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Network Working Group                                      T. Melia, Ed.
Request for Comments: 5164                                 Cisco Systems
Category: Informational                                       March 2008


             Mobility Services Transport: Problem Statement

Status of This Memo

   This memo provides information for the Internet community.  It does
   not specify an Internet standard of any kind.  Distribution of this
   memo is unlimited.

Abstract

   There are ongoing activities in the networking community to develop
   solutions that aid in IP handover mechanisms between heterogeneous
   wired and wireless access systems including, but not limited to, IEEE
   802.21.  Intelligent access selection, taking into account link-layer
   attributes, requires the delivery of a variety of different
   information types to the terminal from different sources within the
   network and vice-versa.  The protocol requirements for this
   signalling have both transport and security issues that must be
   considered.  The signalling must not be constrained to specific link
   types, so there is at least a common component to the signalling
   problem, which is within the scope of the IETF.  This document
   presents a problem statement for this core problem.
























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Table of Contents

   1. Introduction ....................................................2
   2. Terminology .....................................................3
      2.1. Requirements Language ......................................3
   3. Definition of Mobility Services .................................4
   4. Deployment Scenarios for MoS ....................................4
      4.1. End-to-End Signalling and Transport over IP ................5
      4.2. End-to-End Signalling and Partial Transport over IP ........5
      4.3. End-to-End Network-to-Network Signalling ...................6
   5. MoS Transport Protocol Splitting ................................7
      5.1. Payload Formats and Extensibility Considerations ...........8
      5.2. Requirements on the Mobility Service Transport Layer .......8
   6. Security Considerations ........................................11
   7. Conclusions ....................................................12
   8. Acknowledgements ...............................................13
   9. References .....................................................13
      9.1. Normative References ......................................13
      9.2. Informative References ....................................13
   Contributors ......................................................14

1.  Introduction

   This document provides a problem statement for the exchange of
   information to support handover in heterogeneous link environments
   [1].  This mobility support service allows more sophisticated
   handover operations by making available information about network
   characteristics, neighboring networks and associated characteristics,
   indications that a handover should take place, and suggestions for
   suitable target networks to which to handover.  The mobility support
   services are complementary to IP mobility mechanisms [4], [5], [6],
   [7], [8], [9] to enhance the overall performance and usability
   perception.

   There are two key attributes to the handover support service problem
   for inter-technology handovers:

   1. The Information: the information elements being exchanged.  The
       messages could be of a different nature, such as information,
       commands to perform an action, or events informing of a change,
       potentially being defined following a common structure.










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   2. The Underlying Transport: the transport mechanism to support
       exchange of the information elements mentioned above.  This
       transport mechanism includes information transport, discovery of
       peers, and the securing of this information over the network.

   The initial requirement for this protocol comes from the need to
   provide a transport for the Media Independent Handover (MIH) protocol
   being defined by IEEE 802.21 [1], which is not bound to any specific
   link layer and can operate over more that one network-layer hop.  The
   solution should be flexible to accommodate evolution in the MIH
   standard, and should also be applicable for other new mobility
   signalling protocols that have similar message patterns and discovery
   and transport requirements.

   The structure of this document is as follows.  Section 3 defines
   Mobility Services.  Section 4 provides a simple model for the
   protocol entities involved in the signalling and their possible
   relationships.  Section 5 describes a decomposition of the signalling
   problem into service-specific parts and a generic transport part.
   Section 5.2 describes more detailed requirements for the transport
   component.  Section 6 provides security considerations.  Section 7
   summarizes the conclusions and open issues.

2.  Terminology

   The following abbreviations are used in the document:

      MIH: Media Independent Handover

      MN: Mobile Node

      NN: Network Node, intended to represent some device in the network
      (the location of the node, e.g., in the access network, the home
      network is not specified, and for the moment it is assumed that
      they can reside anywhere).

      EP: Endpoint, intended to represent the terminating endpoints of
      the transport protocol used to support the signalling exchanges
      between nodes.

2.1.  Requirements Language

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in RFC 2119 [2].






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3.  Definition of Mobility Services

   As mentioned in the Introduction, mobility (handover) support in
   heterogeneous wireless environments requires functional components
   located either in the mobile terminal or in the network to exchange
   information and eventually to make decisions upon this information
   exchange.  For instance, traditional host-based handover solutions
   could be complemented with more sophisticated network-centric
   solutions.  Also, neighborhood discovery, potentially a complex
   operation in heterogeneous wireless scenarios, can result in a
   simpler step if implemented with a unified interface towards the
   access network.

   In this document, the different supporting functions for Media
   Independent Handover (MIH) management are generally referred to as
   Mobility Services (MoS) that have different requirements for the
   transport protocol.  These requirements and associated
   functionalities are the focus of this document.  Speaking 802.21
   terminology, MoS can be regarded as Information Services (IS), Event
   Services (ES), and Command Service (CS).

4.  Deployment Scenarios for MoS

   The deployment scenarios are outlined in the following sections.

      Note: while MN-to-MN signalling exchanges are theoretically
      possible, these are not currently being considered.

   The following scenarios are discussed for understanding the overall
   problem of transporting MIH protocol.  Although these are all
   possible scenarios and MIH services can be delivered through
   link-layer specific solutions and/or through a "layer 3 or above"
   protocol, this problem statement focuses on the delivery of
   information for Mobility Services only for the latter case.

















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4.1.  End-to-End Signalling and Transport over IP

   In this case, the end-to-end signalling used to exchange the handover
   information elements (the Information Exchange) runs end-to-end
   between MN and NN.  The underlying transport is also end-to-end.

      +------+                              +------+
      |  MN  |                              |  NN  |
      | (EP) |                              | (EP) |
      +------+                              +------+
                   Information Exchange
          <------------------------------------>

          /------------------------------------\
         <          Transport over IP           >
          \------------------------------------/

      Figure 1: End-to-End Signalling and Transport

4.2.  End-to-End Signalling and Partial Transport over IP

   As before, the Information Exchange runs end-to-end between the MN
   and the second NN.  However, in this scenario, some transport means
   other than IP are used from the MN to the first NN, and the transport
   over IP is used only between NNs.  This is analogous to the use of
   EAP end-to-end between Supplicant and Authentication Server, with an
   upper-layer multihop protocol, such as Remote Authentication Dial-In
   User Service (RADIUS), used as a backhaul transport protocol between
   an Access Point and the Authentication Server.

      +------+           +------+           +------+
      |  MN  |           |  NN  |           |  NN  |
      |      |           | (EP) |           | (EP) |
      +------+           +------+           +------+
                   Information Exchange
          <------------------------------------>

           (Transport over  /------------------\
          <--------------->< Transport over IP  >
               e.g. L2)     \------------------/

            Figure 2: Partial Transport









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4.3.  End-to-End Network-to-Network Signalling

   In this case, NN to NN signalling is envisioned.  Such a model should
   allow different network components to gather information from each
   other.  This is useful for instance in conditions where network
   components need to make decisions and instruct mobile terminals of
   operations to be executed.

      +------+          +------+
      |  NN  |          |  NN  |
      | (EP) |          | (EP) |
      +------+          +------+
         Information Exchange
         ------------------->
         <-------------------

         /----------------\
        <    Transport     >
         \----------------/

      Figure 3: Information Exchange between Different NNs

   Network nodes exchange information about the status of connected
   terminals.



























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5.  MoS Transport Protocol Splitting

   Figure 4 shows a model where the Information Exchanges are
   implemented by a signalling protocol specific to a particular
   mobility service, and these are relayed over a generic transport
   layer (the Mobility Service Transport Layer).

                        +----------------+          ^
                        |Mobility Support|          |
                        |   Service 2    |          |
     +----------------+ |                |          | Mobility Service
     |Mobility Support| +----------------+          |    Signaling
     |    Service 1   |    +----------------+       |      Layer
     |                |    |Mobility Support|       |
     +----------------+    |   Service 3    |       |
                           |                |       |
                           +----------------+       V
   ================================================
      +---------------------------------------+     ^ Mobility Service
      |  Mobility Service Transport Protocol  |     |    Transport
      +---------------------------------------+     V      Layer
   ================================================
      +---------------------------------------+
      |                   IP                  |
      +---------------------------------------+

          Figure 4: Handover Services over IP

   The Mobility Service Transport Layer provides certain functionality
   (outlined in Section 5.2) to the higher-layer mobility support
   services in order to support the exchange of information between
   communicating Mobility Service functions.  The transport layer
   effectively provides a container capability to mobility support
   services, as well as any required transport and security operations
   required to provide communication, without regard to the protocol
   semantics and data carried in the specific Mobility Services.

   The Mobility Support Services themselves may also define certain
   protocol exchanges to support the exchange of service-specific
   information elements.  It is likely that the responsibility for
   defining the contents and significance of the information elements is
   the responsibility of standards bodies other than the IETF.  Example
   Mobility Services include the Information Services, Event Services,
   and Command Services.







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5.1.  Payload Formats and Extensibility Considerations

   The format of the Mobility Service Transport Protocol (MSTP) is as
   follows:

      +----------------+----------------------------------------+
      |Mobility Service|           Opaque Payload               |
      |Transport Header|     (Mobility Support Service)         |
      +----------------+----------------------------------------+

                   Figure 5: Protocol Structure

   This figure shows the case for an MIH message that is smaller than
   the MTU of the path to the destination.  A larger payload may require
   the transport protocol to transparently fragment and reassemble the
   MIH message.

   The opaque payload encompasses the Mobility Support Service (MSTP)
   information that is to be transported.  The definition of the
   Mobility Service Transport Header is something that is best addressed
   within the IETF.  MSTP does not inspect the payload, and any required
   information will be provided by the MSTP users.

5.2.  Requirements on the Mobility Service Transport Layer

   The following section outlines some of the general transport
   requirements that should be supported by the Mobility Service
   Transport Protocol.  Analysis has suggested that at least the
   following need to be taken into account:

   Discovery:  MNs need the ability to either discover nodes that
      support certain services or discover services provided by a
      certain node.  The service discovery can be dealt with using
      messages as defined in [1].  This section refers to node-discovery
      in either scenario.  There are no assumptions about the location
      of these Mobility Service nodes within the network.  Therefore,
      the discovery mechanism needs to operate across administrative
      boundaries.  Issues such as speed of discovery, protection against
      spoofing, when discovery needs to take place, and the length of
      time over which the discovery information may remain valid; all
      need to be considered.  Approaches include:

      *  Hard coding information into the MN, indicating either the IP
         address of the NN, or information about the NN that can be
         resolved onto an IP address.  The configuration information
         could be managed dynamically, but assumes that the NN is
         independent of the access network to which the MN is currently
         attached.



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      *  Pushing information to the MN, where the information is
         delivered to the MN as part of other configuration operations,
         for example, via DHCP or Router Discovery exchange.  The
         benefit of this approach is that no additional exchanges with
         the network would be required, but the limitations associated
         with modifying these protocols may limit applicability of the
         solution.

      *  MN dynamically requesting information about a node, which may
         require both MN and NN support for a particular service
         discovery mechanism.  This may require additional support by
         the access network (e.g., multicast or anycast) even when it
         may not be supporting the service directly itself.

      Numerous directory and configuration services already exist, and
      reuse of these mechanisms may be appropriate.  There is an open
      question about whether multiple methods of discovery would be
      needed, and whether NNs would also need to discover other NNs.
      The definition of a service also needs to be determined, including
      the granularity of the description.  For example, IEEE 802.21
      specifies three different types of Mobility Services (Information
      Services, Command Services, and Event Services) that can be
      located in different portions of the network.  An MN could
      therefore run a discovery procedure of any service running in the
      (home or visited) network or could run a discovery procedure for a
      specific service.

   Information from a trusted source:  The MN uses the Mobility Service
      information to make decisions about what steps to take next.  It
      is essential that there is some way to ensure that the information
      received is from a trustworthy source.  This requirement should
      reuse trust relationships that have already been established in
      the network, for example, on the relationships established by the
      Authentication, Authorization, and Accounting (AAA) infrastructure
      after a mutual authentication, or on the certificate
      infrastructure required to support SEND [10].  Section 6 provides
      a more complete analysis.

   Security association management:  A common security association
      negotiation method, independent of any specific MSTP user, should
      be implemented between the endpoints of the MSTP.  The solution
      must also work in the case of MN mobility.

   Secure delivery:  The Mobility Service information must be delivered
      securely (integrity and confidentiality) between trusted peers,
      where the transport may pass though untrusted intermediate nodes
      and networks.  The Mobility Service information should also be
      protected against replay attacks and denial-of-service attacks.



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   Low latency:  Some of the Mobility Services generate time-sensitive
      information.  Therefore, there is a need to deliver the
      information over quite short timescales, and the required lifetime
      of a connection might be quite short-lived.  As an example, the
      frequency of messages defined in [1] varies according to the MIH
      service type.  It is expected that Events and Commands messages
      arrive at an interval of hundreds of milliseconds in order to
      capture quick changes in the environment and/or process handover
      commands.  On the other hand, Information Service messages are
      mainly exchanged each time a new network is visited that may be in
      the order of hours or days.  For reliable delivery, short-lived
      connections could be set up as needed, although there is a
      connection setup latency associated with this approach.
      Alternatively, a long-lived connection could be used, but this
      requires advanced warning of being needed and some way to maintain
      the state associated with the connection.  It also assumes that
      the relationships between devices supporting the mobility service
      are fairly stable.  Another alternative is connectionless
      operation, but this has interactions with other requirements, such
      as reliable delivery.

   Reliability:  Reliable delivery for some of the Mobility Services may
      be essential, but it is difficult to trade this off against the
      low latency requirement.  It is also quite difficult to design a
      robust, high-performance mechanism that can operate in
      heterogeneous environments, especially one where the link
      characteristics can vary quite dramatically.  There are two main
      approaches that could be adopted:

      1. Assume the transport cannot be guaranteed to support reliable
         delivery.  In this case, the Mobility Support Service itself
         will have to provide a reliability mechanism (at the MIH level)
         to allow communicating endpoints to acknowledge receipt of
         information.

      2. Assume the underlying transport will provide reliable delivery.
         There is no need in this case to provide reliability at the MIH
         level.

      Guidelines provided in [3] are being considered while writing this
      document.

   Congestion Control:  A Mobility Service may wish to transfer small or
      large amounts of data, placing different requirements for
      congestion control in the transport.  As an example, the MIH
      message [1] size varies widely from about 30 bytes (for a
      broadcast capability discovery request) to be normally less than
      64 KB, but may be greater than 64KB (for an IS MIH_Get_Information



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      response primitive).  A typical MIH message size for the Events
      and Commands Services service ranges between 50 to 100 bytes.  The
      solution should consider different congestion control mechanisms
      depending on the amount of data generated by the application (MIH)
      as suggested in [3].

   Fragmentation and reassembly:  ES and CS messages are small in
      nature, are sent frequently, and may wish trade reliability in
      order to satisfy the tight latency requirements.  On the other
      hand, IS messages are more resilient in terms of latency
      constraints, and some long IS messages could exceed the MTU of the
      path to the destination.  Depending on the choice of the transport
      protocol, different fragmentation and reassembly strategies are
      required.

   Multihoming:  For some Information Services exchanged with the MN,
      there is a possibility that the request and response messages
      could be carried over two different links.  For example, a
      handover command request is on the current link while the response
      could be delivered on the new link.  It is expected that the
      transport protocol is capable of receiving information via
      multiple links.  It is also expected that the MSTP user combines
      information belonging to the same session/transaction.  When
      mobility is applied, the underlying IP mobility mechanism should
      provide session continuity when required.

   IPv4 and IPv6 support:  The MSTP must support both IPv4 and IPv6
      including NAT traversal for IPv4 networks and firewall
      pass-through for IPv4 and IPv6 networks.

6.  Security Considerations

   Network-supported Mobility Services aim at improving decision making
   and management of dynamically connected hosts.

   Information Services may not require authorization of the client, but
   both Event and Command Services may authenticate message sources,
   particularly if they are mobile.  Network-side service entities will
   typically need to provide proof of authority to serve visiting
   devices.  Where signalling or radio operations can result from
   received messages, significant disruption may result from processing
   bogus or modified messages.  The effect of processing bogus messages
   depends largely upon the content of the message payload, which is
   handled by the handover services application.  Regardless of the
   variation in effect, message delivery mechanisms need to provide
   protection against tampering, spoofing, and replay attacks.





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   Sensitive and identifying information about a mobile device may be
   exchanged during handover-service message exchange.  Since handover
   decisions are to be made based upon message exchanges, it may be
   possible to trace a user's movement between cells, or predict future
   movements, by inspecting handover service messages.  In order to
   prevent such tracking, message confidentiality and message integrity
   should be available.  This is particularly important because many
   mobile devices are associated with only one user, since divulging of
   such information may violate the user's privacy.  Additionally,
   identifying information may be exchanged during security association
   construction.  As this information may be used to trace users across
   cell boundaries, identity protection should be available, if
   possible, when establishing source addresses (SAs).

   In addition, the user should not have to disclose its identity to the
   network (anymore than it needed to during authentication) in order to
   access the Mobility Support Services.  For example, if the local
   network is just aware that an anonymous user with a subscription to
   "example.com" is accessing the network, the user should not have to
   divulge their true identity in order to access the Mobility Support
   Services available locally.

   Finally, the NNs themselves will potentially be subject to
   denial-of-service attacks from MNs, and these problems will be
   exacerbated if operation of the Mobility Service protocols imposes a
   heavy computational load on the NNs.  The overall design has to
   consider at what stage (e.g., discovery, transport layer
   establishment, and service-specific protocol exchange) denial-of-
   service prevention or mitigation should be built in.

7.  Conclusions

   This document outlined a broad problem statement for the signalling
   of information elements across a network to support Mobility
   Services.  In order to enable this type of signalling service, a need
   for a generic transport solution with certain transport and security
   properties was outlined.  Whilst the motivation for considering this
   problem has come from work within IEEE 802.21, a desirable goal is to
   ensure that solutions to this problem are applicable to a wider range
   of Mobility Services.

   It would be valuable to establish realistic performance goals for the
   solution to this common problem (i.e., transport and security
   aspects) using experience from previous IETF work in this area and
   knowledge about feasible deployment scenarios.  This information
   could then be used as an input to other standards bodies in assisting
   them to design Mobility Services with feasible performance
   requirements.



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   Much of the functionality required for this problem is available from
   existing IETF protocols or combination thereof.  This document takes
   no position on whether an existing protocol can be adapted for the
   solution or whether new protocol development is required.  In either
   case, we believe that the appropriate skills for development of
   protocols in this area lie in the IETF.

8.  Acknowledgements

   Thanks to Subir Das, Juan Carlos Zuniga, Robert Hancock, and
   Yoshihiro Ohba for their input.  Thanks to the IEEE 802.21 chair,
   Vivek Gupta, for coordinating the work and supporting the IETF
   liaison.  Thanks to all IEEE 802.21 WG folks who contributed to this
   document indirectly.

9.  References

9.1.  Normative References

   [1]    "Draft IEEE Standard for Local and Metropolitan Area Networks:
          Media Independent Handover Services", IEEE LAN/MAN Draft IEEE
          P802.21/D07.00, July 2007.

   [2]    Bradner, S., "Key words for use in RFCs to Indicate
          Requirement Levels", BCP 14, RFC 2119, March 1997.

9.2.  Informative References

   [3]    Eggert, L. and G. Fairhurst, "UDP Usage Guidelines for
          Application Designers", Work in Progress.

   [4]    3GPP, "3GPP system architecture evolution (SAE): Report on
          technical options and conclusions", 3GPP TR 23.882 0.10.1,
          February 2006.

   [5]    Perkins, C., Ed., "IP Mobility Support for IPv4", RFC 3344,
          August 2002.

   [6]    Johnson, D., Perkins, C., and J. Arkko, "Mobility Support in
          IPv6", RFC 3775, June 2004.

   [7]    Moskowitz, R. and P. Nikander, "Host Identity Protocol (HIP)
          Architecture", RFC 4423, May 2006.

   [8]    Eronen, P., "IKEv2 Mobility and Multihoming Protocol
          (MOBIKE)", RFC 4555, June 2006.





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   [9]    Koodli, R., Ed., "Fast Handovers for Mobile IPv6", RFC 4068,
          July 2005.

   [10]   Arkko, J., Ed., Kempf, J., Zill, B., and P. Nikander, "SEcure
          Neighbor Discovery (SEND)", RFC 3971, March 2005.

Contributors' Addresses

   Eleanor Hepworth
   Siemens Roke Manor Research
   Roke Manor
   Romsey,   SO51 5RE
   UK

   EMail: eleanor.hepworth@roke.co.uk


   Srivinas Sreemanthula
   Nokia Research Center
   6000 Connection Dr.
   Irving,   TX 75028
   USA

   EMail: srinivas.sreemanthula@nokia.com


   Yoshihiro Ohba
   Toshiba America Research, Inc.
   1 Telcordia Drive
   Piscateway  NJ 08854
   USA

   EMail: yohba@tari.toshiba.com


   Vivek Gupta
   Intel Corporation
   2111 NE 25th Avenue
   Hillsboro, OR  97124
   USA

   Phone: +1 503 712 1754
   EMail: vivek.g.gupta@intel.com








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   Jouni Korhonen
   TeliaSonera Corporation.
   P.O.Box 970
   FIN-00051 Sonera
   FINLAND

   Phone: +358 40 534 4455
   EMail: jouni.korhonen@teliasonera.com


   Rui L.A. Aguiar
   Instituto de Telecomunicacoes Universidade de Aveiro
   Aveiro  3810
   Portugal

   Phone: +351 234 377900
   EMail: ruilaa@det.ua.pt


   Sam(Zhongqi) Xia
   Huawei Technologies Co., Ltd
   HuaWei Bld., No.3 Xinxi Rd. Shang-Di Information Industry Base
   100085
   Hai-Dian District Beijing, P.R. China

   Phone: +86-10-82836136
   EMail: xiazhongqi@huawei.com

Authors' Addresses

   Telemaco Melia, Editor
   Cisco Systems International Sarl
   Avenue des Uttins 5
   1180 Rolle
   Switzerland (FR)

   Phone: +41 21 822718
   EMail: tmelia@cisco.com













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Full Copyright Statement

   Copyright (C) The IETF Trust (2008).

   This document is subject to the rights, licenses and restrictions
   contained in BCP 78, and except as set forth therein, the authors
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