Academic literature on the topic 'Ipv6'

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Journal articles on the topic "Ipv6"

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Musbah, Esra Musbah Mohammed, Khalid Hamed Bilal, and Amin Babiker A. Nabi Mustafa. "Comparison of QoS Performance Over WLAN, VoIP4 and VoIP6." International Research Journal of Management, IT & Social Sciences 2, no. 11 (November 1, 2015): 42. http://dx.doi.org/10.21744/irjmis.v2i11.80.

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VoIP stands for voice over internet protocol. It is one of the most widely used technologies. It enables users to send and transmit media over IP network. The transition from IPv4 to IPv6 provides many benefits for internet IPv6 is more efficient than IPv4. This paper presents a performance analysis of VoIP over WLAN using IPv4 and IPv6 and OPNET software program to simulate the protocols and to investigate the QoS parameters such as jitter, delay variation, packet send, and packet received and throughputs for IP4 and IP6 and compare between them.
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YURY, Halavachou, and Yubian Wang. "Research on IPv4, IPv6 and IPV9 Address Representation." International Journal of Advanced Network, Monitoring and Controls 4, no. 2 (2019): 48–60. http://dx.doi.org/10.21307/ijanmc-2019-047.

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Kim, Jeong-Su. "IPv6 Migration, OSPFv3 Routing based on IPv6, and IPv4/IPv6 Dual-Stack Networks and IPv6 Network: Modeling, and Simulation." KIPS Transactions:PartC 18C, no. 5 (October 31, 2011): 343–60. http://dx.doi.org/10.3745/kipstc.2011.18c.5.343.

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RAHMIATI, PAULINE, DWI ARYANTA, and TAUFIQ AGUNG PRIYADI. "Perancangan dan Analisis Perbandingan Implementasi OSPF pada Jaringan IPv4 dan IPv6." ELKOMIKA: Jurnal Teknik Energi Elektrik, Teknik Telekomunikasi, & Teknik Elektronika 2, no. 1 (January 1, 2014): 40. http://dx.doi.org/10.26760/elkomika.v2i1.40.

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ABSTRAKOSPF (Open Shortest Path First) adalah suatu routing protokol bersifat terbuka dan didukung oleh berbagai perangkat network. IPv4 telah mencapai batas maksimum dalam jumlah alamat sehingga IPv6 merupakan solusi dalam hal tersebut. Seperti IPv4, IPv6 juga sudah mulai diimplementasikan untuk routing protokol OSPF, oleh karena itu pada penelitian ini akan dirancang suatu routing protokol OSPF IPv6 dan sebagai bahan perbandingan akan dibandingkan dengan OSPF IPv4. Software Cisco Packet Tracer 5.3 digunakan untuk mensimulasikan perancangan jaringan yang dibuat. Pada penelitian ini akan dibandingkan 2 buah jaringan berbasis routing protokol OSPF, yaitu OSPF untuk IPv4 dan IPv6. Skenario pertama dilakukan 100 kali dalam 5 kasus untuk mengetahui nilai delay OSPF IPv4 dan OSPF IPv6. Skenario kedua dilakukan pemutusan link dilakukan sebanyak 30 kali, hal yang dilihat dari pengujian ini adalah hasil trace route dari cost yang ada. Skenario ketiga dilakukan dengan mengamati waktu konvergensi dari OSPF IPv4 dan IPv6. Secara keseluruhan nilai delay OSPF IPv6 lebih kecil dibandingkan dengan OSPF IPv4 sebesar 3-6%, Trace route dan nilai cost pada OSPF IPv6 dan OSPF IPv4 sama tetapi nilai delay OSPF IPv6 lebih kecil sebesar 3-6% dan waktu konvergensi OSPF IPv4 bernilai sama dengan OSPF IPv6 yaitu 10 detik.Kata kunci: OSPF, IPv4, Ipv6, delay, konvergensiABSTRACTOSPF (Open Shortest Path First) is a routing protocol that opened and supported by a wide range of network devices. IPv4 has reached the maximum limit on the number of addresses that IPv6 are a solution in this case. Same as IPv4, IPv6 also has begun to be implemented for the OSPF routing protocol, therefore this study wiould design an IPv6 OSPF routing protocol and as a comparison will be compared to IPv4 OSPF. Cisco Packet Tracer 5.3 software was used to simulate the made network design. This research would compare two pieces of network-based routing protocol OSPF, OSPF for IPv4 and IPv6. The first scenario was done 100 times in of 5 cases to determine the value of delay OSPF OSPF IPv4 and IPv6. The second scenario was carried out link terminations 30 times, it was seen from the tests was the result of trace route from the existing cost. The third scenario was done by observed at the convergence time of OSPF IPv4 and IPv6. The overall delay value OSPF IPv6 better than IPv4 OSPF by 3-6%, the trace route and the OSPF cost value of IPv6 and IPv4 OSPF were same but delay OSPF IPv6 was better 3-6% and convergence time was the same as IPv4 OSPF OSPF IPv6 as 10 seconds.Keywords: OSPF, IPv4, IPv6, delay, convergence
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Babik, Marian, Martin Bly, Nick Buraglio, Tim Chown, Dimitrios Christidis, Jiri Chudoba, Phil DeMar, et al. "Overcoming obstacles to IPv6 on WLCG." EPJ Web of Conferences 295 (2024): 07036. http://dx.doi.org/10.1051/epjconf/202429507036.

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The transition of the Worldwide Large Hadron Collider Computing Grid (WLCG) storage services to dual-stack IPv6/IPv4 is almost complete; all Tier-1 and 94% of Tier-2 storage are IPv6 enabled. While most data transfers now use IPv6, a significant number of IPv4 transfers still occur even when both endpoints support IPv6. This paper presents the ongoing efforts of the HEPiX IPv6 working group to steer WLCG toward IPv6-only services by investigating and fixing the obstacles to the use of IPv6 and identifying cases where IPv4 is used when IPv6 is available. Removing IPv4 use is essential for the long-term agreed goal of IPv6-only access to resources within WLCG, thus eliminating the complexity and security concerns associated with dual-stack services. We present our achievements and ongoing challenges as we navigate the final stages of the transition from IPv4 to IPv6 within WLCG.
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Marzuki, Imam. "Mekanisme Transisi IPv4 dan IPv6 Menggunakan Metode Automatic Tunneling Pada Jaringan Client Server Berbasis Linux." Jurnal Teknologi Informasi Indonesia (JTII) 3, no. 2 (April 12, 2019): 68–73. http://dx.doi.org/10.30869/jtii.v3i2.311.

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Abstrak - Alamat IP merupakan jantung sebuah jaringan komputer. Hal ini dikarenakan komputer yang terhubung ke jaringan memerlukan IP untuk saling berkomunikasi. Tanpa alamat IP, komputer tersebut tidak dapat saling bertukar data. Alamat IP yang biasa digunakan yaitu IPv4. Namun IPv4 telah digunakan lebih dari 20 tahun dan diperkirakan akan habis seiring dengan bertambahnya pengguna internet di dunia. Perkembangan dari IPv4 adalah IPv6. IPv6 menyediakan alamat IP yang jauh lebih banyak dan tidak akan habis. Dengan demikian, untuk mengatasi permasalahan IPv4 yang memiliki keterbatasan adalah menggunakan IPv6. Permasalahan muncul ketika akan mengimplementasikan IPv6. Implementasi tidak serta merta dilakukan karena secara langsung IPv6 tidak bisa melakukan interkoneksi dengan IPv4. Hal ini tentunya akan menimbulkan kesalahan pada jaringan IPv4 yang telah ada. Sebagai solusi dari masalah implementasi IPv6, maka diperlukan suatu mekanisme transisi IPv4 ke IPv6 atau sebaliknya. Tujuan pembuatan mekanisme transisi ini adalah supaya paket IPv6 dapat dilewatkan pada jaringan IPv4 yang telah ada ataupun sebaliknya. Metode yang digunakan adalah automatic tunneling. Dari hasil implementasi yang dilakukan paket IPv6 dapat dikirimkan ke jaringan IPv4 tanpa mengubah infrastruktur jaringan IPv4. Kata kunci: alamat IP, infrastruktur IPv4, transisi
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Wang, Kui Fu, Yan Ge Chen, and Jing Tao Xu. "Research of IPv6 Transition Technology and its Department on Campus Network." Advanced Materials Research 457-458 (January 2012): 79–84. http://dx.doi.org/10.4028/www.scientific.net/amr.457-458.79.

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IPv4 and IPv6 coexist in networks for a long time,however careful planning and choosing the right techniques actually make the transition to IPv6 smooth and easy. By introducing IPv4 and IPv6 communications solutions in this paper, we provide the particular deployment on IPv6 campus network, furthermore, we touch on the IPv6 network deployment plan. Researching the key technology of deployment and realizing IPv4 to IPv6 smooth transition.
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Tian, Hong Cheng, and Hong Wang. "Deployment and Exploration of Domain Name System Based on IPv6." Applied Mechanics and Materials 668-669 (October 2014): 1247–52. http://dx.doi.org/10.4028/www.scientific.net/amm.668-669.1247.

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IPv6 is intended to replace IPv4 in the Internet. Domain Name System (DNS) is an essential component of functionality of Internet. This paper presents new IPv6 characteristics, IPv6 DNS hierarchy, working process of IPv6 DNS, IPv6 address types, representation formats of IPv6 address, forward (reverse) resolver of IPv6 DNS, and the DNS transition from IPv4 to IPv6, combined with the practice to build the IPv6 experimental network of Peking University. We give corresponding solutions for the problems encountered in the IPv6 DNS deployment. This paper is of important reference value for IPv6 network researchers and engineers to build IPv6 DNS service in the IPv6 network.
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Ardiansyah, M. Ficky Duskarnaen, and Hamidillah Ajie. "DESAIN DAN IMPLEMENTASI INTERNET PROTOCOL VERSION 6 (IPv6) DI KELAS UNIT PELAYANAN TEKNIS TEKNOLOGI INFORMASI DAN KOMUNIKASI (UPT TIK) UNIVERSITAS NEGERI JAKARTA." PINTER : Jurnal Pendidikan Teknik Informatika dan Komputer 4, no. 1 (June 1, 2020): 30–34. http://dx.doi.org/10.21009/pinter.4.1.7.

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Tujuan dari penelitian ini adalah terciptanya migrasi IPv6 dalam skala kecil yang akan diterapkan pada kelas A Unit Pelayanan Teknis Teknologi Informasi dan Komunikasi yang akan dapat digunakan dengan baik dan optimal. Penelitian ini dilakukan melalui beberapa tahapan yaitu: identifikasi masalah dan pengumpulan data, desain dan implementasi pada IPv6. Pada penerapan IPv6 tidak dapat dilakukan dalam yang singkat karena jaringan IPv4 masih mendominasi dan idenya adalah penerapan IPv6 tanpa merusak infrastruktur yang ada sebelumnya pada IPv4. Oleh karena itu, Unit Pelayanan Teknis Teknologi Informasi dan Komunikasi bertujuan untuk bermigrasi dari IPv4 ke IPv6 dengan Metode Rekaya Teknik.Pada penelitian ini penulis menggunakan teknik dual stack dengan pembanding native IPv4 dan IPv6. Mekanisme transisi gunakan untuk menghubungkan site IPv6 yang terpisah oleh jaringan IPv4 sehingga bisa terkoneksi dengan IPv6 lainnya.Sebelum menerapkan desain dan implementasi pada kelas A, IPv4 dan IPv6 juga diuji ketahanan jaringannya setelah di upload sebanyak 5 kali pada web local media streaming server yang sudah dibangun dengan menggunakan sistem operasi Debian Linux 7.8.0 Analisis penelitian menunjukkan pada bagian transfer rate, Wireshark bertugas untuk melihat semua kinerja-kinerja yang ada pada IPv4 dan IPv6, dengan jenis-jenis file seperti (MP4, MP3 dan JPG) dan ukuran yang berbeda-beda. Berhasilnya menggunakan Dual stack yaitu menggunakan dua jaringan yang berbeda IPv4 dan IPv6 dalam satu interface dalam router agar dapat berjalan dalam waktu yang sama. pada Kelas A Unit Pelayanan Teknis Teknologi Informasi dan Komunikasi. Walaupun dari segi pengambilan data transfer rate IPv4 masih bekerja dengan baik saat ini, akan tetapi tahun yang akan datang IPv6 ini akan banyak yang menerapkannya pada kalangan Universitas dan Institusi lainnya dengan kelebihan-kelebihan yang dimiliki IPv6 ini.
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AbouSalem, Z. Z., and M. A. Ashabrawy. "Compared Between Ipv6 And With Ipv4,Differences And Similarities." INTERNATIONAL JOURNAL OF COMPUTERS & TECHNOLOGY 17, no. 2 (October 29, 2018): 7355–63. http://dx.doi.org/10.24297/ijct.v17i2.7805.

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This paperprovides Advantages of using IPv6 andcomparison of IPv4 and IPv6,For that, it’s critical to understand the differences and similarities, Some points in the near future when the sheer size of billions new devices will throw the IPv6 switch.IPv4 and IPv6, where IPv6 is the enhanced version of IPv4, There are various differences between IPv4 and IPv6 protocol including its features, but the critical one is the number of addresses (Address space) it creates. In my paper, I will explained the main Advantages (differences between both protocols)of IPv6 & IPv4, By giving results that can be obtained through the diffusion of technology.
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Dissertations / Theses on the topic "Ipv6"

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Galla, Lokesh, and Suyesh Regmi. "IPv4-IPv6 Transition Techniques : IPv4 exhaustion." Thesis, Högskolan i Halmstad, Sektionen för Informationsvetenskap, Data– och Elektroteknik (IDE), 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:hh:diva-15999.

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IPv4 exhaustion leads to new IP version, which is IPv6. When changing a network from IPv4 to IPv6, Internet networks will be hybrid by using both IPv4 networks and IPv6 networks. This thesis defines the essential information about compatibility between IPv4-IPv6 mechanisms. Dual Stack is one of the IPv4-IPv6 compatible mechanism by running both IPv4 stack and IPv6 stack in a single node. 6 to 4 tunneling mechanism encrypts IPv6 packets in IPv4 packets to make communications possible, from IPv6 network over IPv4 network. Dual Stack & Tunneling mechanisms were completely implemented later in this thesis work. This thesis examine transmission latency, throughput, jitter and delay from end to end, through empirical observations of both Dual Stack and tunneling mechanisms by using TCP/UDP as transport protocols in different scenarios. This thesis work contains some useful strategic point of view before trying to deploy IPv6 in a network.
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Kintu, Zephernia. "Migrating to IPv6." Thesis, KTH, Kommunikationssystem, CoS, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-96355.

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Today hundreds of millions of users are interconnected by communication channels allowing them to communicate and to share information. These users and the devices that interconnect them are what constitute the Internet. The Internet is a network of networks with a myriad of computer devices, including smartphones, game consoles (handheld/stationary), IP televisions, tablet computers, laptop computers, desktop computers, palmtop computers, etc. This network of computers flourishes because of careful planning and maintenance by Internet Service Providers (ISPs), backbone network operators, and others. An additional factor that enables the Internet to operate is the four logical layers of abstraction in the TCP/IP protocol stack. One of these layers is the layer responsible for the transfer of datagrams/packets from one host to another. This layer is known as the Internet Protocol (IP) layer. However, as originally conceived a 32 bit address was thought to be more than enough. The space of IP addresses was distributed among different regions rather disproportionately, driven largely by the numbers of addresses that were requested (ordered in time). Today after a series of inventions in the field (such as the world wide web) and a rapid growth in the number of devices that wish to connect to the Internet the available unassigned address space has largely been depleted. Regions with large populations, but with few assigned blocks of IP addresses have begun to exhaust all their assigned addresses, while other regions face the same fate in a few months. The need for a larger address space was predicted years ago and the next generation addressing scheme was devised as part of the development of Internet Protocol Version 6 (IPv6). Countries such as China and India had few IPv4 addresses and they have been forced to transition to IPv6 rather quickly. Today a significant number of the users in these countries are unable to communicate over IPv4 networks. The purpose of this thesis project is to discuss the transition to IPv6 and the transition to this new addressing scheme. IPv6 provides a much larger address space, along with a number of additional improvements in comparison to the previous version of IP (i.e., IPv4). Despite the advantages of adopting IPv6, the incentive to transition is low amongst well established businesses, especially those in regions that received a considerable number of IPv4 addresses initially. Instead different techniques have been employed in these places to mitigate the problem of IPv4 address exhaustion. It is also probable that this reluctance is a way to keep competing businesses out of the market for a while longer. This thesis aims to facilitate the transition from IPv4 to IPv6.
Miljontals användare är idag sammankopplade genom kommunikationskanaler som tillåter utbyte av information. Datornätet Internet utgörs av dessa användare och de enheter som sammanbinder dem. Internet är ett nätverk av nätverk med en myriad av olika datorutrustning såsom; spelkonsoler, smartphones, bärbara datorer, stationära datorer, handdatorer, även IPTV, kylskåp, tvättmaskiner, osv. Detta nätverk blomstrar på grund av noggrann planering och underhåll av internetleverantörer, nätoperatörer och andra. En ytterligare faktor som gör det möjligt för Internet att fungera är de fyra logiska skikt av abstaktion i TCP/IP-protokollstacken, en standard för datakommunikation. Ett av dessa skikt ansvarar för överföring av datapaket från en ändpunkt till en annan. Detta skikt är kallad Internet Protocol(IP) layer. Ursprungligen ansågs en 32-bitars adress vara mer än tillräcklig. Dessa IP-adresser delades ut till olika regioner rätt så oproportionerligt till stor del beroende på antalet adresser en region begärt. Idag efter en rad uppfinningar inom området(såsom webben/world wide web) och en snabb tillväxt i antal enheter som önskar ansluta sig till Internet är det tillgängliga adressutrymmet i stort sett slut. Regioner med stor befolkning men med få tilldelade block av IP-addresser har börjat göra slut på sina tilldelade adresser medan andra regioner står inför samma öde inom några månader. Behovet av ett större adressrymd sågs flera år sedan och nästa generations addresseringsschema utformades som en del av utveckligen, Internet Protocol version 6(IPv6). Länder som Kina och Indien hade ett fåtal IPv4-adresser och de har varit tvungna att övergå till IPv6 ganska snabbt. Idag kan inte ett stort antal användare i dessa länder kommunicera över IPv4-nätverk. Syftet med detta examensarbete är att diskutera övergången till IPv6 samt övergången till detta nya adresseringsschema. IPv6 ger en mycket större adressrymd samt en rad ytterligare förbättringar i jämförelse med den tidigare versionen av IP(dvs IPv4). Trots fördelarna med att övergå till IPv6 är viljan låg bland väletablerade företag, särskilt i regioner som mottagit ett stort antal IPv4-adresser från början. Dessa regioner tillämpar istället olika tekniker för att bromsa utmattningen av IPv4-adresser. Det är också troligt att denna motvija är ett sätt att hålla konkurrerande företag från marknaden ett tag till. Detta examensarbete syftar till att underlätta övergången från IPv4 till IPv6.
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Lidholm, Gilbert, and Marcus Netterberg. "Evaluating an IPv4 and IPv6 Network." Thesis, KTH, Kommunikationssystem, CoS, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-102157.

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This thesis is the result of the bachelor’s thesis project “Evaluating an IPv4 and IPv6 network”. The IPv6 protocol was created with the main purpose of solving the problem of the depletion of IPaddresses that IPv4 is currently facing. This thesis gives an introduction to the differences between IPv4 and IPv6 and when one should use one protocol rather than the other. It describes the services that we will use in order to evaluate what kinds of problems IPv4 may experience and if these problems can be solved by using IPv6. We also show how to set up a network with both protocols for each service that we examine. We will subsequently evaluate the performance of these two protocols for each of these services. We found that there were no significant differences in the performance of any of the applications that we tested with both IPv4 and IPv6. Due to the depletion of IPv4 addresses and the continuing rapid growth of the Internet, this thesis describes a very current and a relevant issue for computer networks today.
Denna avhandling är resultatet utav högskoleingenjörsexamensarbetet ”Utvärdera ett IPv4- och IPv6 nätverk”. IPv6-protokollet skapades huvudsakligen för att lösa bristen på IP adresser som IPv4 står inför.  Avhandlingen ger en introduktion till skillnaden mellan IPv4 och IPv6 och när det skulle vara mer lämpligt att använda det ena protokoll framför den andra. Den beskriver de tjänster som vi kommer att använda och utvärdera vilka typer av problem som IPv4 kan erfara och om dessa problem kan lösas med hjälp av IPv6. Vi förklarar också hur man sätter upp ett nätverk med de två protokollen för varje tjänst som vi utvärderar. Vi kommer sedermera utvärdera prestandan för båda protokollen för dessa tjänster. Vi kom fram till att det inte var några signifikanta skillnader i prestanda för någon av de applikationer som vi testade med både IPv4 och IPv6. På grund av utarmningen av IPv4-adresser och den snabba tillväxten av internet, så beskriver denna avhandling ett väldigt aktuellt och relevant problem i datornätverk idag.
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Kšica, Martin. "Struktury budoucích směrovacích tabulek pro IPv6." Master's thesis, Vysoké učení technické v Brně. Fakulta informačních technologií, 2010. http://www.nusl.cz/ntk/nusl-237276.

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This thesis is focused on structure of future IPv6 routing tables. It contains basic information about IPv6 addresses , description of hierarchy address allocation, multihoming , strategy of IPv4/IPv6 address allocation, statistics of structure properties at routing tables and forecast of future space for address IPv6 protocol. Other part of this thesis is implementation of IPv6 address generator which generates addresses according given configuration. This thesis simultaneously includes investigation of strategy IPv6 address allocation at region of RIPE NCC organization.
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Möller, Thomas. "Ipv6 : En empirisk studie i hur Ipv6 protokollet har utvecklats de senaste åren." Thesis, University of Skövde, School of Humanities and Informatics, 2009. http://urn.kb.se/resolve?urn=urn:nbn:se:his:diva-3446.

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Internet grows, so it’s cracking, soon will all IPv4 addresses be allocated and a solution is urgently needed. The new protocol, IPv6 is the solution to this problem. With a size of 128 bits against IPv4s 32 bits gives IPv6 a huge amount of addresses to distribute. The security addition that may be added manually in IPv4 is the standard with the new protocol. To implement IPv6 will not get done over a day, and the various protocols are not talking with each other so the transition will be a problem. A solution for this is dual-stack that allows a node using both protocols.

The aim of the thesis is to examine how the reach ability is with IPv6 is on different pages, which claim to use dual-stack. To see if it was an improvement, the results will be compared with results from the survey Empirical Performance of IPv6 vs.. IPv4 under a Dual-Stack Environment. The aim has been achieved through the theoretically learn about IPv6 protocol. After this, a survey which was later compiled, compared and presented in this work. The survey results show that the IPv6 network has increased since the last survey. It also shows that practical with IPv4 is about the same level as in the investigation being compared. This indicates that dual-stack is used and that it will in time be moving in a pure IPv6 Internet.


Internet växer så det knakar, snart är alla IPv4 adresserna tilldelade och en lösningbehövs omgående. Det nya protokollet IPv6 är lösningen på detta problem. Med enstorlek på 128 bitar gentemot IPv4s 32 bitar ger IPv6 en ofantligt mycket störremängd adresser att dela ut. De säkerhetstillägg som får läggas till manuellt i IPv4 ärstandard med det nya protokollet. Att implementera IPv6 kommer inte att gå på endag och de olika protokollen pratar inte med varandra så övergången kommer att bliett problem. En lösning för detta är Dual-stack som gör att en nod använder bådaprotokollen.Syftet med examensarbetet är att undersöka hur nåbarheten med IPv6 är på olika sidorsom påstår att de använder dual-stack. För att se om det blivit en förbättring kommerresultatet att jämföras med resultatet från undersökningen Empirical Performance ofIPv6 vs. IPv4 under a Dual-Stack Environment.Syftet har uppnåtts genom att teoretiskt ta lärdom om IPv6 protokollet. Efter dettagjort en undersökning som senare sammanställts, jämförts och presenterats i dettaarbete.Undersökningens resultat visar att IPv6 nätet har ökat de sedan den förraundersökningen. Det visar även att nåbarheten med IPv4 är ungefär på samma nivåsom vid undersökningen som jämförs med. Detta visar på att dual-stack används ochatt det tids nog kommer att gå över i ett renodlat IPv6 Internet.

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Kasselstrand, Olof. "Att Införa IPv6 i ett IPv4-nätverk." Thesis, Jönköping University, JTH, Computer and Electrical Engineering, 2007. http://urn.kb.se/resolve?urn=urn:nbn:se:hj:diva-841.

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Internet is growing every day and this is leading to an address depletion of the current IPv4 addresses. A new version of IPv4, called IPv6, is the protocol for addressing computers that will deal with this problem. IPv4 and IPv6 are unfortunately not compatible with each other. IPv4 and IPv6 have to co-exist for a long time until IPv6 will be the dominant protocol.

The purpose of this thesis is to examine how a transition could be done or more correctly, how to deploy IPv6 in an already existing IPv4 network. After that part of the report a case study at the local Internet service provider Junet AB will be conducted. This case study will investigate an IPv6 deployment scenario for Junet AB.

A theoretical background has been written that describes some steps an Internet service provider has to go through to deploy IPv6. The case study was conducted after the theoretical background was written. The result of this report shows that a deployment of IPv6 in an IPv4 network is technically achievable. All the main components to maintain and use IPv6 in a commercial network exist.

The case study indicates that it is possible to deploy IPv6 in Junet AB´s network. IPv4 and IPv6 could be used in their network without any major effort. IPv6 have been around for many years now but have not had that break through many early adopters have hoped for. A lack of documentation and experience is an obstacle for a deployment of IPv6.One thing that remains now is to prove that there is a need for IPv6, but that is out of scope for this thesis.

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Harnell, Jonas, and Yonatan Alemayehn. "En jämförande studie av IPv4 och IPv6." Thesis, Växjö University, School of Mathematics and Systems Engineering, 2005. http://urn.kb.se/resolve?urn=urn:nbn:se:vxu:diva-60.

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The Internet protocol of today has been used for over 20 years. A new version of the protocol has been developed to replace the old one. This is a direct result due to the explosive growth of the usage of the Internet. This follows by new demands which needs new solutions. This report brings up the old protocol IPv4, the new protocol IPv6 and shows what kind of changes that has been developed to meet the users demand.

The report brings up two important aspects; internet security and mobility. To show the important changes within these areas, the report compares the old protocol with the new one. Furthermore, the report also studies the world’s greatest test environment to this date. The aim of this is to show how the protocol behaves in reality and thereby get an insight to the specific areas that needs to be illustrated. To conclude the report, there is a broad discussion regarding the future of the two protocols and how this may effect the Internet in a future perspective.


Dagens Internetprotokoll är över 20 år gammalt och en ny version av protokollet har

utvecklats för att ersätta det befintliga. Detta är ett resultat av en explosionsartad

tillväxt av Internetanvändandet med nya krav som kräver nya lösningar. Rapporten tar upp det gamla protokollet IPv4, det nya protokollet IPv6 och visar vilka förändringar som har gjorts.

Speciellt viktiga aspekter i form av säkerhet och

mobilitet tas upp för att sedan jämföras mellan de olika protokollen. Dessutom

studeras den hittills största testmiljön i världen, detta för att få en känsla av hur

protokollet beter sig i praktiken och därigenom få en inblick i områden som behöver

belysas. Rapporten avslutas med en diskussion om hur framtiden för de olika

protokollen ser ut för ett framtida Internet.

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8

Oliveira, Luís Miguel Lopes de. "Mobilidade em cenários de transição IPv4 - IPv6." Master's thesis, Universidade de Aveiro, 2004. http://hdl.handle.net/10773/16803.

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Mestrado em Engenharia Electrónica e Telecomunicações
A evolução da Internet, actualmente baseada no protocolo IPv4, para o protocolo IPv6, será feita de uma forma progressiva recorrendo a mecanismos de transição. Durante o processo de transição, torna-se necessário introduzir serviços de rede que são considerados de importância chave para os objectivos da Internet da próxima geração. Um desses serviços é a mobilidade. Actualmente existem soluções que permitem realizar mobilidade IP em redes IPv4 e mobilidade IP em redes IPv6. Contudo, ainda existem algumas incertezas relativas à concretização da mobilidade IP em redes heterogéneas. O IETF (Internet Engineering Task Force) propõe diferentes mecanismos de transição que permitem solucionar diversos aspectos relacionados com a conectividade ponto-a-ponto em cenários de transição IPv4-IPv6. No entanto, cada mecanismo de transição, por si só, não resolve o problema da conectividade entre terminais móveis em diferentes cenários de transição e, no caso geral, diferentes mecanismos deverão ser combinados para este fim. Esta dissertação aborda o problema de providenciar o serviço de mobilidade IP em redes mistas IPv4-IPv6. Para tal, primeiro são estudados em detalhe os protocolos Mobile IPv4, Mobile IPv6 e os mecanismos de transição IPv4-IPv6 propostos pelo IETF. De seguida, é proposto um conjunto de cenários de transição para o qual são estudadas as melhores formas de providenciar mobilidade IP. As soluções apresentadas combinam diferentes mecanismos de transição para permitir o serviço de mobilidade nos cenários propostos. As soluções propostas foram validadas experimentalmente em laboratório recorrendo ao uso de concretizações de mobilidade IPv4 e IPv6 e de mecanismos de transição disponíveis.
It is known that the evolution of the current Internet, based on IPv4 protocol, to the future IPv6 Internet will be based on transition scenarios. In this migrating path, there is the need to introduce as soon as possible new network services that are considered of key importance for the objectives of the future IPv6 Internet. One of these services is mobility. Although there are already solutions to provide mobile IP in IPv4 networks and in IPv6 networks, the provision of mobility in mixed IPv4/IPv6 networks has yet many uncertainties. Currently, there are several transition mechanisms proposed by IETF (Internet Engineering Task Force) to solve different aspects on the provision of point-to-point IP connectivity in Pv4-IPv6 transition scenarios. However, none of these mechanisms was aimed to address the specific needs of mobile IP. In fact, there is no single IPv4-IPv6 transition mechanism that can provide connectivity to mobile nodes. This dissertation addresses the issue on how to combine the different transition mechanisms in order to provide seamless mobile IP service. We address the mobile service provision both to IPv4 and IPv6 hosts. These solutions were validated in laboratory using available Mobile IPv4 and IPv6 and transition mechanism available implementations.
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Florin, Snöarve Jonathan, and Filip Nilsson. "IPv6 : en nulägesstudie." Thesis, Högskolan Kristianstad, Sektionen för hälsa och samhälle, 2016. http://urn.kb.se/resolve?urn=urn:nbn:se:hkr:diva-15570.

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IPv4-adresser är begränsat när det gäller antalet det finns att dela ut, ett framtida problem är att dessa adresser med största sannolikhet kommer att ta slut. Vårt arbete har således fokuserat på att inhämta information som bidrar till en klarare bild av hur dagsläget ser ut kopplat mot implementeringen av IPv6 som sker i Europa och Sverige. För att kunna förklara denna implementering på ett bra sätt finns det delar i arbetet som beskriver de tekniska hinder och möjligheter som bidrar till införandet av detta protokoll. Huvuddelen av tiden har spenderats med att inhämta information och fakta som ger en fördjupad kunskap i ämnet, med avsikten att skriva en gedigen bas som utredningsdelen i arbetet utger. Intervjuer har också varit en del, denna del finns i syfte att ge en bild över hur internetleverantörer arbetar med införandet av IPv6. De organisationer som finns och arbetar med införandet av IPv6 har alla en bra pool med fakta som beskriver hur situationen ser ut i dagsläget. RIPE NCCs databas visar klart och tydligt de organisationer som finns med i arbetet med implementeringen av IPv6. Denna databas samt information tagen från genomförda intervjuer ger oss en uppfattning om att införandet än så länge inte har kommit särskilt långt, detta i relation till bristen av IPv4 adresser som råder. I Sverige jobbar PTS mycket mot att hjälpa organisationer med en eventuell övergång till IPv6, deras arbete är ordentligt men problematiken där är istället att organisationer idag inte är i behov av denna information. Det positiva är således att informationen finns där, hos PTS, att hämta vid behov.Trots att de sista IPv4-blocken är utdelade finns det egentligen inget behov av att implementera IPv6 i dagsläget. Ett IPv4-nätverk med fungerande NAT fungerar och kommer med största sannolikhet fungera ett bra tag framöver.
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Dongo, Daniel. "Övergången från IPv4 till IPv6 : varför dröjer den?" Thesis, University of Skövde, School of Humanities and Informatics, 2005. http://urn.kb.se/resolve?urn=urn:nbn:se:his:diva-1018.

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Allt ifrån persondatorer, mobiltelefoner och bilar kommer inom en snar framtid att vara uppkopplade mot Internet. Detta medför att varje enhet med en förbindelse till Internet kommer att behöva en unik IP-adress för att identifiera sig själv samt resten av Internet. Dagens Internet i form av IP version 4 (IPv4) kan inte hantera detta på grund av bristen på IPv4-adresser. Vidare saknar det nuvarande IPv4 trots det massiva antalet användare någon form av inbyggd säkerhet samtidigt som efterfrågan av nya tjänster samt teknologi från användare av Internet drastiskt ökar. Uppföljaren till IPv4, vars tekniska specifikation redan är färdigställd och standardiserad kallas IP Version 6 (IPv6). Det nyare IPv6 uppgraderar adressrymden som det äldre IPv4 tillhandahåller vilket löser problemet med sinande IPv4-adresser. Vidare förbättrar IPv6 säkerheten på Internet genom sitt inbyggda stöd för kryptering samtidigt som det erbjuder förbättrad tillförlitlighet, nya tjänster samt en rad tekniska fördelar över IPv4. Trots problemen med det utdaterade IPv4 som skapades för mer än 20 år sedan visar sig dock övergången från IPv4 till IPv6 svårartad. Utvecklingen av IPv6 varierar från en geografisk region till en annan. Företag och användare vet inte idag när de kan förvänta sig IPv6 samt dess tjänster från de stora Internetleverantörerna. Denna rapport ämnar undersöka vad det är som varit viktigast för att Internetleverantörerna ej övergått från IPv4 till IPv6 i större grad än vad som skett hittils. Resultatet av rapporten kan ge en insikt i vad det är som behöver förändras för att utvecklingen av IPv6 kan ta fart på riktigt. Vidare kan den ge en inblick i var i övergången från IPv4 till IPv6 Internetleverantörerna står idag

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Books on the topic "Ipv6"

1

Loukides, Mike, and Meghan Blanchette, eds. IPv6 Essentials: Integrating IPv6 into Your IPv4 Network. Beijing: O’Reilly Media, 2014.

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Cisco self-study: Implementing IPv6 networks (IPV6). Indianapolis, IN: Cisco, 2003.

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van Beijnum, Iljitsch. Running IPv6. Berkeley, CA: Apress, 2006. http://dx.doi.org/10.1007/978-1-4302-0090-1.

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Gonçalves, Marcus. IPv6 networks. New York: McGraw-Hill, 1998.

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Eric, Vyncke, ed. IPv6 security. Indianapolis, IN: Cisco Systems, 2009.

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Davies, Joseph. Understanding IPv6. 2nd ed. Redmond, WA: Microsoft Press, 2008.

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Kitty, Niles, ed. IPv6 networks. New York: McGraw-Hill, 1998.

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Beijnum, Iljitsch van. Running IPV6. Berkeley, CA: Apress, 2005.

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Davies, Joseph. Understanding IPv6. 2nd ed. Redmond, WA: Microsoft Press, 2008.

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Davies, Joseph. Understanding IPv6. Redmond, Wash: Microsoft Press, 2003.

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Book chapters on the topic "Ipv6"

1

Rosen, Rami. "IPv6." In Linux Kernel Networking, 209–46. Berkeley, CA: Apress, 2013. http://dx.doi.org/10.1007/978-1-4302-6197-1_8.

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Riggert, Wolfgang. "IPv6." In Rechnernetze, edited by Michael Lutz and Christian Märtin, 163–86. München: Carl Hanser Verlag GmbH & Co. KG, 2014. http://dx.doi.org/10.3139/9783446440968.008.

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Riggert, Wolfgang, and Ralf Lübben. "IPv6." In Rechnernetze, 175–206. München: Carl Hanser Verlag GmbH & Co. KG, 2020. http://dx.doi.org/10.3139/9783446463691.007.

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Nagel, Christian, Ajit Mungale, Vinod Kumar, Nauman Laghari, Andrew Krowczyk, Tim Parker, S. Srinivasa Sivakumar, and Alexandru Serban. "IPv6." In Pro .NET 1.1 Network Programming, 189–211. Berkeley, CA: Apress, 2004. http://dx.doi.org/10.1007/978-1-4302-0660-6_6.

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Kralicek, Eric. "DNS, DHCP, IPv4, and IPv6." In The Accidental SysAdmin Handbook, 189–201. Berkeley, CA: Apress, 2016. http://dx.doi.org/10.1007/978-1-4842-1817-4_11.

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Amutha, J., S. Albert Rabara, and R. Meenakshi Sundaram. "An Integrated Secure Architecture for IPv4/IPv6 Address Translation Between IPv4 and IPv6 Networks." In Advances in Intelligent Systems and Computing, 669–79. New Delhi: Springer India, 2015. http://dx.doi.org/10.1007/978-81-322-2523-2_65.

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Horley, Edward. "Miscellaneous IPv6." In Practical IPv6 for Windows Administrators, 209–27. Berkeley, CA: Apress, 2013. http://dx.doi.org/10.1007/978-1-4302-6371-5_10.

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Horley, Edward. "IPv6 Addressing." In Practical IPv6 for Windows Administrators, 17–67. Berkeley, CA: Apress, 2013. http://dx.doi.org/10.1007/978-1-4302-6371-5_3.

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Hasan, Syed Faraz. "IPv6 Networks." In Emerging Trends in Communication Networks, 5–18. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-07389-7_2.

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Hughes, Lawrence E. "IPv6 Projects." In Third Generation Internet Revealed, 395–99. Berkeley, CA: Apress, 2022. http://dx.doi.org/10.1007/978-1-4842-8603-6_13.

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Conference papers on the topic "Ipv6"

1

Costella, Leonardo, Marco Trentin, and Ricardo De Oliveira Schmidt. "CatchmentView: Uma ferramenta para a análise e comparação de IPv4 e IPv6 catchments." In XXXVII Simpósio Brasileiro de Redes de Computadores e Sistemas Distribuídos. Sociedade Brasileira de Computação - SBC, 2019. http://dx.doi.org/10.5753/sbrc_estendido.2019.7769.

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Com o crescimento da adoção do IPv6, muitos serviços estão operando no formato dual-stack, ou seja, configurados e aptos a receberem requisições em IPv4 e IPv6. O ideal seria que a performance em ambos os protocolos fosse a mesma. Entretanto, devido a políticas de roteamento requisições em IPv4 e IPv6 para um mesmo serviço podem ser roteadas de uma maneira completamente diferente. Esse problema, acentua-se em serviços que utilizem anycast. Baseado no fato de que ferramentas de monitoramento são importantes aliados na busca de uma melhor eficiência dos serviços disponibilizados, neste trabalho desenvolveu-se uma ferramenta visual para observar e monitorar as diferenças entre o IPv4 e IPv6 catchment em serviços anycast.
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Sena, Jansen Carlo, Paulo Lício de Geus, and Alessandro Augusto. "Impactos da Transição e Utilização do IPV6 sobre a Segurança de Ambientes Computacionais." In Workshop em Segurança de Sistemas Computacionais. Sociedade Brasileira de Computação - SBC, 2002. http://dx.doi.org/10.5753/sbseg.2002.21262.

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Do ponto de vista da segurança de sistemas, o IPv6 soluciona diversas fragilidades relativas ao IPv4, porém traz consigo a possibilidade do desenvolvimento de novos ataques. Desta forma, a identificação das suas potencialidades e problemas é fundamental para a auxiliar o processo de transição. Este artigo apresenta uma análise de segurança do IPv6, caracterizando suas soluções para ataques clássicos voltados ao IPv4, bem como novos problemas intrínsecos àquele protocolo.
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Cesen, Fabricio E. Rodriguez, P. Gyanesh Kumar Patra, Christian Esteve Rothenberg, and Gergely Pongracz. "Design, Implementation and Evaluation of IPv4/IPv6 Longest Prefix Match support in P4 Dataplanes." In XVII Workshop em Desempenho de Sistemas Computacionais e de Comunicação. Sociedade Brasileira de Computação - SBC, 2018. http://dx.doi.org/10.5753/wperformance.2018.3319.

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New trends in dataplane programmability inside Software Defined Networking (SDN) paradigm are in an effort to bring multi-platform support with a high-level definition of the dataplane pipeline functions. The MultiArchitecture Compiler System for Abstract Dataplanes (MACSAD) can integrate the Protocol-Independent Packet Processors (P4) domain-specific language and the OpenDataPlane Project (ODP) APIs, to define a programmable dataplane across multiple targets in a unified compiler system. In this paper, we present and evaluate the IPv4/IPv6 Longest Prefix Match (LPM) support in MACSAD. We develop a new ODP Helper library implementing the IPv6 lookup mechanism based on the current IPv4 solution and evaluate its performance and scalability for diverse workloads and target platform configurations.
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Meher, Kunal, and Shilpa Verma. "IPV4 to IPV6 transition." In the International Conference & Workshop. New York, New York, USA: ACM Press, 2011. http://dx.doi.org/10.1145/1980022.1980364.

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Hyun, Jonghwan, Jian Li, Hwankuk Kim, Jae-Hyoung Yoo, and James Won-Ki Hong. "IPv4 and IPv6 performance comparison in IPv6 LTE network." In 2015 17th Asia-Pacific Network Operations and Management Symposium (APNOMS). IEEE, 2015. http://dx.doi.org/10.1109/apnoms.2015.7275417.

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Govil, Jivesh, and Jivika Govil. "IPv6: Mobility Management and Roaming between IPv6 and IPv4." In 2007 International Conference on Convergence Information Technology (ICCIT 2007). IEEE, 2007. http://dx.doi.org/10.1109/iccit.2007.348.

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Govil, Jivesh, and Jivika Govil. "IPv6: Mobility Management and Roaming between IPv6 and IPv4." In 2007 International Conference on Convergence Information Technology (ICCIT 2007). IEEE, 2007. http://dx.doi.org/10.1109/iccit.2007.4420475.

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Chuangchunsong, N., S. Kamolphiwong, T. Kamolphiwong, R. Elz, and P. Pongpaibool. "Performance evaluation of IPv4/IPv6 transition mechanisms: IPv4-in-IPv6 tunneling techniques." In 2014 International Conference on Information Networking (ICOIN). IEEE, 2014. http://dx.doi.org/10.1109/icoin.2014.6799698.

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Kotliar, A., and V. Kotliar. "IPV6 DUAL-STACK DEPLOYMENT FOR THE DISTRIBUTED COMPUTING CENTER." In 9th International Conference "Distributed Computing and Grid Technologies in Science and Education". Crossref, 2021. http://dx.doi.org/10.54546/mlit.2021.69.15.001.

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Computing center of the Institute for High Energy Physics in Protvino provides computing and storageresources for various HEP experiments (Atlas, CMS, Alice, LHCb) and currently operates more than150 working nodes with around 3000 cores and provides near 2.5 PB of disk space. All theseresources are connected through two 10 GB/s links to LHCONE and other research networks. IHEPcomputing center has IPv4 address space limited to one C-sized network and all computing nodesworking behind the NAT that has some drawbacks for production use. To optimize routing, switchingand to get higher network throughput for data transfer the IPv6 dual-stack was deployed on thecomputing farm. This work shows the full cycle of the real IPv6 dual-stack deployment from zero toproduction.
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Eun-Young Park, Jae-Hwoon Lee, and Byoung-Gu Choe. "An IPv4-to-IPv6 dual stack transition mechanism supporting transparent connections between IPv6 hosts and IPv4 hosts in integrated IPv6/IPv4 network." In 2004 IEEE International Conference on Communications (IEEE Cat. No.04CH37577). IEEE, 2004. http://dx.doi.org/10.1109/icc.2004.1312656.

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Reports on the topic "Ipv6"

1

Bao, C., C. Huitema, M. Bagnulo, M. Boucadair, and X. Li. IPv6 Addressing of IPv4/IPv6 Translators. RFC Editor, October 2010. http://dx.doi.org/10.17487/rfc6052.

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Baker, F., W. Harrop, and G. Armitage. IPv4 and IPv6 Greynets. RFC Editor, September 2010. http://dx.doi.org/10.17487/rfc6018.

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Baker, F., X. Li, C. Bao, and K. Yin. Framework for IPv4/IPv6 Translation. RFC Editor, April 2011. http://dx.doi.org/10.17487/rfc6144.

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Morton, A., J. Fabini, N. Elkins, M. Ackermann, and V. Hegde. IPv4, IPv6, and IPv4-IPv6 Coexistence: Updates for the IP Performance Metrics (IPPM) Framework. RFC Editor, November 2018. http://dx.doi.org/10.17487/rfc8468.

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De, J., D. Ooms, S. Prevost, and F. Le. Connecting IPv6 Islands over IPv4 MPLS Using IPv6 Provider Edge Routers (6PE). RFC Editor, February 2007. http://dx.doi.org/10.17487/rfc4798.

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Wakikawa, R., and S. Gundavelli. IPv4 Support for Proxy Mobile IPv6. RFC Editor, May 2010. http://dx.doi.org/10.17487/rfc5844.

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Cheng, D., M. Boucadair, and A. Retana. Routing for IPv4-Embedded IPv6 Packets. RFC Editor, July 2013. http://dx.doi.org/10.17487/rfc6992.

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Cui, Y., J. Wu, P. Wu, O. Vautrin, and Y. Lee. Public IPv4-over-IPv6 Access Network. RFC Editor, November 2013. http://dx.doi.org/10.17487/rfc7040.

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Chen, I., A. Lindem, and R. Atkinson. OSPFv3 over IPv4 for IPv6 Transition. RFC Editor, August 2016. http://dx.doi.org/10.17487/rfc7949.

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Anderson, T. Local-Use IPv4/IPv6 Translation Prefix. RFC Editor, August 2017. http://dx.doi.org/10.17487/rfc8215.

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