Analysis of IPV6 Transition Technologies

Currently IPv6 is extremely popular with companies, organizations and Internet service providers (ISP) due to the limitations of IPv4. In order to prevent an abrupt change from IPv4 to IPv6, three mechanisms will be used to provide a smooth transition from IPv4 to IPv6 with minimum effect on the network. These mechanisms are Dual-Stack, Tunnel and Translation. This research will shed the light on IPv4 and IPv6 and assess the automatic and manual transition strategies of the IPv6 by comparing their performances in order to show how the transition strategy affects network behaviour. The experiment will be executed using OPNET Modeler that simulates a network containing a Wide Area Network (WAN), a Local Area Network (LAN), hosts and servers. The results will be presented in graphs and tables, with further explanation. The experiment will use different measurements such as throughput, latency (delay), queuing delay, and TCP delay.Comment: pages 19-38, Online link: http://airccse.org/journal/cnc/6514cnc02.pd

IPv6: a new security challenge

Tese de mestrado em Segurança Informática, apresentada à Universidade de Lisboa, através da Faculdade de Ciências, 2011O Protocolo de Internet versão 6 (IPv6) foi desenvolvido com o intuito de resolver alguns dos problemas não endereçados pelo seu antecessor, o Protocolo de Internet versão 4 (IPv4), nomeadamente questões relacionadas com segurança e com o espaço de endereçamento disponível. São muitos os que na última década têm desenvolvido estudos sobre os investimentos necessários à sua adoção e sobre qual o momento certo para que o mesmo seja adotado por todos os players no mercado. Recentemente, o problema da extinção de endereçamentos públicos a ser disponibilizado pelas diversas Region Internet registry – RIRs - despertou o conjunto de entidades envolvidas para que se agilizasse o processo de migração do IPv4 para o IPv6. Ao contrário do IPv4, esta nova versão considera a segurança como um objetivo fundamental na sua implementação, nesse sentido é recomendado o uso do protocolo IPsec ao nível da camada de rede. No entanto, e devido à imaturidade do protocolo e à complexidade que este período de transição comporta, existem inúmeras implicações de segurança que devem ser consideradas neste período de migração. O objetivo principal deste trabalho é definir um conjunto de boas práticas no âmbito da segurança na implementação do IPv6 que possa ser utilizado pelos administradores de redes de dados e pelas equipas de segurança dos diversos players no mercado. Nesta fase de transição, é de todo útil e conveniente contribuir de forma eficiente na interpretação dos pontos fortes deste novo protocolo assim como nas vulnerabilidades a ele associadas.IPv6 was developed to address the exhaustion of IPv4 addresses, but has not yet seen global deployment. Recent trends are now finally changing this picture and IPv6 is expected to take off soon. Contrary to the original, this new version of the Internet Protocol has security as a design goal, for example with its mandatory support for network layer security. However, due to the immaturity of the protocol and the complexity of the transition period, there are several security implications that have to be considered when deploying IPv6. In this project, our goal is to define a set of best practices for IPv6 Security that could be used by IT staff and network administrators within an Internet Service Provider. To this end, an assessment of some of the available security techniques for IPv6 will be made by means of a set of laboratory experiments using real equipment from an Internet Service Provider in Portugal. As the transition for IPv6 seems inevitable this work can help ISPs in understanding the threats that exist in IPv6 networks and some of the prophylactic measures available, by offering recommendations to protect internal as well as customers’ networks

PROTOKÓŁ IPv6 - CHARAKTERYSTYKA I PROPONOWANE METODY WDROŻENIA W ISTNIEJĄCYCH SIECIACH IPv4 KORZYSTAJĄCYCH Z ROUTERÓW CISCO

The article constitutes an introduction to IPv6 protocol and is a review of the existing approaches to ensure the coexistence of IPv6 and IPv4, on the example of homogeneous Cisco network infrastructure. In the first paragraph, the IPv6 protocol has been characterized and compared to the IPv4. Then, concepts connected with IPv6 addressing have been described. As the main part, it has been discussed methods to provide the coexistence of the two IP protocols. It has been characterized the primary option which is the dual stack, two types of both point to point and multipoint tunnels and finally - address translation NAT-PT.Artykuł stanowi wprowadzenie do protokołu IPv6 oraz jest przeglądem istniejących podejść dla zapewnienia współistnienia IPv6 i IPv4, na przykładzie homogenicznej infrastruktury sieciowej Cisco. W pierwszym rozdziale scharakteryzowano protokół IPv6 i porównano go z IPv4. Następnie opracowano koncepcje związane z adresowaniem IPv6. W głównej części opisano metody do zapewnienia koegzystencji dwóch protokołów IP. Scharakteryzowano podstawową opcję jaką jest podwójny stos, po dwa rodzaje tunelowania punkt-punkt i punkt-wielopunkt oraz w końcu translację adresów NAT-PT

Implementação de mecanismos de transição e coexistência dos protocolos IPV4-IPV6 nos centros de computação de alto desempenho suportados pelas redes acadêmicas

El presente documento pretende contextualizar al lector sobre algunos de los mecanismos que existen para la transición de IPv4-IPv6 y evidencia algunos aspectos que se deben tener en cuenta al momento de evaluar e implementar algunos de ellos, específicamente en centros de computación de alto desempeño y en redes académicas para el apoyo de proyectos de investigación. También se pretende mostrar la implementación y soporte de IPv6 en plataformas tecnológicas e-learningThis document aims to contextualize the reader about some of the mechanisms that currently exist for IPv4-IPv6 transition and evidence some aspects that must be taken into account when evaluating and implementing some of them, specifically in centers of high performance computing and academic networks to support research projects. It also aims to show the implementation and support of IPv6 in e-learning technology platforms.Este documento tem como objetivo contextualizar o leitor sobre alguns dos mecanismos que existem para a transição do IPv4 para o IPv6 e evidenciar alguns aspectos que devem ser considerados na avaliação e implementação de qualquer um deles, especificamente nos centros de computação de alto desempenho e redes acadêmicas para apoiar projetos de pesquisa.  Ainda se pretende mostrar a implementação e o suporte de IPv6 em plataformas tecnológicas e-learning

ANALYSIS OF IPV6 TRANSITION TECHNOLOGIES

ABSTRAC

IPv6 : prospects and problems : a technical and management investigation into the deployment of IPv6

Masteroppgave i informasjons- og kommunikasjonsteknologi 2003 - Høgskolen i Agder, GrimstadIPv4 has been used for over twenty years, and will most likely be used in many years ahead. However, we are now experiencing that the IPv4 address space is running out, resulting in restrictions on who will be able to get these types of addresses assigned to them. Methods such as Network Address Translator (NAT) have been developed and implemented in order to save the IPv4 address space. It is said that this is not a good enough solution, as such techniques introduce new problems at the same time solving some. A new version of the Internet Protocol, IPv6, has been developed and is likely to replace IPv4. IPv6 has been developed to solve the address problem, but also new features are designed to supposedly enhance network traffic. In our thesis we give an overview of the problems with IPv4. This includes the limited address space and the limited quality of service. Further we present the features of IPv6 that are meant to solve these problems and add new possibilities. These are: New address format, the IPv6 header and Extension headers to mention some. Further we have investigated and here present how the transition from IPv4 to IPv6 is expected to take place, followed by a thorough description of the transition mechanisms. One of the original intentions on the development of IPv6 was that IPv4 and IPv6 have to be able to coexist for a long period of time. Transition mechanisms have therefore been designed to make this possible. There are three main types of mechanisms: - Tunnelling - Translation - Dual-stack. Each of these mechanisms requires different configuration and implementations in hosts and network. Technical research on transition mechanisms states that these are not good enough for all IPv6/IPv4 scenarios and need improvements in order to make IPv4 and IPv6 coexist smoothly. There are a lot of transition mechanisms that are agreed upon as being good for general use and then there are transition mechanisms that are good for certain scenarios and not for others. Some scenarios still lack a good translation mechanism. As a result of this, IPv6 networks are being built separately from IPv4 networks. In Asia commercial IPv6 networks are offered, while the process is slower in other parts of the world. The reasons for not building IPv6 networks are many, and not agreed upon. Some believe it is because of economical restrictions, while others claim it is technical reasons and that it exists far too few applications supporting IPv6. The number of IPv6 enabled applications is growing. Large companies like; Microsoft Corporation, Cisco Systems Inc, Apple Computers Inc., Sun Microsystems Inc and various versions of Linux include support for IPv6. The deployment of IPv6 is expected to happen at different times in different parts of the world. We have investigated the status of IPv6 globally and in Norway. The main results are that the roll-out has reached the furthest in Asia where commercial IPv6 networks already are offered. The activity in Norway is still small, but growing. It was desired to run an experiment in order to prove or disprove some of the information we gathered on how IPv6 interoperates with IPv4, but because of limitations in the network at Heriot-Watt University we were not able to do this. Instead we have focused on a project by Telenor R&D; “IPv6 migration of unmanaged networks-The Tromsø IPv6 Pilot”. We also gathered some information from people working at Norwegian ISPs in order to address some of the aspects of the upgrading

Development of a Graduate Course on the Transition to Internet Protocol Version 6

Internet and mobile connectivity has grown tremendously in the last few decades, creating an ever increasing demand for Internet Protocol (IP) addresses. The pool of Internet Protocol version 4 (IPv4) addresses, once assumed to be more than sufficient for every person on this planet, has reached its final stages of depletion. With The Internet Assigned Numbers Authority’s (IANA) global pools depleted, and four of the five Regional Internet Registries (RIR) pools down to the their last /8 block, the remaining addresses will not last very long. In order to ensure continuous growth of the internet in the foreseeable future, we would need a newer internet protocol, with a much larger address space. Specifically, with that goal in mind the Internet Protocol version 6 (IPv6) was designed about two decades ago. Over the years it has matured, and has proven that it could eventually replace the existing IPv4. This thesis presents the development a graduate level course on the transition to IPv6. The course makes an attempt at understanding how the new IPv6 protocol is different than the currently used IPv4 protocol. And also tries to emphasize on the options existing to facilitate a smooth transition of production networks from IPv4 to IPv6

Network performance evaluation of 6to4 tunneling

Several types of IPv6 transition mechanisms have been developed to facilitate the migration of IPv4 to the new protocol, IPv6. Although all transition mechanisms have the same objective, the process necessitates compliance with their respective capabilities. This paper focuses on the evaluation of the transition mechanisms namely 6to4 tunneling in terms of data transmission. The assessment is based upon experimental work that is conducted on a controlled environment. User-to-user network performance software is used to obtain the throughput, round trip time and tunneling overhead for TCP and UDP transmission protocol. The performance of TCP and UDP through 6to4 tunnel is then compared over the native IPv4 and IPv6 environment. As a result, the findings prove the ease of TCP data transmission via the tunnel compared to both native networks. In contrast, the UDP implementations show the slight difference for them. © 2012 IEEE

Implementation of IPv6

On 14 September 2012 last block of IPv4 has been allocated from the Regional Internet Register (RIR) across the Europe, Middle East and Asia. In addition, the demand of further addresses, security and efficient routing across Internet has been increasing every day. Hence, to provide the abundant IP addresses and also to overcome the shortcoming of IPv4, IETF developed a new protocol IPv6. IPv6 overcome the limitations of IPv4 and integrate advance feature. These advanced improvements include larger address space, more efficient addressing and routing, auto-configuration, security, and QOS. The main objective of this project was to implement IPv6 network in Cisco laboratory of Rovaniemi University of Applied Sciences (RAMK). Cisco 2800 and 1700 Series routers, 3500 series Cisco Catalyst Switches, Microsoft Server 2012, Windows 7, Windows 8 and finally Mac OS X were used during implementation process. This project covers the implementation of IPv6, DHCPv6, DNS, Routing Protocols EIGRP, and Security. The goal of the project was to implement IPv6 to existing IPv4 network without affecting the running services. Furthermore, this project was implementation in Local Area Network (LAN) only

An analysis of the risk exposure of adopting IPV6 in enterprise networks

The IPv6 increased address pool presents changes in resource impact to the Enterprise that, if not adequately addressed, can change risks that are locally significant in IPv4 to risks that can impact the Enterprise in its entirety. The expected conclusion is that the IPv6 environment will impose significant changes in the Enterprise environment - which may negatively impact organisational security if the IPv6 nuances are not adequately addressed. This thesis reviews the risks related to the operation of enterprise networks with the introduction of IPv6. The global trends are discussed to provide insight and background to the IPv6 research space. Analysing the current state of readiness in enterprise networks, quantifies the value of developing this thesis. The base controls that should be deployed in enterprise networks to prevent the abuse of IPv6 through tunnelling and the protection of the enterprise access layer are discussed. A series of case studies are presented which identify and analyse the impact of certain changes in the IPv6 protocol on the enterprise networks. The case studies also identify mitigation techniques to reduce risk