Roaming Real-Time Applications - Mobility Services in IPv6 Networks

Emerging mobility standards within the next generation Internet Protocol, IPv6, promise to continuously operate devices roaming between IP networks. Associated with the paradigm of ubiquitous computing and communication, network technology is on the spot to deliver voice and videoconferencing as a standard internet solution. However, current roaming procedures are too slow, to remain seamless for real-time applications. Multicast mobility still waits for a convincing design. This paper investigates the temporal behaviour of mobile IPv6 with dedicated focus on topological impacts. Extending the hierarchical mobile IPv6 approach we suggest protocol improvements for a continuous handover, which may serve bidirectional multicast communication, as well. Along this line a multicast mobility concept is introduced as a service for clients and sources, as they are of dedicated importance in multipoint conferencing applications. The mechanisms introduced do not rely on assumptions of any specific multicast routing protocol in use.Comment: 15 pages, 5 figure

Multicast Mobility in Mobile IP Version 6 (MIPv6) : Problem Statement and Brief Survey

Publisher PD

On the security of the Mobile IP protocol family

The Internet Engineering Task Force (IETF) has worked on\ud network layer mobility for more than 10 years and a number\ud of RFCs are available by now. Although the IETF mobility\ud protocols are not present in the Internet infrastructure as of\ud today, deployment seems to be imminent since a number\ud of organizations, including 3GPP, 3GPP2 and Wimax, have\ud realized the need to incorporate these protocols into their architectures.\ud Deployment scenarios reach from mobility support\ud within the network of a single provider to mobility support\ud between different providers and technologies. Current Wimax\ud specifications, for example, already support Mobile IPv4,\ud Proxy Mobile IPv4 and Mobile IPv6. Future specifications will\ud also support Proxy Mobile IPv6. Upcoming specifications in\ud the 3GPP Evolved Packet Core (EPC) will include the use of\ud Mobile IPv4, Dual Stack MIPv6 and Proxy Mobile IPv6 for\ud interworking between 3GPP and non 3GPP networks.\ud This paper provides an overview on the state-of-the-art\ud in IETF mobility protocols as they are being considered by\ud standardization organizations outside the IETF and focusing\ud on security aspects

Analysis of Handoff Latency in Advanced Wireless Networks

The association of different wireless communication technologies on the way to advanced wireless networks had better face with the developing systems resource utilization and user authentication. Mobility management is vital to omnipresent computing which can be established by location management and distinctive of the mobility management modules. In this work the new protocol is proposed which includes the integration of FHMIPv6 and MIH. The proposed protocol performance is analysed using NS2 simulation. It shows the reduction of handoff latency for video streaming. The cost is also being reduced by the handoff latency while transmitting the signal from one mobile user to another. Further the proposed protocol is compared with the previous protocols

An overview of internet engineering task force mobility management protocols: approaches and its challenges

In recent years, internet protocol mobility management has become one of the most popular research areas in networking. Mobility management protocols are in charge of preserving continuing communications as a user roam between different networks. All existing internet protocols (IP), like MIPv6, and PMIPv6, rely on a centralized mobility anchor to control mobile node traffic and signaling. The disadvantages of centralized mobility management (CMM) include ineffectiveness in handling massive volumes of traffic, poor scalability, wasteful use of network resources, and packet delay. When CMM is required to handle mobile media, which demands a huge amount of information and frequently needs quality of services (QoS) such as session continuance and reduced latency, these difficulties become apparent. It drives the need for distributed mobility management protocol (DMM) systems to manage the growing amount of mobile data, the overwhelming of this is video communication. DMM approaches could be regarded as an innovative and effective method to deal with mobility. An overview of the CMM protocol and its drawbacks are analyzed. This study examines the various DMM protocol techniques and their performance metrics are compared to highlight similarities and differences. The study reveals the network-based DMM protocol improves overall handoff time and packet loss

A hybrid network/host mobility management scheme for next generation networks

Includes bibliographical references.The author proposes a hybrid network/host interworking scheme to allow the MN to transition smoothly between different access networks supporting two distinct mobility approaches

Implementación de un sistema SDN para la movilidad en redes OMNIRAN

This document details all the information needed to understand and test distributed mobility management using the SDN paradigm. This project stars by an analysis of the mobility problem in dense networks. Traditionally mobility has been managed with hierarchical approaches extending the current mobility protocols. But thinking in the future evolution of the network into dense environments some scalability problems appear. The traditional centralized elements may not be able to handle all the traffic in the network and bottlenecks appear at the Mobility Anchors. Nowadays, the problems related to scalability are mostly resolved with hardware upgrades, but in dense environments this couldn’t be enough and surely it would be quite expensive. To find a solution to this problem the IETF has chartered the Distributed Mobility Management (DMM) Group.This project focus on implementing a DMM-based mobility solution designed within the EU FP7 CROWD project. Once the analysis of the problem ended and the requirements of the theoretical solution were defined, we developed all the necessary elements to physically build a distributed network using SDN to manage layer 2 and layer 3.The entities of the network are defined by the CROWD projectin its related publications[9][10]. These districts were run using an SDN implementation called OpenFlow. With all the elements developed we proceed to perform the necessary tests in order to evaluate the distributed mobility management as a solution. This document explains the full design, execution and validationprocesses. Finally all the measurements and statistical data are detailed in order to have an approximation of the services that could achieve the developed network.Ingeniería Telemátic