks such as Wireless Local Area Network (WLAN), Global System for Mobile (GSM), Universal Mobile Telecommunications System (UMTS), Worldwide Interoperability for Microwave Access (WiMAX), and satellite network etc
Estudio de la movilidad en redes de siguiente generación
El continuo avance de las redes de telecomunicaciones nos proporciona cada
vez más facilidades en todos los ámbitos de nuestra vida. En este caso, nos hemos
centrado en el estudio de la movilidad en Redes de Siguiente Generación.
Una parte del presente proyecto se ha realizado en colaboración con Deutsche
Telekom AG, durante una estancia de seis meses trabajando como colaboradora en
sus laboratorios con emplazamiento en Berlín.
El principal objetivo de este proyecto ha sido realizar un estudio sobre los
diferentes estándares y tecnologías que facilitan la movilidad en Redes de
Siguiente Generación. Por ello, en la primera parte se han estudiado los diferentes
grupos de trabajo centrados en este aspecto, así como se ha recabado información
sobre productos y soluciones disponibles en el mercado, para obtener una visión
global de la situación actual.
Como se puede comprobar más adelante, esta primera parte es la más extensa
de todo el documento. Esto se debe a que es, probablemente, la parte más
importante del trabajo, ya que contiene el estudio de los mecanismos que más tarde
nos servirán para dar una solución teórica a los distintos escenarios que se
plantean.
En la segunda parte del proyecto, nos hemos centrado en desarrollar varios
escenarios de interés en sistemas de Redes de Siguiente Generación y aportar, de
forma posterior, posibles soluciones teóricas.
Para finalizar, se han expuesto las conclusiones extraídas como resultado del
trabajo y los aspectos que se podrán tratar sobre el mismo en un futuro próximo.Ingeniería de Telecomunicació
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