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

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Design and implementation of multicast listener discovery protocol on constrained devices

Para la aplicación y apoyo del uso de IPv6 en 6LoWPANs (Low-power Wireless Personal Area Networks), ha habido numerosas investigaciones y se han desarrollado protocolos y mecanismos estandarizados. Sin embargo para la comunicación multicast en estas redes, el tema esta aún bastante abierto a la investigación. La comunicación multicast permite conectar routers con hosts preseleccionados por grupos. La comunicación multicast es muy beneficiosa para aplicaciones con dispositivos con recursos limitados ya que ahorra energía y ancho de banda. A continuación mostramos posibles ejemplos de estas aplicaciones, la iluminación de un edificio organizada por plantas, una red de sensores de temperatura organizados por áreas y un largo número de aplicaciones basadas en la comunicación de un punto a varios puntos preseleccionados. El grupo de investigación de la universidad de Aalto (Finlandia) llamado MAMMoTH (Massive Scale Machine-to-Machine Service) tiene como uno de sus objetivos construir un protocolo multicast para dispositivos con recursos limitados. Para el desarrollo de este protocolo, es necesario un protocolo de encaminamiento multicast y un protocolo de gestión de grupos multicast. Este último, es el protocolo que he desarrollado como “research assistant” para mi proyecto final de carrera. En este proyecto final de carrera, se ha diseñado, implementado y evaluado el protocolo MLD para dispositivos con recursos limitados. MLD permite a un router IPv6 gestionar grupos multicast. No obstante, el uso de MLD en LoWPANs tiene varios problemas como la definición del area local, el tamaño de los paquete y la complejidad del comportamiento del router. El protocolo ha sido implementado en Contiki, un sistema operativo para desarrollar para el “Internet of Things”. Contiki permite conectar sistemas pequeños de poco coste con poca potencia a Internet. Hemos ampliado la pila TCP/IP de Contiki para respaldar MLD. El protocolo ha sido evaluado y analizado sobre un simulador en diferentes topologías para validar el funcionamiento. Del mismo modo, también se ha verificado que el tamaño del objeto creado no ocupaba más memoria de la disponible en los dispositivos Z1 Zolertia

Progressive introduction of network softwarization in operational telecom networks: advances at architectural, service and transport levels

Technological paradigms such as Software Defined Networking, Network Function Virtualization and Network Slicing are altogether offering new ways of providing services. This process is widely known as Network Softwarization, where traditional operational networks adopt capabilities and mechanisms inherit form the computing world, such as programmability, virtualization and multi-tenancy. This adoption brings a number of challenges, both from the technological and operational perspectives. On the other hand, they provide an unprecedented flexibility opening opportunities to developing new services and new ways of exploiting and consuming telecom networks. This Thesis first overviews the implications of the progressive introduction of network softwarization in operational networks for later on detail some advances at different levels, namely architectural, service and transport levels. It is done through specific exemplary use cases and evolution scenarios, with the goal of illustrating both new possibilities and existing gaps for the ongoing transition towards an advanced future mode of operation. This is performed from the perspective of a telecom operator, paying special attention on how to integrate all these paradigms into operational networks for assisting on their evolution targeting new, more sophisticated service demands.Programa de Doctorado en Ingeniería Telemática por la Universidad Carlos III de MadridPresidente: Eduardo Juan Jacob Taquet.- Secretario: Francisco Valera Pintor.- Vocal: Jorge López Vizcaín

Development of a multicast routing protocol for low power and lossy networks

The Internet of things (IoT) is a new paradigm that has been gaining popularity in recent years. As the name "Internet of things" suggests, things surrounding us will be able to interact with each other and also connect to the Internet, thus forming a worldwide network of connected objects. The number of potential applications of this concept is huge and indudes various domains such as home environment, transportation, healthcare and so on. To enable the Internet of things, different technologies and standards have been proposed. Among them, the IP for Smart Objects (IPSO) alliance promotes the use of Internet Protocol (IP) as the network technology for IoT. The Internet Engineering Task Force (IETF), as part of its IoT related activities, has been working on using IPv6 to connect devices in low power wireless personal area networks (LoWPANs). The devices operating in LoWPANs are constrained on resources such as memory, processing power and sometimes energy (in case, they are operating on battery). Hence protocols designed for such networks have to consider the limitations of the devices. There has been considerable research done to design protocols that enable and support IPv6 in LoWPANs. However, there is not much effort in the area of multicast communication. There are various scenarios where efficient multicast communication would be beneficial. For example, consider a group of lights in a room that can be controlled by an actuator. In such scenarios, well designed multicast protocols would be useful in saving resources of the nodes. In this thesis, we design and implement a multicast routing protocol for low power and lossy networks. The protocol is implemented on Contiki OS, an operating system developed for the Internet of things. In addition, we test this protocol using Cooja, a cross-layer simulator developed for Contiki OS

A new framework for minimising handover in multicast mobility

Nowadays, mobile devices support a variety of multimedia applications such as live video, radio or online gaming. People spend their time on mobile devices for entertainment more and more via the internet. Due to the requirements of multimedia applications over wireless communication those applications require a huge bandwidth on the network to support them, which creates problems for the network provider. However, one pattern that is appropriate for the efficient delivery of multimedia messages is multicast delivery.Multicast services do, however, introduce challenges within the network when the recipients of the service are moving. Powerful multicast routing protocols are designed for static client IP addresses. Hence, when the mobile node changes the location, it introduces the problem of access network handover. Therefore, this is the aim of the research where a new framework will be developed for multicast mobility within WiFi network to reduce and provide smooth mobility when handover occurs. This research is focused on techniques to reduce handover latency, minimize packet loss and provide connection when a user moves between network zones.To achieve these aims, this designed framework lets mobile nodes send the message to register to foreign agents in advance for addressing IP address of the new zone and to establish the multicast tree earlier. Moreover, there are processes that keep the connection of the path alive.The framework is being simulated on OPNET Modeler for evaluating the performance in terms of handover latency time, the number of packet loss and so on. There are many scenarios that have been tested. According to the results, it shows that the new framework has reduced handover latency time around 60% on average and minimized packet delay approximately 0.7 - 150 ms on mobile node depending on network topology. This framework can provide IP address reconfiguration, binding update, joining multicast group and distribution path of multicast tree in advance. However, there are some overheads and cost that this framework has to pay for such as IP address database, increasing broadcast within networks and keeping connection path alive

Scalability Improvement Of Multicast Source Movement Over Mobile Ipv6 Using Clustering Technique

Mobile IPv6 (MIPv6) describes how a mobile node can change its point of attachment to the Internet. While MIPv6 focuses on unicast communications, it also proposes two basic mechanisms, known as bi-directional tunnelling and remote subscription, to handle multicast communications with mobile members. In the mean time, the deployment of Source-Specific Multicast (SSM) is of great interest, using the Protocol Independent Multicast-Sparse Mode (PIM-SM) and Multicast Listener Discovery (MLDv2) protocols. In the particular case of mobile IPv6 SSM sources, the mechanism proposed in MIPv6 to support multicast communications introduced a number of problems that need to be addressed. First, in most scenarios the MIPv6 solution leads to suboptimal routing by setting up a tunnel to forward packets between the home agent in its home network and the current location in the foreign network. The use of a third party when roaming which is the home agent leads to suboptimal routing. Second, it introduces a central point of failure (i.e. the Home Agent (HA)) that is not to be neglected. The proposed MIPv6 solution also induces a great traffic concentration around this central point. Third, the processing task of the central point increases with the number of mobile sources it serves, thus reducing the efficiency of multicast delivery. The objective of this thesis is to remove some of the obstacles encountered in the way of multicast deployment in the Internet, thereby making Mobile IPv6 better equipped to support mobile SSM sources. Recent proposals to provide multicasting over mobile IP focuses mainly on recipient mobility but little attention has been given to the case of source mobility. This thesis attempts to address this problem. The basic essence of the problem is that while the effect of receiver movement on the multicast tree is local, the effect of source movement may be global and it may affect the complete multicast delivery tree. The initial design was motivated by the need to support one-to-many and many-to-many applications in a scalable fashion. Such applications cannot be serviced efficiently with unicast delivery. As the overall problem statement of “Scalability Improvement of Multicast Source Movement over IPv6 Using Clustering Technique” is extremely complex, we divide the problem into the following components: build the multicast delivery tree for source specific multicast which is a routing issue; clustering receivers based on their IPv6 addresses; improve the state scalability of these clusters which is a deployment issue; find an efficient way for service distribution which is a deployment issue as well; and finally, the seamless integration of the work with Mobile IPv6 allowing it to support multicast efficiently for mobile nodes. The combined solution provides a comprehensive procedure for planning and managing a multicast-based IPv6 network. The outcome of this thesis are: a software to represent an architecture of a multicast delivery tree for one-to-many type of group communication, a group management scheme that could handle the end nodes subscription/un-subscription process with the required updates, an average subscription delay of between 0.255 ms-0.530 ms and un-subscription delay of between 0.0456 ms-0.087 ms for up to 50000 nodes, an approach to multicast forwarding state reduction that could support small-size groups as well as large-size groups, and finally the integration of the work with Mobile IPv6 to handle the multicast source movement

IP Mobile Multicast over Next Generation Satellite Networks. Design and Evaluation of a Seamless Mobility Framework for IP Multicast Communications over a Multi-beam Geostationary Satellite Network

The inherent broadcast nature of satellites, their global coverage and direct access to a large number of subscribers give satellites unrivalled advantages in supporting IP multicast applications. A new generation of satellite systems that support regenerative on-board processors and multiple spot beam technology have opened new possibilities of implementing IP multicast communication over satellites. These new features enable satellites to make efficient use of their allocated bandwidth resources and provide cost effective network services but equally, create new challenges for mobile satellite terminals. IP mobility support in general and IP mobile multicast support in particular on mobile satellite terminals like the ones mounted on continental flights, maritime vessels, etc., still remain big challenges that have received very little attention from the research community. Up till now, there are no proposed mechanisms to support IP multicast for mobile receivers/sources in multi-beam satellite networks in open literature. This study explores the suitability of IP multicast mobility support schemes defined for terrestrial networks in a satellite environment and proposes novel schemes based on the concepts of Home and Remote subscription-based approaches, multiple interface and PMIPv6 protocol. Detailed analysis and comparison of results obtained from the proposed schemes, Mobile IP (MIP) Home and Remote subscription-based approaches (for terrestrial networks) when implemented on a reference multi-beam satellite network are presented. From these results, the proposed schemes outperform the MIP Home and Remote subscription-based approaches in terms of gateway handover latency, number of multicast packets lost and signalling cost over the satellite air interface

Multicast-Based Mobile Ipv6 Join/Leave Mechanism Software

Increasing demand for mobility in the Internet has created the need for a routing protocol that allows a host to roam in the network. Mobile IP is a solution that enables an IP host to leave its home link while transparently maintaining all of its present connections and remaining reachable to the rest of the Internet. The Internet Engineering Task Force (IETF) has standardized Mobile IPv4. Mobile IPv6 is a work in progress in the IETF, offering support for IPv6 mobile nodes. Although it is not yet standardized, every IPv6 node is required to implement Mobile IPv6, which means that mobility must be widely supported. IP-multicast provides efficient algorithms for multiple packet delivery. It also provides location-independent group addressing. The receiver-initiated approach for IP-multicast enables new receivers to join to a nearby branch of an already established multicast tree. Hence, IP-multicast provides a scalable infrastructure for efficient, location-independent, packet delivery.The recent advances in wireless communication technology and the growth of the Internet have paved the way for wireless networking and IP mobility. Unlike conventional wired networks, wireless networks possess different channel characteristics and mobility dynamics that render network design and analysis more cha1lenging. Performance during handoff where the mobile moves from one cell, or coverage area, to another is a significant factor in evaluating wireless networks

ICMPv6 Echo Request Ddos Attack Detection Framework Using Backpropagation Neural Network

Pertumbuhan pesat Internet dalam beberapa tahun kebelakangan ini telah mendedahkan had ruang alamat dalam protokol Internet semasa (IP), iaitu, IPv4. Permintaan yang semakin meningkat dalam penggunaan alamat IP telah mengakibatkan kehabisan alamat IPv4 seperti yang dijangkakan. Untuk menangani kebimbangan ini, IPv6 baru telah dibangunkan untuk menyediakan ruang alamat yang mencukupi. IPv6 dimuatkan dengan protokol baru, iaitu, versi Protokol Mesej Kawalan Internet 6 (ICMPv6), dan protokol baru ini membuka pintu bagi penyerang untuk menyerang rangkaian IPv6. Salah satu jenis serangan yang paling kerap dalam rangkaian IPv6 pada lapisan rangkaian adalah satu serangan banjir ICMPv6 DoS / DDoS. Laporan Arbor Network pada tahun 2014 menunjukkan bahawa ancaman terhadap IPv6 semakin meningkat (72% merupakan kebanjiran trafik/serangan DDoS). Di samping itu, ICMPv6 adalah protokol wajib dalam rangkaian IPv6 tidak seperti dalam IPv4, iaitu ICMP boleh disekat atau diturunkan melalui get laluan lalai. The rapid growth of the Internet in the last few years have exposed the limitation of address space in the current Internet protocol (IP) namely IPv4, due to the increasing consumption of IP addresses. The IPv6 has been developed to provide sufficient address space. It ships with a new protocol. i.e., the Internet Control Message Protocol version 6 (ICMPv6), this protocol is a mandatory protocol in IPv6 networks unlike in IPv4, in which ICMP can be blocked or dropped. ICMPv6 opens the door for attackers to attack IPv6 networks. The most frequent types of attack in IPv6 networks at the network layer is an ICMPv6 DDoS flooding attack. One of the main problem in ICMPv6 DDoS flooding attacks is accuracy detection, which suffers from a high false alarm rate. Thus, protecting infrastructure service is a critical issue that urgently needs to be addressed