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Network Working Group                                          B. O'Hara
Request for Comments: 3990                                    P. Calhoun
Category: Informational                                        Airespace
                                                                J. Kempf
                                                         Docomo Labs USA
                                                           February 2005


  Configuration and Provisioning for Wireless Access Points (CAPWAP)
                           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.

Copyright Notice

   Copyright (C) The Internet Society (2005).

Abstract

   This document describes the Configuration and Provisioning for
   Wireless Access Points (CAPWAP) problem statement.

1.  Introduction

   With the approval of the 802.11 standard by the IEEE in 1997,
   wireless LANs (WLANs) began a slow entry into enterprise networks.
   The limited data rates of the original 802.11 standard, only 1 and 2
   Mbps, limited the widespread adoption of the technology.  802.11
   found wide deployment in vertical applications, such as inventory
   management, point of sale, and transportation management.  Pioneering
   enterprises began to deploy 802.11, mostly for experimentation.

   In 1999, the IEEE approved the 802.11a and 802.11b amendments to the
   base standard, increasing the available data rate to 54 and 11 Mbps,
   respectively, and expanding to a new radio band.  This removed one of
   the significant factors holding back adoption of 802.11 in large
   enterprise networks.  These large deployments were bound by the
   definition and functionality of an 802.11 Access Point (AP), as
   described in the 802.11 standard.  The techniques required extensive
   use of layer 2 bridging and widespread VLANs to ensure the proper
   operation of higher layer protocols.  Deployments of 802.11 WLANs as
   large as several thousand APs have been described.





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RFC 3990                CAPWAP Problem Statement           February 2005


   Large deployments of 802.11 WLANs have introduced several problems
   that require solutions.  The limitations on the scalability of
   bridging should come as no surprise to the networking community, as
   similar limitations arose in the early 1980s for wired network
   bridging during the expansion and interconnection of wired local area
   networks.  This document will describe the problems introduced by the
   large-scale deployment of 802.11 WLANs in enterprise networks.

2.  Problem Statement

   Large WLAN deployments introduce several problems.  First, each AP is
   an IP-addressable device requiring management, monitoring, and
   control.  Deployment of a large WLAN will typically double the number
   of network infrastructure devices that require management.  This
   presents a significant additional burden to the network
   administration resources and is often a hurdle to adoption of
   wireless technologies, particularly because the configuration of each
   access point is nearly identical to the next.  This near-sameness
   often leads to misconfiguration and improper operation of the WLAN.

   Second, distributing and maintaining a consistent configuration
   throughout the entire set of access points in the WLAN is
   problematic.  Access point configuration consists of both long-term
   static information (such as addressing and hardware settings) and
   more dynamic provisioning information (such as individual WLAN
   settings and security parameters).  Large WLAN installations that
   have to update dynamic provisioning information in all the APs in the
   WLAN require a prolonged phase-over time.  As each AP is updated, the
   WLAN will not have a single, consistent configuration.

   Third, dealing effectively with the dynamic nature of the WLAN medium
   itself is difficult.  Due to the shared nature of the wireless medium
   (shared with APs in the same WLAN, with APs in other WLANs, and with
   devices that are not APs at all), parameters controlling the wireless
   medium on each AP must be monitored frequently and modified in a
   coordinated fashion to maximize WLAN performance.  This must be
   coordinated among all the access points, to minimize the interference
   of one access point with its neighbors.  Manually monitoring these
   metrics and determining a new, optimum configuration for the
   parameters related to the wireless medium is a task that takes
   significant time and effort.

   Fourth, securing access to the network and preventing installation of
   unauthorized access points is challenging.  Physical locations for
   access points are often difficult to secure since their location must
   often be outside of a locked network closet or server room.  Theft of
   an access point, with its embedded secrets, allows a thief to obtain
   access to the resources secured by those secrets.



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RFC 3990                CAPWAP Problem Statement           February 2005


   Recently, to address some, or all, of the above problems, multiple
   vendors have begun offering proprietary solutions that combine
   aspects of network switching, centralized control and management, and
   distributed wireless access in a variety of new architectures.  Since
   interoperable solutions allow enterprises and service providers a
   broader choice, a standardized, interoperable interface between
   access points and a centralized controller addressing the problems
   seems desirable.

   In currently fielded devices, the physical portions of this network
   system are one or more 802.11 access points (APs) and one or more
   central control devices, alternatively described as controllers (or
   as access controllers, ACs).  Ideally, a network designer would be
   able to choose one or more vendors for the APs and one or more
   vendors for the central control devices in sufficient numbers to
   design a network with 802.11 wireless access to meet the designer's
   requirements.

   Current implementations are proprietary and are not interoperable.
   This is due to a number of factors, including the disparate
   architectural choices made by the various manufacturers.  A taxonomy
   of the architectures employed in the existing products in the market
   will provide the basis of an output document to be provided to the
   IEEE 802.11 Working Group.  This taxonomy will be utilized by the
   802.11 Working Group as input to their task of defining the
   functional architecture of an access point.  The functional
   architecture, including descriptions of detailed functional blocks,
   interfaces, and information flow, will be reviewed by CAPWAP to
   determine if further work is necessary to apply or develop standard
   protocols providing for multi-vendor interoperable implementations of
   WLANs built from devices that adhere to the newly appearing
   hierarchical architecture using a functional split between an access
   point and an access controller.

3.  Security Considerations

   The devices used in WLANs control network access and provide for the
   delivery of packets between hosts using the WLAN and other hosts on
   the WLAN or elsewhere on the Internet.  Therefore, the functions for
   control and provisioning of wireless access points, require
   protection to prevent misuse of the devices.

   Confidentiality, integrity, and authenticity requirements should
   address central management, monitoring, and control of wireless
   access points that should be addressed.  Once an AP and AC have been
   authenticated to each other, a single level of authorization allowing
   monitoring, control, and provisioning may not be sufficient.  The
   requirement for more than a single level of authorization should be



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RFC 3990                CAPWAP Problem Statement           February 2005


   determined.  Physical security should also be addressed for those
   devices that contain sensitive security parameters that might
   compromise the security of the system, if those parameters were to
   fall into the hands of an attacker.

   To provide comprehensive radio coverage, APs are often installed in
   locations that are difficult to secure.  The CAPWAP architecture may
   reduce the consequences of a stolen AP.  If high-value secrets, such
   as a RADIUS shared secret, are stored in the AC, then the physical
   loss of an AP does not compromise these secrets.  Further, the AC can
   easily be located in a physically secure location.  Of course,
   concentrating all the high-value secrets in one place makes the AC an
   attractive target, and strict physical, procedural, and technical
   controls are needed to protect the secrets.

Authors' Addresses

   Bob O'Hara
   Airespace
   110 Nortech Parkway
   San Jose, CA  95134

   Phone: +1 408-635-2025
   EMail: bob@airespace.com


   Pat R. Calhoun
   Airespace
   110 Nortech Parkway
   San Jose, CA  95134

   Phone: +1 408-635-2000
   EMail: pcalhoun@airespace.com


   James Kempf
   Docomo Labs USA
   181 Metro Drive, Suite 300
   San Jose, CA  95110

   Phone: +1 408 451 4711
   EMail: kempf@docomolabs-usa.com









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RFC 3990                CAPWAP Problem Statement           February 2005


Full Copyright Statement

   Copyright (C) The Internet Society (2005).

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

   This document and the information contained herein are provided on an
   "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
   OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET
   ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED,
   INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE
   INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
   WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.

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Acknowledgement

   Funding for the RFC Editor function is currently provided by the
   Internet Society.






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