MUSE
MUlti-Service access Everywhere
Vitor Ribeiro
1
, José Miguel Santos
1
, Teresa Almeida
1
, Kare Gustafsson
2
Jeroen Wellen
3
, Jeanne De Jaegher
4
, François Fredricx
4
, Peter Vetter
4
1
Portugal Telecom Inovação S.A., Rua Eng. Ferreira Pinto Basto,
3810-106 Aveiro, Portugal
2
Ericsson AB, Torshamnsgatan 23,
164 80, Stockholm, Sweden
3
Lucent Technologies Nederland BV, Larenseweg 50,
NL-1221 CN, Hilversum, Netherlands
4
Alcatel Research&Innovation, Francis Wellesplein 1,
2018, Antwerpen, Belgium
Keywords. Broadband; Multi-service; Access; Access Nodes; First Mile;
Home Gateways; QoS; Auto-configuration; OAM; CPE; xDSL; FTTx; IPv6;
Ethernet; ATM; Techno-economic; Service enablers; Inter-working; Trials.
Abstract. MUSE is an integrated project of the 6
th
framework European re-
search program.
The overall objective of MUSE is research and development on a future low
cost, full service access and edge network, which enables the ubiquitous
delivery of broadband services to every European citizen.
MUSE project integrates studies in the following areas:
- Access and edge network architectures and techno-economical studies;
- Access and edge platforms;
- First mile solutions (xDSL and optical access);
- Inter-working of the access network with home gateway and local networks;
- Lab trials.
The concepts of MUSE will be validated for three end-to-end deployment
scenarios:
- Migration scenario featuring a hybrid access network of ATM and packet
(Ethernet, IP) network elements and CPE with embedded service awareness
and application enablers;
- Non-legacy scenario showing access nodes, various first mile solutions, and
CPE that are optimised for native Ethernet and IPv6 throughout the home and
access network;
- FTTx scenarios integrating new concepts for access technologies - VDSL,
optical access, and feeders for wireless services, and service-aware CPE.
The expected impact and results are:
- Consensus about the future access and edge network by major operators and
Ribeiro V., Miguel Santos J., Almeida T., Gustafsson K., Wellen J., De Jaegher J., Fredricx F. and Vetter P. (2004).
MUSE - MUlti Service access Everywhere.
In Proceedings of the 1st International Workshop on Shaping the Broadband Society, pages 3-11
DOI: 10.5220/0001403100030011
Copyright
c
SciTePress
vendors in Europe.
- Pre-standardisation work and joint position in standardisation bodies;
- Proof of concept demonstrators and lab trials by operators.
1 Integrated project organization
In order to reach the overall objectives of MUSE in an effective and manageable way,
the integrated project has been organised in four subprojects (SP) (cf. Fig. 1.
Integrated project organization). Subproject A will define the access and edge
network architecture. It will drive the technical directions of the other activities in
MUSE and ensure the overall coherence. Furthermore it will host the techno-
economic evaluation of the various solutions and finally prepare standardisation
inputs. The other subprojects B to D consist of a subset of partners who are co-
operating on solutions for a specific deployment scenario, as further outlined below.
Towards the end of the project, the access networks of the subprojects will be
interconnected to validate their end-to-end interoperability.
Each subproject B to D consists of four work-packages (WP), which are organised
per technical area: Access Platforms, First Mile Solutions, CP Gateways and Private
Networks, and Lab Trials. The subproject organisation ensures the end-to-end
integration of the prototypes from the different WP.
Fig. 1. Integrated project organization.
In order to ensure communication and consensus in the specific technical areas
across the subprojects, four task forces (TF) have been defined. The respective work-
SPA - Access Architecture
TF1 Access Platform s
1.1 Intelligent access & Edge N odes
1.2 O AM M anagem ent
1.3 Node SW Architecture
1.4 Node HW Architecture
T F 2 F irs t m ile s o lu tio n s
1.1 DSL Access
1.2 O ptical Access
1.3 Fixed W ireless A ccess
TF3 CP Gatew ays and Private Netw orks
1.1 Public and Private N W Interw orking
1.2 Hom e G ateway
TF4 Lab Trials
1.1 Test objectives & Test Suites
1.2 Stand-alone lab trials
1.3 Com parison studies (integrated trial)
SPB
Migration
Scenarios
SPC
Non-Lagacy
Scenarios
SPD
Optical
Access
Deploym ent
WP B.1
WP B.2
WP B.3
WP B.4
WP C.1
WP C.2
WP C.3
WP C.4
WP D.1
WP D.2
WP D.3
WP D.4
WP A.1 Services and Applications
WP A.2 Architectures Studies
WP A.3 Techno-Econom ic Studies
2
packages of each subproject can contribute to a task force. The task forces outputs are
common contributions to standardisation, position papers, and comparisons of
different approaches or possible common specifications, so as to ensure global
interoperability, when considering end-to-end solutions.
2 SPA - Access Architectures
The objective of SP A is to create a common vision of the access network
architecture, enabling multi-service broadband access everywhere and for everyone.
For achieving this objective, the research work that will be carried out in the Access
Architectures subproject focuses on three main activities: WP A1 services and
applications, WP A2 network architecture and WP A3 techno-economical studies.
During the whole project, SP A is responsible for the technical management of the
integrated project, ensuring that studies and realisations in other subprojects are in
accordance with the access architecture vision.
All major operators and vendors of MUSE participate in SP A activity.
3 SPB - Migration Scenarios
The focus of this Sub Project is to tackle migration scenarios for the introduction of
multi-services. Migration means that the existing public network situation has to be
taken into account. For that reason, and to facilitate multiple services introduction by
multiple providers, gradual technical changes are applied in the network. The work
also takes the results of the migration studies carried out in SP A into account as
guidance for the activities.
More specifically at layer 2, the migration from ATM to Ethernet will be
addressed, in the light of the need to leverage both technologies in an evolving access
infrastructure and maximise exploitation of existing investments. The current
installed base of broadband access heavily relies on ADSL, using ATM in access and
aggregation networks, and in ongoing mass deployments aimed at providing
ubiquitous broadband service. On the other hand Ethernet is being introduced in the
aggregation network (EMAN) and is the pervasive protocol used in private networks.
Clearly the interaction of ATM with Ethernet has to be thoroughly addressed in order
to support the requirements of the multimedia and emerging peer-to-peer services
(including end-to-end QoS).
Another migration track is the introduction of layer 3 awareness closer to the end
users, e.g. in the DSLAM. These layer 3 (IP) functionalities can be driven by cost
reasons and service reasons. More specifically, inserting service enabling functions
operating at layer 3 and above expands the capabilities of the access nodes in terms of
security, accounting, etc.
3
The considerable installed share of ADSL as first mile broadband technology must
be taken into account for migration scenarios. Here SP B will evaluate technical
improvements and the transition towards other DSL flavours (ADSL2, ADSL2+,
VDSL).
On the user’s side, the protocols (stacks and message flows) in the Home Gateway
(both at public network side and at LAN side) have to be addressed in order to
guarantee the delivery of the multiple services to the end-user and a proper interaction
between user terminals and public network (e.g. for auto-configuration, the migration
from PPP to DHCP must be addressed).
Currently all IP functionalities use IPv4. The evolution to IPv6 raises several
opportunities and issues, and in this subproject the assumption is taken of a gradual
introduction of IPv6 (in the first place in the residential networks and their residential
gateways). Obviously a seamless coexistence with the installed IPv4 base in the
access and aggregation public network is then required [1].
4 SPC - Non-Legacy Scenarios
The focus of SP C is twofold. Firstly, SP C targets a highly scalable platform solution
based on a large (typically 100.000 users) single Ethernet switching domain with
enough QoS to handle quality voice as well as advanced multi-media applications.
This will be based on related work in, e.g.,
DSLForum [2] and IEEE 802.3ah [3]. In
contrast to SP B “Migration Scenarios”, SP C will not take into consideration a
previously installed ATM base in the access part of the network – hereby the name
“Non-legacy scenarios”. Instead, subproject C will use Ethernet as the single
communication technology in order for operators, providers and other parties of the
business chain to provide more and more services at lower cost and in this way
become more competitive. This is indeed a challenge and such a system has not been
demonstrated before. Similar to ATM VC, SP C introduces service bindings, but in
this case within the framework of mass-produced Ethernet technology with variable
length packets size. Since user generated Ethernet packets do not have to be
converted into and from fixed cells, they only have to be transported to the right place
according to the “switch where you can, route where you must” paradigm to keep the
costs for services as low as possible. In order to make this solution widely applicable,
different first mile technologies have to be explored within this framework, e.g.,
Ethernet over DSL (using the already considerable installed copper pair technology)
and Ethernet point-to-point fibre access. Looking to the customer side, the access
network will be terminated by means of a home gateway. An IP phone will also be
brought into the project for evaluation.
Secondly, IPv6 optimised solutions for the same type of network will be explored.
Given the new IPv6 functionality, e.g., L2-addressing, auto-configuration and larger
addressing space, the problem space for a public deployed broadband access network
4
can probably be simplified to a large extent. This has implications on both the
hardware and software architectures. These activities will be carefully coordinated
with related work in, e.g., 6INIT [4] and the IPv6 task force [5]. Use of IPv6 allows
de-centralised routing in access and edge nodes, a feature that has large technical and
economical implications. On the technical side, de-centralised routing networks offer
more throughput and less latency and are less vulnerable to core node failures. On the
economical side, it allows network operators to offer added value through routing
service. The implications of such a scenario on network nodes, services, applications,
business models etc. will be studied in close co-operation with SP A.
Both approaches will work in parallel and together to see how different exacting
problems related to the open multi-service environment can be solved. Focus
questions will be how to meet the challenging QoS requirements, the required VPN
functionality, auto-configuration, standardised open outer interfaces and OAM
solutions that enable end-to-end QoS, full automation of customer interaction,
network management and requirements on system and service management in edge
nodes and CPEs.
The subproject also has at its disposal several sites to perform early and continuous
trials both in the labs but also in the field with live customers. SP C will use these to
test early prototypes coming both from inside and outside of MUSE in order to guide
the further work.
5 SPD - Optical Access Deployment
Subproject D will address the challenges imposed by the deployment of fibre optic
access in Europe. This sub project will focus on the migration of current
infrastructures to high-speed fibre-based access facilities, including migration through
VDSL, and on the interaction with multi-service gateways at the customer. Based on
the studies in Subproject A and further detailed discussions within the different
taskforces, a further elaboration on the specification and design of last mile
technologies and customer terminals will be performed.
Although current access infrastructures are being upgraded to provide broadband
services, the deployment of FTTH is still considered disruptive from an economic
point of view. The most important reason is the huge investment needed to roll out
the last portion of fibre to connect residential and small business users, and the de-
investment of existing copper-based last-mile networks. Another reason is that
current networks, cable, DSL and PSTN, deliver dedicated services and their
associated QoS and operation characteristics. Current edge and access nodes have
become a patchwork of functions for different last-mile services. On the other side,
the market for end-user routers and gateways is booming, without facilities and
support for communication and other QoS sensitive services. Subproject D will
provide solutions for deploying optical access by determining techno-economic,
operational and also practical issues that obstruct introduction. Based on this, a set of
5
tools will be developed which, for the architectural part of it will be fed back to
subproject A. Furthermore, novel enabling technologies will be developed resulting
in lab demonstrations.
6 Task Forces
In addition to the in-depth research and prototyping work in subprojects B-D, consen-
sus related activities across the subprojects will be conducted in four task forces. The
outputs of the task forces are common contributions to standardisation, position pa-
pers, or comparisons of different approaches.
6.1 TF1 - Access Platforms
TF1 will pursue consensus on the proposed solutions for an open multi-service access
platform at a node level. The following areas of common interest have been identified
within the task force:
- End-to-end Quality of Service (QoS);
- Definition of NSM/OAM functionality in the multi-service access network;
- Identify possible advantages of IPv6 for the access and edge network
One of the major results from TF1 activities will be a description of concept,
implementation and functionality of a European telecom access platform.
6.2 TF2 – First Mile Solutions
The main function of the First Mile solutions is to distribute and aggregate traffic
associated with all types of services between Access Multiplexers and the users.
Since installation and maintenance of access infrastructures will take much, if not
most, of the network investments it is vital to keep the costs of new fibre and fixed
wireless technologies low, while the economic lifetime of existing copper
infrastructures should be extended as much as possible.
In the area of DSL access, the purpose will be to align the technological
enhancements studied in the different subprojects, in particular Architecture and
Migration issues: network management of quasi-autonomous DSL systems, best
practices for OAM, loop-qualification, ADSL to VDSL upgrading, spectral
management, and the coordination of standardisation efforts.
In the area of optical access, the purpose will be to compare architectural options
addressed in subprojects C and D, as well as in former FP5 projects, and to generate
recommendations on low-cost fibre deployment
6
6.3 TF3 – CP Gateways and Private Networks
The Gateway is a strategic component being the bridge between CP/Home/Private
Networks and Public Networks. While Private Networks have to take PC and LAN
technologies as a given, Public Network functionality will be enhanced in MUSE,
encompassing mainly QoS/ VPN support and auto-configuration. It enables new
applications and plug-and-play operation to the subscriber. Figure 2 shows the Gate-
way reference architecture, consisting of a Private Network part and a Public Net-
work compliant part, both separated by a reference point. Public and Private Network
functionalities may be concentrated in one physical box, but could be distributed over
distinct devices in the Private Network.
Fig. 2. Gateway reference architecture
In current networks the subscriber interfaces for broadband service are operator
specific. TF3 will improve this situation by defining a common subscriber interface
based on the network architecture of SP A.
6.4 TF4 – Lab trials and Demos
Test objectives and test suites:
The purpose of this task force is to define the test objectives and a test suite that
will be used as a basis for the different subprojects B, C and D. It should be well
defined what to test, how to test it and how to quantify the associated "performance".
Comparison studies of trials:
These activities focus on comparing different concepts, in an objectively
comparable way, including those resulting from different sub-projects.
The comparison studies generate essential information to operators on the direction
of migrating their networks.
Integrated interoperability demo:
A last activity of this task force is the co-ordination of full service, end-to-end, lab
trials that integrate the set-ups realised in the different subprojects B, C and D (see
Figure 3). Objective is to show the interoperability of the network functions in the
respective platforms of subprojects B, C and D.
Public
network
compliant
Part
Private
network
Part
Public Network
Private Network
Gateway
Reference point
Subscriber-Interface
7
Fig. 3. Top level view of integrated trial
7 MUSE Partners
The following entities are participating in the MUSE Integrated Project:
Alcatel, Ericsson, Lucent Technologies, Siemens, Thomson Multimedia, Infineon
Technologies, STMicroelectronics, BT, France Telecom R&D, Portugal Telecom
Inovação, TNO Telecom, Telefónica Investigación y Desarrollo, TeliaSonera,
Telecom Italia, T-Systems Nova, The Broadband Society of Aarhus, Fundacion
Robotiker, Interuniversitair Micro-Elektronica Centrum (IMEC), Institut National de
Recherche en Informatique et Automatique (INRIA), Budapest University of
Technology and Economics, Institute of Communication and Computer Systems of
the National Technical University of Athens (ICCS/NTUA), Lund University, Acreo,
Universidad Carlos III de Madrid, Fraunhofer Institute for Telecommunications –
Heinrich Herz Institute, Technische Universiteit Eindhoven, and University of Essex.
8 Conclusions
The MUSE project is a wide and ambitious European consortium that aims to provide
expertise and guidelines to the networking community for supporting a generalised
and ubiquitous offer of Broadband services.
In that pursuit, MUSE achieved bringing together both academic and competitive
industrial and network operator partners, specialised in a wide variety of technologies
Carrier
SP C
SP D
SP B
Application
ser ver s
Se r v i c e
packet
gateway
Home
Gateway
Home
Gateway
Access
Multiplexer
Access
Multiplexer
Edge
Sw i t c h
Ed g e
Sw i t c h
Home
Gateway
8
for the edge and access network, working in order to reach consensus and compatible
solutions for Multi service access everywhere.
Effort will also be directed to proof the viability of the solutions through trials, and
important techno-economic analysis.
This common effort is accompanied by the necessary pre-standardisation work in
order to permit a generalised adoption of the developed solutions by several
networking players and allow inter-working. One important objective is to show the
interoperability of the network functions in the respective platforms of subprojects B,
C and D.
As a conclusion, although ambitious, and in spite of its complexity, MUSE is a
pragmatic project, whose success will be based on the explained strategy.
References
1. Waddington, D.G.; Fangzhe Chang, “Realizing the transition to IPv6”, IEEE Communica-
tions Magazine, Volume: 40 Issue: 6, Jun 2002, Page(s): 138 –147
2. DSL Forum (http://www.dslforum.org/)
3. IEEE 802.3ah (EFM) - www.ieee802.org/3/efm
4. IPv6 INternet IniTiative (http://www.6init.org)
5. IPv6 Task Force (http://www.ipv6tf.org/ and http://www.ec.ipv6tf.org/in/i-index.php)
9