APNIC 16 Address Council Election 22 August 2003 Seoul, Korea.
August 2003, Seoul
Transcript of August 2003, Seoul
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Euro6IX: The Concept• How to pronounce it: forget IX and read 6 (“SIX”)
• Build a large, scalable and native IPv6 Backbone of Traffic Exchanges, with connectivity across Europe and other IPv4/v6 Exchangers
• In order to promote and allow other players to trial v6 and port/develop key applications and services
• In order to break the chicken and egg issue !• Gain REAL IPv6 experience, in a real world with not just
research users, involving Telcos/ISPs/ASPs, among others: Allow new players into our trials
• Bring IPv6 into a production transit service
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Euro6IX Goal• Support the fast introduction of IPv6 in Europe.• Main Steps:
– Network design & deployment– Research on network advanced services– Development of applications validated by user
groups & international trials– Active dissemination:
• participation in events/conferences/papers• contributions to standards• project web site
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Objectives1. Research an appropriate architecture, to design
and deploy the first Pan-European non-commercial IPv6 Internet Exchange Network.
2. Use this infrastructure to research, test and validate IPv6-based applications & services.
3. Open the network to specific User Groups for its validation in trials.
4. Dissemination, liaison and coordination with clusters, fora, standards organizations (e.g. IETF, RIPE) and third parties.
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Updated Network Map
Torino
Paris
Zurich
Berlin
London
Lisbon
Madrid
Murcia
BernBretigny
Lannion
Aveiro
Issy
Caen
Southampton
Viby
TEF
PT/TEF
TI
TI
FT
FT
DT
IPv6 IX
IPv6 NodeLink Sponsor/s
34 Mbps Native Link
Node to IX Link
name
1) IPv6 in IPv6 Tunnel in own network2) IPv6 over IPv4 over internet/6Bone• Other similar tunnels could be setup
in other links if needed
Alcobendas
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Layer 3 IX• Infrastructure providing both layer 2 and
layer 3 interconnection service.• Several IXs can make direct peering offering
also Wide Area Layer 3 transport as an Internet Service Provider. Every IXs will use an assigned xTLA prefix (x=p or s) to assign NLA prefixes to ISPs or customers connecting to the IX.
• Project partners will use their xTLA prefix to assign NAL to customers and regional ISP connecting to IX.
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Layer 3 IXs Network Architecture
Next GenerationNext GenerationIX customers IX customers
RR
L3L3 Internet Internet ExchangeExchange Euro6IX
Backbone
Standard IX customersStandard IX customers
RR
L3L3 Internet Internet ExchangeExchange
RR
L3L3 Internet Internet ExchangeExchange
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IX Model C
LH ISP3
Hosted long-haul ISP routers
IX Infrastructureand services
LH ISP1
RR
Hosting building
RegionalISPs
ISPCustomers
Hosted regionalISP routers RR RRRR
RR
Long Haul Pr.Long Haul Pr.customers customers
Next GenerationNext GenerationIX SubscribersIX Subscribers
LH ISP2
RR RR
• L2 infrastructure (fully redundant) where the IX services are placed
• Routers infrastructure (long-haul providers and customers)
• Layer 3 mediation function router (L3MF) is the real new element of this model
L3MF router
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RFC2374 Benefits• This model is based on the RFC 2374 to verify that:
– a customer could change its service provider without changing its addressing space
– the renumbering functionality could be realized more easily (no renumbering in the better case)
– the multihoming functionality could be realized more easily• IX plays an intermediation role between the ISP and the
customers (Layer 3 mediation function router)• Routing:
– iBGP+IGP: inside the Long Haul Provider – Euro6IX is the collection of the routers inside the IX emulating the
LHP (single AS)– eBGP4+: between the customers and the IX– eBGP4+: between the IX and the LHPs
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Address Assignment
IPv6 IX services
Next GenerationNext GenerationIX customersIX customers
StandardStandardIX customer IX customer
RR
L3L3 mediationmediationL2 standardL2 standard
Add
ress
del
egat
ion
Euro6IX
IX Address Space(e.g. TILAB, 2001:06b8::/35)
Add
ress
dele
gatio
n
/35)Other
long-haulISPs
• Two options1. IPv6 addresses assigned by the
long-haul ISPs (e.g. Euro6IX)2. IPv6 addresses directly
assigned by the IX
1
2
Euro6IXAddress Space
(e.g. 2001:xyzk::
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Routing
Euro6IXBackbone
AutonomousSystem
RR
IXIX
OtherIXs
IXIXIXIX
RR
Next GenerationNext GenerationIX customer IX customer
Standard IXStandard IXcustomercustomer
RR
eBGP4+
eBGP4+
eBGP4+
IS-ISOSPFv6
RIPngiBGP4+IGP
Euro6IXIPv6 Exchange
Euro6IXSites
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Static VPNs with IPv6• To evaluate the current status of the
main open source IPsec/IKE implementations and some commercial IPsec/IKE solutions
• To deploy of a static VPN service in the Euro6IX test-bed
• Configuration and installations guides for IPsec/IKE
• Test reports of interoperability and conformance
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UMU – PKIv6 Description• Main Objective: Establish a high security
infrastructure for distributed systems• Main Features:
– PKI supporting IPv6– Developed in Java Multiplatform– Issue, renew and revoke certificates– Final users can use either RAS or Web– LDAPv6 directory support– Use of smart cards (file system, RSA or Java Cards) ...
allowing user mobility and increasing security– PKI Certification Policy support– VPN devices certification support (using the SCEP protocol)– Support for the OCSP protocol and Time Stamp– Web administration
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UMU – PKIv6 Architecture
WWW Secure Request Server
Data Base
LDAP Server End User
Certification Authority Registration
Authority
Administrator
IPv6 SSL connectionIPv6 Plain connection
SCEP
VPN Device
WWW Secure Request Server
Data BaseData Base
LDAP ServerLDAP Server End UserEnd User
Certification Authority
Certification Authority Registration
AuthorityRegistration
AuthorityRegistration
Authority
AdministratorAdministrator
SCEPSCEP over IPv6
VPN Device
https://pki.ipv6.um.es
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UMU – PKIv6 Advanced Services
SCEP Server (for requesting certificates from an IPsec device)
Certification Authority
OCSP Authority
Time StampingAuthority
TimeStamp Server (associated with a NTP server)
OCSP Server (for on-line revocation support)
TSPClient
Certificate
CertificateOCSP Client
TSP Message
OCSP Message
VPN Device
SCEP Server
SCEP Client
IPsec device
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UMU – PKIv6 RA Snapshot
Validating a certificate
Requesting a certificate
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UMU – PKIv6 CA Snapshot
CA Internal Management Process
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IX Based Services• IX becomes a place where new services are offered to the
users.• IX is an aggregation point, so it can provide those services
who can benefit by this “user aggregation” (e.g. in a based multicast network, the RP could be located inside the IX, because a lot of users connect to it).– Network Services
• Multicast, AAA, QoS, DNSSec• Transition Mechanisms: NAT-PT, Tunnel Broker, 6to4• Route Server mechanism
– Application Services• HTTP, FTP, SMTP• VideoConference/e-learning services• P2P applications
– Monitoring Services• Routing/Traffic/Reachability Monitoring (Magalia, AS-Path tree, Looking Glass)
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The UK6x (LON6IX)• Layer 2 & 3 IPv6 Internet exchange• First in the UK• Uses commercial IPv6 addresses• Located at the heart of the UK Internet – Telehouse• Open to all• Primary aims are:
– to stimulate the IPv6 environment in the UK, Europe and the World
– to further the understanding of IPv6
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UK6x Core Architecture• Ethernet switch for Layer 2 peering• ATM switch for additional customer access mechanisms• Router for Layer 3 functionality• 2001:618::/32 used for address allocation• 2001:7F8:2::/48 used for infrastructure• Maintenance via Looking Glass, ASpath-tree etc.
ATM Switch
WWWEmail
DNS
Customers
Ethernet
IPv6 Service Environment
MP3, Video, Quake, Mobile IPv6 HA, Debian mirror …
Router
Customers Customers
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UK6x Connectivity
Manual, 6to4 or via Tunnel Broker
IPv4Internet
GPRS
Customers
CustomersCustomers
CustomersCustomers
Customers
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DNSv6 (I)
• 1995: AAAA, nibble and IP6.INT (RFC1886)• 2000: A6, bit-string and IP6.ARPA (RFC2874)• 2002: A6 and bit-string -> Experimental
(RFC3363)• Servers and resolvers with IPv6 MUST
support EDNS0 (RFC3226)• Good support in DNS servers• Some TLDs with IPv6 and AAAA
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DNSv6 (II)• Difference between transport and content
IPv6 User Local Server
euro6ix.org. Server
org. Server
root server
www.euro6ix.org
AAAAAAAA
www.euro6ix.org
www.euro6ix.org
www.euro6ix.org
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DNSv6 (III)
• What does these all means?• AAAA as easy as A records• Reverse lookups are little bit more difficult to
manage• Be aware of the lack of IPv6 transport up to
the root servers -> need of IPv4 connectivity
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DNSsecv6 (I)• Provide integrity and authentication to security aware
DNS entities: for both queries and zone transfers• Defined independently of the IP version used• DNS resolvers and servers with DNSsec MUST
support EDNS0 (RFC3226)• Storage of authenticated public keys in the DNS
(support for general public key distribution services as well as DNS security)
• Use cryptographic digital signatures which are included in secured zones as RRs
• TSIG (Transaction signatures) to secure DNS messages. Private shared keys. Simple and lightweight. (RFC 2845)
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DNSsecv6 (II)• Each node in the DNS tree is associated with a public
key.
• Each key is authenticated by the parent zone, up to the root (globally secure)
• Or up to a security security root (locally secure)
• Handling of DNSsec keys
• The querier will receive signatures of RRs and the public key, for signatures the private key associated with the public key of the domain is used
• A DNSsec aware resolver will follow the “chain of trust” of public keys, until it reaches a trusted one.
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DNSsecv6 (III)IPv6 User Local
Servereuro6ix.org.
Serverorg.
Serverroot
server
www.euro6ix.org
AAAA + SIG (euro6ix.org)
AAAA
www.euro6ix.org
www.euro6ix.org
www.euro6ix.org
KEY (euro6ix.org) + SIG (org)
KEY(org)
KEY(org) + SIG(root)
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IX service PKIv6 to publish certificates using DNSSEC
• Scenario 1:– Root CA and Name Server are together in the IX
IX
ISP-1
Name serverzone IX Name server
zone ISP-1
update
update
Root CARoot CA
IX
ISP-1
Name serverzone IX Name server
zone ISP-1
update
update
Root CARoot CA
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IX service PKIv6 to publish certificates using DNSSEC
• Scenario 2:– Root CA is out
IX-2
IX-1
ISP-1
Name serverzone IX
Name serverzone ISP-1
update
Root CA
Root CA
update
IX-2
IX-1
ISP-1
Name serverzone IX
Name serverzone ISP-1
update
Root CA
Root CA
update
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Euro6IX Work (I)
• DNSsec pilot• Locally secured domain: sigz.euro6ix.org• TSIG for zone transfers (symmetric keys)• DNSsec for secure queries
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Euro6IX Work (II)• DNSsec pilot
Security Root
Forward server
euro6ix.org.
sigz.euro6ix.org
umu. upm. consulintel.
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Euro6IX Work (III)• DNSsec emulator tool• OBJECTIVE: creation of complex DNS
scenarios made of complete name server hierarchies inside one computer, in order to test different scenarios and configuration alternatives before deploying the service to real servers.
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Euro6IX Work (IV)• Certificates management with DNSsec• Study the use of a secure DNS service to
publish digital certificates in cooperation with a PKI
• The CERT RR can be used to store certificates in the DNS. The types of certificates currently defined are X.509, SPKI and PGP certificates. It is intended that personal public keys should be stored in the DNS using the CERT record, and not by using the KEY record.
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Open Issues• DNSv6
– Autoconfiguration: DHCPv6, RA, others?
– Reverse lookups: IP6.INT -> IP6.ARPA
– Root servers with IPv6
• DNSsec– Key management
– root servers with DNSsec
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Multicast Advantages• Network bandwidth optimization (e.g. multicast
network makes a copy of the packets only when needed)
• Source optimization (e.g. no need to transmit a packet per destination)
• Well scalable technology (e.g. when a receiver is added to a network, no addiction cost is required)
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Operating Multicast: M6Bone• Core routers running typically PIM-Sparse
Mode• Access routers running PIM-SM and
additionally MLD (for group managing)• Hosts implementing the MLD protocol • Users are grouped in the so-called “multicast
groups”. All the hosts inside a multicast group, have the same multicast address and when a host wants to add or to leave a group, it has only to communicate this to the border router of the network where it is connected to.
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The M6Bone
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Implementing QoS• In a typical model for QoS implementation over an administrative
domain, the network is composed by a core and edge (usuallyPoPs) routers. Following the DiffServ model in its simplest way, the traffic coming from the customers is received by the edge routers, marked on DSCP, and policed or shaped according to the SLAs.
• In this simple model, with a single Service Provider all the tasks are performed within the same administrative domain, and it can be insured that the marking, policing and queuing tasks applied to the packets along the network are coherent.
ISP
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Implementing QoS in Real Life• The real world, like in Euro6IX, is not a single Service Provider, but
a lot of them.
• To implement a global QoS we need to define agreements of SLSsbetween the partners (different administrative domains).– In some cases the remarking could be needed.
– The definition of SLAs is needed in order to define how much traffic is allowed between the providers.
• In the case which some external entities are used by the Providers, to manage the QoS provisioning, interoperability is already needed between these entities in order to negotiate the SLAs dynamically.
ISP1 ISP3ISP2
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Euro6IX model of QoS• The Euro6IX models also brings the new L3 IX.
• This situation doesn't changes anything the model. The IX network should be considered as one Service Provider more.
• The only new requirement from the 6IX is the provisioning of L2 QoS, using 801.2P technology.
• This is needed to support in a coherent way the L3QoS. But not just the Ethernet-based should do it. All the other connections either ATM or FR should do the same, if possible.
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AAAv6• Radius for IPv6 is standardized, but not well
implemented (RFC3162)
• Almost no implementations using UDP/IPv6
• Some IDs for DIAMETER usage with IPv6– Some preliminary implementations
• http://playground.sun.com/diameter
• http://sourceforge.net/projects/diameter
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Network Access• Well supported and implemented:
– PPPoA (RFC2364)
– PPPoE (RFC2516)
– IPv6 over PPP (RFC2472)
• The question is how the remote host obtains the global IPv6 address instead of the link-local one. Usually:– Router Advertisement
– DHCPv6 (RFC3315)
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Mobility• Mobile IPv6 (proposed standard draft-ietf-mobileip-
ipv6-24.txt last July) describes basic functionality and agents that take part on it
• Other documents in progress, including:– Security in signaling for MIPv6 (http://www.ietf.org/internet-
drafts/draft-ietf-mobileip-mipv6-ha-ipsec-06.txt)– Handovers enhancements (HMIPv6,
http://www.ietf.org/internet-drafts/draft-ietf-mobileip-hmipv6-08.txt and FMIPv6 http://www.ietf.org/internet-drafts/draft-ietf-mobileip-fast-mipv6-06.txt)
– AAA management (http://www.ietf.org/internet-drafts/draft-ietf-mobileip-aaa-key-13.txt)
– QoS issues for MIPv6 (http://www.ietf.org/internet-drafts/draft-ietf-nsis-qos-requirements-01.txt)
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Network Management
• IPv6 Network Management Tool (Magalia)• Intrusion Detection System• Firewalls• Route Server
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How IP Can Reach all the Planet: 6POWER
IPv6, QoS & Power Line Integration
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6QM
IPv6 Quality of Service Measurement
www.6qm.org
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6QM: Objectives• Development of a measurement device for IPv6.• Development of a measurement server.• Integration and local test of the developed
components, for the further trial and evaluation of the developed system.
• Dissemination and Linkage with other relatedForas and Projects, in order to publicize the project results.
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IPv6 Network
Network manager
Element
Network
Service
Business AccountingOrder
managementSLA Manager
GW
GW
Contents provider End- user
Policy/VPN Server
IP measurement
server
Provisioning Surveillance/ SLA guarantee
Billing
Control Monitor Traffic
GW
Management Layer
Target of this project
IP Measurementdevice
IP Measurementdevice
Structure of IP OSS
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Measurement Device and Server• The measurement device inserts precise
timestamp information when it captures the IPv6 packet.
• Each device has time synchronization functionality, by GPS, or any other equivalent mechanism.
• The measurement server collects the captured IPv6 packet.
• Then it provides usage and also QoS metrics (delay, loss, jitter and so on).
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IP Measurement System Structure
IP network
Captured Packets
Measurement device
QoS measurement server
ServerClient
Collected packets
Report
Reporting: delay, loss, jitter, packets amount,
bytes amount
GPS receiver GPS receiver
Measurement device
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QoS & Management• The operators and ISPs must be capable to control the
QoS, to measure it objectively and to share information with the clients according the SLAs contracts.
• These measures are useful also to compare ISPs (comparison of SLAs provided by different ISPs).
• Is necessary to carry out measurement on both, network and application level.
• The correlation processing in the application level needs elaborating very complex rules, so 6QM project focus is only on the network level itself.
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6QM Expected Achievements• Operational rules and practical tools.• Small test-beds and measurement systems,
towards their use in large-scale networks. • Build formal models based on empiric
measures achieved on operational IPv6 networks (e.g., Euro6IX, 6NET)
• Implicate other network communities to build a significant and representative scenario.
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IPv6 Commercial Deployment in Europe
Jordi Palet ([email protected])European IPv6 Task Force & Steering CommitteeIPv6 Forum, Education & Promotion WG Co-chair
Consulintel, CTO/CEO
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The European IPv6 Task Force• The European Commission created the IPv6 TF (2001)• Goal: Prepare the roadmap for the IPv6 adoption and
large scale deployment in 2005
• "Our objective is to ensure that Europe's competitiveness in wireless technology is not jeopardized by the lack of a clear road map towards IPv6," European Enterprise Commissioner Erkki Liikanen said in his opening speech to the IPv6 Task Force.
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The move to IPv6 is Global• January 2002: The TF concluded• February, March and June 2002:
– The EC and the Council publish different documents adopting the TF conclusions.
• e-Europe 2005: IPv6, Broadband and 3G• Continuation of the TF, in a 2nd phase, with the
support of the Steering Committee project• Several European countries (Spain, France, UK,
Germany, Switzerland, …), initiated local activities• Several TF-like groups across the world,
cooperating together
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R&D “Arena”: Past & Present• A few research projects 2-3 years ago (FP5 - IST program)• Now several Research projects representing investments
over 180 MEuros (90 from the EC)• Major platforms and networks:
– 6NET, Euro6IX– Available NOW, and interconnected– With international peering to Japan, Korea, Abilene (Internet2), …– Also to provide native connectivity for other projects
• Over 40 projects:– With IPv6 as the main focus (6POWER, 6QM, 6WINIT, …), or– Using IPv6 for new applications and services (Android, Crumpet, …)
• 6LINK to support the collaboration in the IPv6 Cluster• Eurov6 to provide permanent and nomadic showrooms for
the industrial and R&D achievements
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R&D “Arena”: The Future• Next IST Program, FP6, clearly
supports IPv6, Broadband and 3G as key technologies– Over 900 MEuros in the 1st call (4-5 calls)– International cooperation expected and
highly encouraged• The IPv6 Cluster facilitated the creation
of the “ALL-IPv6-World” WG– 20 Activity areas suggested– Towards new applications and services
• IPv6 as a key enabler of “Ambient Intelligence” www.6link.org
www.ist-ipv6.org
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Deployment Status• European industry is supporting IPv6
– In a short term– Manufacturers of devices, routers– Appliance manufacturers– Application developers
• Several Telcos and ISPs seriously considering commercial deployment, some already started– A few already providing services– GEANT moving to IPv6 NOW
• Education programs still needed
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Pre-Commercial Trials
Torino
Paris
Zurich
Berlin
London
Lisbon
Madrid
Murcia
BernBretigny
Lannion
Aveiro
Issy
Caen
Southampton
Viby
TEF
PT/TEF
TI
TI
FT
FT
DT
IPv6 IX
IPv6 NodeLink Sponsor/s
34 Mbps Native Link
Node to IX Link
name
1) IPv6 in IPv6 Tunnel in own network2) IPv6 over IPv4 over internet/6Bone• Other similar tunnels could be setup
in other links if needed
Alcobendas
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And Moving …
To Commercial
*** With Contributions from SeveralEuropean Telcos andNational IPv6 Task Forces
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Portugal• IPv6 Portuguese Task Force created with the support of UMIC
(Governmental entity responsible for incentive the innovation inPortugal and follow the eEurope 2005 European program).
• Strong involvement in R&D activities (Portugal Telecom Inovação).• No ISPs starting IPv6 commercial operation or public trials in Portugal.
No publicly known dates defined to start.• GigaPIXv6 (public IX operated by FCCN) started operation several
months ago.– FCCN, Vodafone Portugal, Telepac (Portugal Telecom Group) and other
small regional operators (NFSi).• Some companies are performing small internal trials with several
access networks. Telepac: Internal trial with ISDN and preparing for ASDL.– Commercial around 2004
• Other companies from PT Group investing in IPv6 training.• Documentation being written for high level instances on PT, pointing to
start thinking seriously in IPv6.
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France• Strong participation on the France IPv6 Task Force• Deployment of internal IPv6 network between sites of
FTR&D since 1998.• Deployment of a national scale IPv6 and dual-stack high
bandwidth network within VTHDv6 project (national research project).
• Experimentation of a WLAN IPv6 network within Strasbourg University campus.
• Strong involvement in R&D activities
• Operational: Opentransit– France Telecom's carrier has deployed an IPv6 native backbone, in
order to help customers to move forward RIGHT NOW.• IPv6 in 2 IX
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Italy• IPv6 Task Force being kick-off next October• Early participants in IPv6 standards and R&D• Strong involvement in R&D activities• ngnet.it Telecom Italia initiative
– More than 30000 experimental users to Tunnel Broker service– 2000 users connected together
• Applications services:– IPv6 only IRC server with more 1000 users connected together
• Other Telcos starting to be involved in IPv6 in Italy.– Wind– Edisontel
• IPv6 in the two main IX– Milan Internet Exchange– NAMEX (Rome)
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Spain• Strong participation in the Spanish IPv6 Task Force, supported by the
Ministry of Science and Technology• Strong involvement in R&D activities• IPv6 in two IX• DNS root server mirror moving to IPv6 (Espanix)• 1st Newspaper offering all the contents in IPv6 (El Mundo)• 1st Hotel of the World with IPv6• 1st ISP already commercial (arsys)• Several ISPs starting soon …• LMDS service with IPv6 soon …• WLAN service with IPv6 soon …• NAP with IPv6 soon …• Telefónica Data: Transit Pre-commercial pilot, with several customers.
Feel more interest, but still no real business. May be after 2004.
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Switzerland• Swisscom Mobile:
– Plans for GPRS/UMTS, first testing for WLAN.– Commercial expected in 2004 (WLAN) and 2005 (UMTS)
• Swisscom Enterprise Solutions (ISP for business customers):– RIPE IPv6 /32 since Sept 2002, test environment with native IPv6
connectivity to Euro6IX since June 2003.
• Bluewin (ISP for residential customers): RIPE IPv6 /32 since May 2002, test environment.– Commercial expected 2004/2005
• Swisscom Innovations (Swisscom R&D):– 6Bone TLA since 1997, testlabs since then, operational Intranet with
IPv6 support since April 2003.
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Others …• Germany
– Deutsche Telekom and T-Systems are working on IPv6 in projects (European projects, Customer projects) for several years.
– Deutsche Telekom has done an IPv6 Showcase with industry partners and is founding member of the IPv6 Forum and the European and German IPv6 Task Force.
– T-Systems, the system integration subsidiary of Deutsche Telekom, is offering IPv6 in customer projects on a project basis.
• UK– Pre-commercial trials by a number of leading Telco’s, ISPs, IX,
corporations, SMEs and individuals.– BT is heavily involved in R&D, the IPv6 Forum and IPv6 Task Force.
• Several European IXs, some ISPs.• Global carriers with presence in Europe:
– Global Crossing, NTT/Verio, Telia. A few others working on it, but not public info.
• Other countries also involved, including Belgium, Denmark, Sweden and Netherlands.
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The FP5 IPv6 PictureThe FP5 IPv6 Picture• Deployment
– 6NET– Euro6IX
• Promotion– Eurov6– IPv6TF-SC
• Clustering– 6LINK
• Others– More specific
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Big Experimentation Platforms
• In Particular– 6NET and Euro6IX– Total budget: 34 M€– Total EU funding: 18 M€
http://www.6net.org http://www.euro6ix.org
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IPv6 Project Cluster
www.6link.org
www.ist-ipv6.org
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6LINK: Objectives• Consensus building
– IPv6 development– IPv6 deployment
• Dissemination• Exploitation of consensus
– Common trials– Coordinated input to standards
development
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IST IPv6 Cluster• www.ist-ipv6.org• Register and get:
– Newsletter (every 2 months)– Standards report (every 4 months)– Applications Database– Publications– Contact with IPv6 EU Researchers
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Thanks !Contact:• Jordi Palet (Consulintel): [email protected]
• Madrid 2004 IPv6 Summit, information soon available at:http://www.ipv6-es.com
• Euro6IX Project Coordinators ([email protected]):– Jordi Palet Martínez (Consulintel): [email protected]– Carlos Ralli Ucendo (Telefónica I+D): [email protected]