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Framework for Emergency Calling Using Internet Multimedia
draft-ietf-ecrit-framework-13

The information below is for an old version of the document that is already published as an RFC.
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This is an older version of an Internet-Draft that was ultimately published as RFC 6443.
Authors Brian Rosen , James Polk , Andy Newton , Henning Schulzrinne
Last updated 2015-10-14 (Latest revision 2011-09-07)
Replaces draft-rosen-ecrit-framework
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draft-ietf-ecrit-framework-13
ecrit                                                           B. Rosen
Internet-Draft                                                   NeuStar
Intended status: Informational                            H. Schulzrinne
Expires: March 11, 2012                                      Columbia U.
                                                                 J. Polk
                                                           Cisco Systems
                                                               A. Newton
                                                      TranTech/MediaSolv
                                                       September 8, 2011

       Framework for Emergency Calling using Internet Multimedia
                     draft-ietf-ecrit-framework-13

Abstract

   The IETF has standardized various aspects of placing emergency calls.
   This document describes how all of those component parts are used to
   support emergency calls from citizens and visitors to authorities.

Status of this Memo

   This Internet-Draft is submitted in full conformance with the
   provisions of BCP 78 and BCP 79.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF).  Note that other groups may also distribute
   working documents as Internet-Drafts.  The list of current Internet-
   Drafts is at http://datatracker.ietf.org/drafts/current/.

   Internet-Drafts are draft documents valid for a maximum of six months
   and may be updated, replaced, or obsoleted by other documents at any
   time.  It is inappropriate to use Internet-Drafts as reference
   material or to cite them other than as "work in progress."

   This Internet-Draft will expire on March 11, 2012.

Copyright Notice

   Copyright (c) 2011 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must

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   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

Table of Contents

   1.  Terminology  . . . . . . . . . . . . . . . . . . . . . . . . .  3
   2.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  4
   3.  Overview of how emergency calls are placed . . . . . . . . . .  7
   4.  Which devices and services should support emergency calls  . . 11
   5.  Identifying an emergency call  . . . . . . . . . . . . . . . . 12
   6.  Location and its role in an emergency call . . . . . . . . . . 13
     6.1.  Types of location information  . . . . . . . . . . . . . . 15
     6.2.  Location determination . . . . . . . . . . . . . . . . . . 16
       6.2.1.  User-entered location information  . . . . . . . . . . 17
       6.2.2.  Access network "wire database" location information  . 18
       6.2.3.  End-system measured location information . . . . . . . 18
       6.2.4.  Network measured location information  . . . . . . . . 19
     6.3.  Who adds location, endpoint or proxy . . . . . . . . . . . 19
     6.4.  Location and references to location  . . . . . . . . . . . 20
     6.5.  End system location configuration  . . . . . . . . . . . . 20
     6.6.  When location should be configured . . . . . . . . . . . . 22
     6.7.  Conveying location . . . . . . . . . . . . . . . . . . . . 23
     6.8.  Location updates . . . . . . . . . . . . . . . . . . . . . 23
     6.9.  Multiple locations . . . . . . . . . . . . . . . . . . . . 23
     6.10. Location validation  . . . . . . . . . . . . . . . . . . . 24
     6.11. Default location . . . . . . . . . . . . . . . . . . . . . 25
     6.12. Location format conversion . . . . . . . . . . . . . . . . 26
   7.  LIS and LoST discovery . . . . . . . . . . . . . . . . . . . . 26
   8.  Routing the call to the PSAP . . . . . . . . . . . . . . . . . 26
   9.  Signaling of emergency calls . . . . . . . . . . . . . . . . . 28
     9.1.  Use of TLS . . . . . . . . . . . . . . . . . . . . . . . . 28
     9.2.  SIP signaling requirements for User Agents . . . . . . . . 29
     9.3.  SIP signaling requirements for proxy servers . . . . . . . 29
   10. Call backs . . . . . . . . . . . . . . . . . . . . . . . . . . 29
   11. Mid-call behavior  . . . . . . . . . . . . . . . . . . . . . . 30
   12. Call termination . . . . . . . . . . . . . . . . . . . . . . . 30
   13. Disabling of features  . . . . . . . . . . . . . . . . . . . . 31
   14. Media  . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
   15. Testing  . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
   16. Security Considerations  . . . . . . . . . . . . . . . . . . . 32
   17. IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 32
   18. Acknowledgments  . . . . . . . . . . . . . . . . . . . . . . . 32
   19. Informative References . . . . . . . . . . . . . . . . . . . . 33
   Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 36

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1.  Terminology

   This document uses terms from [RFC3261], [RFC5222] and [RFC5012].  In
   addition the following terms are used:
   Access network:  The access network supplies IP packet service to an
      endpoint.  Examples of access networks include digital subscriber
      lines (DSL), cable modems, IEEE 802.11, WiMaX, enterprise local
      area networks and cellular data networks.
   Confidence:  Confidence is an estimate indicating how sure the
      measuring system is that the actual location of the endpoint is
      within the bounds defined by the uncertainty value, expressed as a
      percentage.  For example, a value of 90% indicates that the actual
      location is within the uncertainty nine times out of ten.
   Dispatch Location:  The dispatch location is the location used for
      dispatching responders to the person in need of assistance.  The
      dispatch location must be sufficiently precise to easily locate
      the caller; it typically needs to be more accurate than the
      routing location.
   Location configuration:  During location configuration, an endpoint
      learns its physical location.
   Location Configuration Protocol (LCP):  A protocol used by an
      endpoint to learn its location.
   Location conveyance:  Location conveyance delivers location
      information to another element.
   Location determination:  Location determination finds where an
      endpoint is physically located.  For example, the endpoint may
      contain a Global Navigation Satellite System (GNSS) receiver used
      to measure its own location or the location may be determined by a
      network administrator using a wiremap database.
   Location Information Server (LIS):  A Location Information Server
      stores location information for retrieval by an authorized entity.
   Mobile device:  A mobile device is a user agent that may change its
      physical location and possibly its network attachment point during
      an emergency call.
   NENA (National Emergency Number Association):  The National Emergency
      Number Association is an organization of professionals to "foster
      the technological advancement, availability and implementation of
      a universal emergency telephone number system in North America."
      It develops emergency calling specifications and procedures.
   Nomadic device (user):  A nomadic user agent is connected to the
      network temporarily, for relatively short durations, but does not
      move significantly during the during the emergency call.  Examples
      include a laptop using an IEEE 802.11 hotspot or a desk IP phone
      that is moved occasionally from one cubicle to another.

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   Physical location:  A physical location describes where a person or
      device is located in physical space, described by a coordinate
      system.  It is distinguished from the network location, described
      by a network address.
   PSAP:  Public Safety Answering Point, the call center that answers
      emergency calls.
   Routing Location:  The routing location of a device is used for
      routing an emergency call and may not be as precise as the
      Dispatch Location.
   Stationary device:  An stationary device is not mobile and is
      connected to the network at a fixed, long-term-stable physical
      location.  Examples include home PCs or pay phones.
   Uncertainty:  Uncertainty is an estimate, expressed in a unit of
      length, indicating the diameter of a circle that contains the
      endpoint with the probability indicated by the confidence value.

2.  Introduction

   Requesting help in an emergency using a communications device such as
   a telephone or mobile phone is an accepted practice in many parts of
   the world.  As communications devices increasingly utilize the
   Internet to interconnect and communicate, users will expect to use
   such devices to request help.  This document describes establishment
   of a communications session by a user to a "Public Safety Answering
   Point" (PSAP), that is, a call center established by response
   agencies to accept emergency calls.  Such citizen/
   visitor-to-authority calls can be distinguished from those that are
   created by responders (authority-to-authority) using public
   communications infrastructure often involving some kind of priority
   access as defined in Emergency Telecommunications Service (ETS) in IP
   Telephony [RFC4190].  They also can be distinguished from emergency
   warning systems that are authority-to-citizen.

   Supporting emergency calling requires cooperation by a number of
   elements, their vendors and service providers.  This document
   discusses how end device and applications create emergency calls, how
   access networks supply location for some of these devices, how
   service providers assist the establishment and routing, and how PSAPs
   receive calls from the Internet.

   The emergency response community will have to upgrade their
   facilities to support a wider range of communications services, but
   cannot be expected to handle wide variations in device and service
   capability.  New devices and services are being made available that
   could be used to make a request for help that are not traditional
   telephones, and users are increasingly expecting to use them to place
   emergency calls.  However, many of the technical advantages of

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   Internet multimedia require re-thinking of the traditional emergency
   calling architecture.  This challenge also offers an opportunity to
   improve the operation of emergency calling technology, while
   potentially lowering its cost and complexity.

   It is beyond the scope of this document to enumerate and discuss all
   the differences between traditional (Public Switched Telephone
   Network) and IP-based telephony, but calling on the Internet is
   characterized by:
   o  the interleaving over the same infrastructure of a wider variety
      of services;
   o  the separation of the access provider from the application
      provider;
   o  media other than voice (for example, video and text in several
      forms);
   o  the potential mobility of all end systems, including endpoints
      nominally thought of as fixed systems and not just those using
      radio access technology.  For example, consider a wired phone
      connected to a router using a mobile data network such as EV-DO as
      an uplink.

   This document focuses on how devices using the Internet can place
   emergency calls and how PSAPs can handle Internet multimedia
   emergency calls natively, rather than describing how circuit-switched
   PSAPs can handle VoIP calls.  In many cases, PSAPs making the
   transition from circuit-switched interfaces to packet-switched
   interfaces may be able to use some of the mechanisms described here,
   in combination with gateways that translate packet-switched calls
   into legacy interfaces, e.g., to continue to be able to use existing
   call taker equipment.  There are many legacy telephone networks that
   will persist long after most systems have been upgraded to IP
   origination and termination of emergency calls.  Many of these legacy
   systems route calls based on telephone numbers.  Gateways and
   conversions between existing systems and newer systems defined by
   this document will be required.  Since existing systems are governed
   primarily by local government regulations and national standards, the
   gateway and conversion details will be governed by national standards
   and thus are out of scope for this document.

   Existing emergency call systems are organized locally or nationally;
   there are currently few international standards.  However, the
   Internet crosses national boundaries, and thus Internet standards are
   required.  To further complicate matters, VoIP endpoints can be
   connected through tunneling mechanisms such as virtual private
   networks (VPNs).  Tunnels can obscure the identity of the actual
   access network that knows the location.  This significantly
   complicates emergency calling, because the location of the caller and
   the first element that routes emergency calls can be on different

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   continents, with different conventions and processes for handling of
   emergency calls.

   The IETF has historically not created national variants of its
   standards.  Thus, this document attempts to take into account best
   practices that have evolved for circuit switched PSAPs, but makes no
   assumptions on particular operating practices currently in use,
   numbering schemes or organizational structures.

   This document discusses the use of the Session Initiation Protocol
   (SIP) [RFC3261] by PSAPs and calling parties.  While other inter-
   domain call signaling protocols may be used for emergency calling,
   SIP is ubiquitous and possesses the proper support of this use case.
   Only protocols such as H.323, XMPP/Jingle, ISUP and SIP are suitable
   for inter-domain communications, ruling out Media Gateway Controller
   protocols such as MGCP or H.248/Megaco.  The latter protocols can be
   used by the enterprise or carrier placing the call, but any such call
   would reach the PSAP through a media gateway controller, similar to
   how inter-domain VoIP calls would be placed.  Other signaling
   protocols may also use protocol translation to communicate with a
   SIP-enabled PSAP. p2psip is not considered in this document.

   Existing emergency services rely exclusively on voice and
   conventional text telephony ("TTY") media streams.  However, more
   choices of media offer additional ways to communicate and evaluate
   the situation as well as to assist callers and call takers in
   handling emergency calls.  For example, instant messaging and video
   could improve the ability to communicate and evaluate the situation
   and to provide appropriate instruction prior to arrival of emergency
   crews.  Thus, the architecture described here supports the creation
   of sessions of any media type, negotiated between the caller and PSAP
   using existing SIP protocol mechanisms [RFC3264].

   This document focuses on the case in which all three steps in the
   emergency calling process -- location configuration, call routing,
   and call placement - can be and are performed by the calling
   endpoint, with the endpoint's Access Service Provider supporting the
   process by providing location information.  Calls in this case may be
   routed via an application-layer Communications Service Provider
   (e.g., a Voice Service Provider), but need not be.  The underlying
   protocols can also be used to support other models in which parts of
   the process are delegated to the Communications Service Provider.
   This document does not address in detail either these models or
   interoperability issues between them and the model described here.

   Since this document is a framework document, it does not include
   normative behavior.  A companion document, [I-D.ietf-ecrit-phonebcp],
   describes Best Current Practice for this subject and contains

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   normative language for devices, access and calling network elements.

   Supporting emergency calling does not require any specialized SIP
   header fields, request methods, status codes, message bodies, or
   event packages, but does require that existing mechanisms be used in
   certain specific ways, as described below.  User Agents (UAs) unaware
   of the recommendations in this draft may be able to place emergency
   calls, but functionality may be impaired.  For example, if the UA
   does not implement the location mechanisms described, an emergency
   call may not be routed to the correct PSAP, and if the caller is
   unable to supply his exact location, dispatch of emergency responders
   may be delayed.  Suggested behavior for both endpoints and servers is
   provided.

   From the point of view of the PSAP, three essential elements
   characterize an emergency call:
   o  The call is routed to the most appropriate PSAP, based primarily
      on the location of the caller.
   o  The PSAP must be able to automatically obtain the location of the
      caller with sufficient accuracy to dispatch a responder to help
      the caller.
   o  The PSAP must be able to re-establish a session to the caller if
      for any reason the original session is disrupted.

3.  Overview of how emergency calls are placed

   An emergency call can be distinguished (Section 5) from any other
   call by a unique Service URN [RFC5031] that is placed in the call
   set-up signaling when a home or visited emergency dial string is
   detected.  Because emergency services are local to specific
   geographic regions, a caller obtains his location (Section 6) prior
   to making emergency calls.  To get this location, either a form of
   measuring, for example, GNSS (Section 6.2.3) is deployed, or the
   endpoint is configured (Section 6.5) with its location from the
   access network's Location Information Server (LIS) using a Location
   Configuration Protocol (LCP).  The location is conveyed (Section 6.7)
   in the SIP signaling with the call.  The call is routed (Section 8)
   based on location using the LoST protocol [RFC5222], which maps a
   location to a set of PSAP URIs.  Each URI resolves to a PSAP or an
   Emergency Services Routing Proxy (ESRP) that serves as an incoming
   proxy for a group of PSAPs.  The call arrives at the PSAP with the
   location included in the INVITE request.

   The following is a quick overview for a typical Ethernet connected
   telephone using SIP signaling.  It illustrates one set of choices for
   various options presented later in this document.

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   o  The phone "boots" and connects to its access network.
   o  The phone gets location via a Location Configuration Protocol
      (LCP), for example from the DHCP server in civic [RFC4776] and/or
      geo [RFC6225] forms, a HELD server [RFC5985] or the first level
      switch's LLDP server [LLDP].
   o  The phone obtains the local emergency dial string(s) from the LoST
      [RFC5222] server for its current location.  It also receives and
      caches the PSAP URI obtained from the LoST server.
   o  Some time later, the user places an emergency call.  The phone
      recognizes an emergency call from the dial strings and uses the
      "urn:service:sos" [RFC5031] URN to mark an emergency call.
   o  It refreshes its location via DHCP and updates the PSAP's URI by
      querying the LoST mapping server with its location.
   o  It puts its location in the SIP INVITE request in a Geolocation
      header [I-D.ietf-sip-location-conveyance] and forwards the call
      using its normal outbound call processing, which commonly involves
      an outbound proxy.
   o  The proxy recognizes the call as an emergency call and routes the
      call using normal SIP routing mechanisms to the URI specified.
   o  The call routing commonly traverses an incoming proxy server
      (ESRP) in the emergency services network.  That proxy would route
      the call to the PSAP.
   o  The call is established with the PSAP and mutually agreed upon
      media streams are created.
   o  The location of the caller is displayed to the call taker.

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          Configuration Servers
    . . . . . . . . . . . . . . . . .
    .                               .
    .   +--------+    +----------+  .
    . +--------+ |  +----------+ |  .
    . | LIS    | |  | SIP      | |  .
    . |        |-+  | Registrar|-+  .
    . +--------+    +----------+    .
    .   ^               ^           .
    . . | . . . . . . . | . . . . . .
        |               |
        |[M1][M4]       |[M2]
        |               |         +--------+
        |+--------------+       +--------+ |
        ||                      | LoST   | |
        ||+-------------------->| Servers|-+
        |||        [M3][M5]     +--------+       +-------+
        |||                                      | PSAP2 |
        |||                                      +-------+
        |||
        |||  [M6]  +-------+ [M7]+------+ [M8]+-------+
      Alice ------>| Proxy |---->| ESRP |---->| PSAP1 |-----> Call-Taker
                   +-------+     +------+     +-------+

                                                 +-------+
                                                 | PSAP3 |
                                                 +-------+

                Figure 1: Emergency Call Component Topology

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  The typical message flow for this example using Alice as the caller:
  [M1] Alice -> LIS:  LCP Request(s) (ask for location)
       LIS -> Alice:  LCP Reply(s) (replies with location)
  [M2] Alice -> Registrar: SIP REGISTER
       Registrar -> Alice: SIP 200 OK (REGISTER)
  [M3] Alice -> LoST Server: Initial LoST Query (contains location)
       Lost Server -> Alice: Initial LoST Response (contains
                         PSAP-URI and dial string)

  Some time later, Alice dials or otherwise initiates an emergency call:

  [M4] Alice -> LIS:  LCP Request (update location)
       LIS -> Alice:  LCP Reply (replies with location)
  [M5] Alice -> LoST Server: Update LoST Query (contains location)
       Lost Server -> Alice: LoST Response (contains PSAP-URI)
  [M6] Alice -> Outgoing Proxy: SIP INVITE (service URN,
                                       Location and PSAP URI)
  [M7] Outgoing Proxy -> ESRP: SIP INVITE (service URN,
                                       Location and PSAP URI)
  [M8] ESRP -> PSAP: SIP INVITE (service URN, Location and PSAP URI)

  The 200 OK response is propagated back from the PSAP to Alice and the
  ACK response is propagated from Alice to the PSAP.

                          Figure 2: Message Flow

   Figure 1 shows emergency call component topology and the text above
   shows call establishment.  These include the following components:
   o  Alice - who places the emergency call.
   o  Configuration Servers - Servers providing Alice's UA its IP
      address and other configuration information, perhaps including
      location by-value or by-reference.  Configuration servers also may
      include a SIP registrar for Alice's UA.  Most SIP UAs will
      register, so it will be a common scenario for UAs that make
      emergency calls to be registered with such a server in the
      originating calling network.  Registration would be required for
      the PSAP to be able to call back after an emergency call is
      completed.  All the configuration messages are labeled M1 through
      M3, but could easily require more than 3 messages to complete.
   o  LoST server - Processes the LoST request for location plus a
      Service URN to a PSAP-URI, either for an initial request from a
      UA, or an in-call routing by the proxy server in the originating
      network, or possibly by an ESRP.
   o  ESRP - Emergency Services Routing Proxy, a SIP proxy server that
      is the incoming call proxy in the emergency services domain.  The
      ESRP makes further routing decisions (e.g., based on PSAP state
      and the location of the caller) to choose the actual PSAP that
      handles the call.  In some jurisdictions, this may involve another

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      LoST query.
   o  PSAP - Emergency calls are answered at a Public Safety Answering
      Point, a call center.

   Generally, Alice's UA either has location configured manually, has an
   integral location measurement mechanism, or it runs a LCP [M1] to
   obtain location from the access (broadband) network.  Alice's UA then
   will most likely register [M2] with a SIP registrar.  This allows her
   to be contacted by other SIP entities.  Next, her UA will perform an
   initial LoST query [M3] to learn a URI for use if the LoST query
   fails during an emergency call, or to use to test the emergency call
   mechanism.  The LoST response contains the dial string for emergency
   calls appropriate for the location provided.

   At some time after her device has booted, Alice initiates an
   emergency call.  She may do this by dialing an emergency dial string
   valid for her current ("local") location, or for her "home" location.

   The UA recognizes the dial string.  The UA attempts to refresh its
   location [M4], and with that location, to refresh the LoST mapping
   [M5], in order to get the most accurate information to use for
   routing the call.  If the location request or the LoST request fails,
   or takes too long, the UA uses values it has cached.

   The UA creates a SIP INVITE [M6] request that includes the location.
   [I-D.ietf-sip-location-conveyance] defines a SIP Geolocation header
   that contains either a location-by-reference URI or a [RFC3986] "cid"
   URL indicating where in the message body the location-by-value is.

   The INVITE message is routed to the ESRP [M7], which is the first
   inbound proxy for the emergency services domain.  This message is
   then routed by the ESRP towards the most appropriate PSAP for Alice's
   location [M8], as determined by the location and other information.

   A proxy in the PSAP chooses an available call taker and extends the
   call to its UA.

   The 200 OK response to the INVITE request traverses the path in
   reverse, from call taker UA to PSAP proxy to ESRP to originating
   network proxy to Alice's UA.  The ACK request completes the call
   set-up and the emergency call is established, allowing the PSAP call-
   taker to talk to Alice about Alice's emergency.

4.  Which devices and services should support emergency calls

   Current PSAPs support voice calls and real-time text calls placed
   through PSTN facilities or systems connected to the PSTN.  Future

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   PSAPs will however support Internet connectivity and a wider range of
   media types and provide higher functionality.  In general, if a user
   could reasonably expect to be able to place a call for help with the
   device, then the device or service should support emergency calling.
   Certainly, any device or service that looks like and works like a
   telephone (wired or mobile) should support emergency calling, but
   increasingly, users have expectations that other devices and services
   should work.

   Devices that create media sessions and exchange audio, video and/or
   text, and have the capability to establish sessions to a wide variety
   of addresses, and communicate over private IP networks or the
   Internet, should support emergency calls.

   Traditionally, enterprise support of emergency calling is provided by
   the telephony service provider to the enterprise.  In some more
   recent systems, the enterprise PBX assists emergency calling by
   providing more fine grained location in larger enterprises.  In the
   future, the enterprise may provide the connection to emergency
   services itself, not relying on the telephony service provider.

5.  Identifying an emergency call

   Using the PSTN, emergency help can often be summoned by dialing a
   nationally designated, widely known number, regardless of where the
   telephone was purchased.  The appropriate number is determined by the
   infrastructure the telephone is connected to.  However, this number
   differs between localities, even though it is often the same for a
   country or region, as it is in many countries in the European Union.
   In some countries, there is only one uniform digit sequence that is
   used for all types of emergencies.  In others, there are several
   sequences that are specific to the type of responder needed, e.g.,
   one for police, another for fire.  For end systems, on the other
   hand, it is desirable to have a universal identifier, independent of
   location, to allow the automated inclusion of location information
   and to allow the device and other entities in the call path to
   perform appropriate processing within the signaling protocol in an
   emergency call set-up.

   Since there is no such universal identifier, as part of the overall
   emergency calling architecture, common emergency call URNs are
   defined in [RFC5031].  For a single number environment the urn is
   "urn:service:sos".  Users are not expected to "dial" an emergency
   URN.  Rather, appropriate emergency dial strings are translated to
   corresponding service URNs, carried in the Request-URI of the INVITE
   request.  Such translation is best done by the endpoint, because,
   among other reasons, emergency calls convey location in the

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   signaling, but non-emergency calls do not normally do that.  If the
   device recognizes the emergency call, it can include location.  A
   signaling intermediary (proxy server) can also recognize emergency
   dial strings if the endpoint fails to do so.

   For devices that are mobile or nomadic, an issue arises of whether
   the home or visited dial strings should be used.  Many users would
   prefer that their home dialing sequences work no matter where they
   are.  However, local laws and regulations may require that the
   visited dialing sequence(s) work.  Therefore, the visited dial string
   must work.  Devices may have a way to be configured or learn home
   dial strings.

   LoST [RFC5222] provides the mechanism for obtaining the dialing
   sequences for a given location.  LoST servers must return dial
   strings for emergency services.  If the endpoint does not support the
   translation of dial strings to service URNs, the dialing sequence
   from the endpoint to its proxy is represented as a dial string
   [RFC4967] and the outgoing proxy must recognize the dial string and
   translate it to the equivalent service URN.  To determine the local
   emergency dial string, the proxy needs the location of the endpoint.
   This may be difficult in situations where the user can roam or be
   nomadic.  Endpoint recognition of emergency dial strings is therefore
   preferred.  If a service provider is unable to guarantee that it can
   correctly determine local emergency dialstrings, wherever its
   subscribers may be, then it is required that the endpoint do the
   recognition.

   Note: The emergency call practitioners consider it undesirable to
   have a single button emergency call user interface element.  These
   mechanisms tend to result in a very high rate of false or accidental
   emergency calls.  In order to minimize this issue, practitioners
   recommend that device should only initiate emergency calls based on
   entry of specific emergency call dial strings.  Speed dial mechanisms
   may effectively create single button emergency call invocation and
   practitioners recommend they not be permitted.

6.  Location and its role in an emergency call

   Location is central to the operation of emergency services.  Location
   is used for two purposes in emergency call handling: routing of the
   call and dispatch of responders.  It is frequently the case that the
   caller reporting an emergency is unable to provide a unique, valid
   location themselves.  For this reason, location provided by the
   endpoint or the access network is needed.  For practical reasons,
   each PSAP generally handles only calls for a certain geographic area,
   with overload arrangements between PSAPs to handle each others'

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   calls.  Other calls that reach it by accident must be manually re-
   routed (transferred) to the most appropriate PSAP, increasing call
   handling delay and the chance for errors.  The area covered by each
   PSAP differs by jurisdiction, where some countries have only a small
   number of PSAPs, while others decentralize PSAP responsibilities to
   the level of counties or municipalities.

   In most cases, PSAPs cover at least a city or town, but there are
   some areas where PSAP coverage areas follow old telephone rate center
   boundaries and may straddle more than one city.  Irregular boundaries
   are common, often for historical reasons.  Routing must be done based
   on actual PSAP service boundaries -- the closest PSAP, or the PSAP
   that serves the nominal city name provided in the location, may not
   be the correct PSAP.

   Accuracy of routing location is a complex subject.  Calls must be
   routed quickly, but accurately, and location determination is often a
   time/accuracy tradeoff, especially with mobile devices or self
   measuring mechanisms. if more accurate routing location is not
   available it is considered acceptable to base a routing decision on
   an accuracy equal to the area of one sector of a mobile cell site.

   Routing to the most appropriate PSAP is always based on the location
   of the caller, despite the fact that some emergency calls are placed
   on behalf of someone else, and the location of the incident is
   sometimes not the location of the caller.  In some cases, there are
   other factors that enter into the choice of the PSAP that gets the
   call, such as time of day, caller media requests and language
   preference and call load.  However, location of the caller is the
   primary input to the routing decision.

   Many mechanisms used to locate a caller have a relatively long "cold
   start" time.  To get a location accurate enough for dispatch may take
   as much as 30 seconds.  This is too long to wait for emergencies.
   Accordingly, it is common, especially in mobile systems, to use a
   coarse location, for example, the cell site and sector serving the
   call, for call routing purposes, and then to update the location when
   a more precise value is known prior to dispatch.  In this document we
   use "routing location" and "dispatch location" when the distinction
   matters.

   Accuracy of dispatch location is sometimes determined by local
   regulation, and is constrained by available technology.  The actual
   requirement is more stringent than available technology can deliver:
   It is required that a device making an emergency call close to the
   "demising" or separation wall between two apartments in a high rise
   apartment building report location with sufficient accuracy to
   determine on what side of the wall it is on.  This implies perhaps a

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   3 cm accuracy requirement.  As of the date of this memo, assisted
   GNSS uncertainty in mobile phones with 95% confidence cannot be
   relied upon to be less than hundreds of meters.  As technology
   advances, the accuracy requirements for location will need to be
   tightened.  Wired systems using wire tracing mechanisms can provide
   location to a wall jack in specific room on a floor in a building,
   and may even specify a cubicle or even smaller resolution.  As this
   discussion illustrates, emergency call systems demand the most
   stringent location accuracy available.

   In Internet emergency calling, where the endpoint is located is
   determined using a variety of measurement or wire-tracing methods.
   Endpoints may be configured with their own location by the access
   network.  In some circumstances, a proxy server may insert location
   into the signaling on behalf of the endpoint.  The location is mapped
   to the URI to send the call to, and the location is conveyed to the
   PSAP (and other elements) in the signaling.  The terms
   'determination', 'configuration', 'mapping', and 'conveyance' are
   used for specific aspects of location handling in IETF protocols.
   Likewise, we employ Location Configuration Protocols, Location
   Mapping Protocols, and Location Conveyance Protocols for these
   functions.

   This document provides guidance for generic network configurations
   with respect to location.  It is recognized that unique issues may
   exist in some network deployments.  The IETF will continue to
   investigate these unique situations and provide further guidance, if
   warranted, in future documents.

6.1.  Types of location information

   Location can be specified in several ways:
   Civic:  Civic location information describes the location of a person
      or object by a street address that corresponds to a building or
      other structure.  Civic location may include more fine grained
      location information such as floor, room and cubicle.  Civic
      information comes in two forms:
      'Jurisdictional':  refers to a civic location using actual
         political subdivisions, especially for the community name.
      'Postal':   refers to a civic location for mail delivery.  The
         name of the post office sometimes does not correspond to the
         community name and a postal address may contain post office
         boxes or street addresses that do not correspond to an actual
         building.  Postal addresses are generally unsuitable for
         emergency call dispatch because the post office conventions
         (for community name, for example) do not match those known by
         the responders.  The fact that they are unique can sometimes be
         exploited to provide a mapping between a postal address and a

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         civic address suitable to dispatch a responder to.  In IETF
         location protocols, there is an element (Postal Community Name)
         that can be included in a location to provide the post office
         name as well as the actual jurisdictional community name.
         There is also an element for a postal code.  There is no other
         accommodation for postal addresses in these protocols.
   Geospatial (geo):  Geospatial addresses contain longitude, latitude
      and altitude information based on an understood datum and earth
      shape model (datum).  While there have been many datums developed
      over time, most modern systems are using or moving towards the
      WGS84 [WGS84] datum.
   Cell tower/sector:  Cell tower/sector is often used for identifying
      the location of a mobile handset, especially for routing of
      emergency calls.  Cell tower and sectors identify the cell tower
      and the antenna sector that a mobile device is currently using.
      Traditionally, the tower location is represented as a point chosen
      to be within a certain PSAP service boundary who agrees to take
      calls originating from that tower/sector, and routing decisions
      are made on that point.  Cell/sector information could also be
      represented as an irregularly shaped polygon of geospatial
      coordinates reflecting the likely geospatial location of the
      mobile device.  Whatever representation is used must route
      correctly in the LoST database, where "correct" is determined by
      local PSAP management.

   In IETF protocols, both civic and geospatial forms are supported.
   The civic forms include both postal and jurisdictional fields.  A
   cell tower/sector can be represented as a geo point or polygon or
   civic location.  Other forms of location representation must be
   mapped into either a geo or civic for use in emergency calls.

   For emergency call purposes, conversion of location information from
   civic to geo or vice versa prior to conveyance is not desirable.  The
   location should be sent in the form it was determined.  Conversion
   between geo and civic requires a database.  Where PSAPs need to
   convert from whatever form they receive to another for responder
   purposes, they have a suitable database.  However, if a conversion is
   done before the PSAP's, and the database used is not exactly the same
   one the PSAP uses, the double conversion has a high probability of
   introducing an error.

6.2.  Location determination

   As noted above, location information can be entered by the user or
   installer of a device ("manual configuration"), measured by the end
   system, can be delivered to the end system by some protocol or
   measured by a third party and inserted into the call signaling.

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   In some cases, an entity may have multiple sources of location
   information, possibly partially contradictory.  This is particularly
   likely if the location information is determined both by the end
   system and a third party.  Although self measured location (e.g.,
   GNSS) is attractive, location information provided by the access
   network could be much more accurate, and more reliable in some
   environments such as high rise buildings in dense urban areas.

   The closer an entity is to the source of location, the more likely it
   is able to determine which location is most appropriate for a
   particular purpose when there are more than one location
   determinations for a given endpoint.  In emergency calling, the PSAP
   is the least likely to be able to appropriately choose which location
   to use when multiple conflicting locations are presented to it.
   While all available locations can be sent towards the PSAP, the order
   of the locations should be the sender's best attempt to guide the
   recipient of which one(s) to use.

6.2.1.  User-entered location information

   Location information can be maintained by the end user or the
   installer of an endpoint in the endpoint itself, or in a database.

   Location information routinely provided by end users is almost always
   less reliable than measured or wire database information, as users
   may mistype location information or may enter civic address
   information that does not correspond to a recognized (i.e., valid,
   see Section Section 6.10) address.  Users can forget to change the
   data when the location of a device changes.

   However, there are always a small number of cases where the automated
   mechanisms used by the access network to determine location fail to
   accurately reflect the actual location of the endpoint.  For example,
   the user may deploy his own WAN behind an access network, effectively
   removing an endpoint some distance from the access network's notion
   of its location.  To handle these exceptional cases, there must be
   some mechanism provided to manually provision a location for an
   endpoint by the user or by the access network on behalf of a user.
   The use of the mechanism introduces the possibility of users falsely
   declaring themselves to be somewhere they are not.  However, this is
   generally not a problem in practice.  Commonly, if an emergency
   caller insists that he is at a location different from what any
   automatic location determination system reports he is, responders
   will always be sent to the user's self-declared location.

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6.2.2.  Access network "wire database" location information

   Location information can be maintained by the access network,
   relating some form of identifier for the end subscriber or device to
   a location database ("wire database").  In enterprise LANs, wiremap
   databases map Ethernet switch ports to building locations.  In DSL
   installations, the local telephone carrier maintains a mapping of
   wire-pairs to subscriber addresses.

   Accuracy of location historically has been to a street address level.
   However, this is not sufficient for larger structures.  The PIDF
   Location Object [RFC4119] extended by [RFC5139] and [RFC5491] permits
   interior building/floor/room and even finer specification of location
   within a street address.  When possible, interior location should be
   supported.

   The threshold for when interior location is needed is approximately
   650 square meters.  This value is derived from USA fire brigade
   recommendations of spacing of alarm pull stations.  However, interior
   space layout, construction materials and other factors should be
   considered.

   Even for IEEE 802.11 wireless access points, wire databases may
   provide sufficient location resolution.  The location of the access
   point as determined by the wiremap may be supplied as the location
   for each of the clients of the access point.  However, this may not
   be true for larger-scale systems such as IEEE 802.16 (WiMAX) and IEEE
   802.22 that typically have larger cells than those of IEEE 802.11.
   The civic location of an IEEE 802.16 base station may be of little
   use to emergency personnel, since the endpoint could be several
   kilometers away from the base station.

   Wire databases are likely to be the most promising solution for
   residential users where a service provider knows the customer's
   service address.  The service provider can then perform address
   validation (see Section 6.10), similar to the current system in some
   jurisdictions.

6.2.3.  End-system measured location information

   Global Positioning System (GPS) and similar Global Navigation
   Satellite Systems (e.g., GLONAS and Galileo) receivers may be
   embedded directly in the end device.  GNSS produces relatively high
   precision location fixes in open-sky conditions, but the technology
   still faces several challenges in terms of performance (time-to-fix
   and time-to-first-fix), as well as obtaining successful location
   fixes within shielded structures, or underground.  It also requires
   all devices to be equipped with the appropriate GNSS capability.

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   Many mobile devices require using some kind of "assist", that may be
   operated by the access network (A-GPS) or by a government (WAAS).  A
   device may be able to use multiple sources of assist data.

   GNSS systems may be always enabled and thus location will always be
   available accurately immediately (assuming the device can "see"
   enough satellites).  Mobile devices may not be able to sustain the
   power levels required to keep the measuring system active.  In such
   circumstances, when location is needed, the device has to start up
   the measurement mechanism.  This typically takes tens of seconds, far
   too long to wait to be able to route an emergency call.  For this
   reason, devices that have end-system measured location mechanisms but
   need a cold start period lasting more than a couple seconds need
   another way to get a routing location.  Typically this would be a
   location associated with a radio link (cell site/sector).

6.2.4.  Network measured location information

   The access network may locate end devices.  Techniques various forms
   of triangulation.  Elements in the network infrastructure triangulate
   end systems based on signal strength, angle of arrival or time of
   arrival.  Common mechanisms deployed include:
   o  Time Difference Of Arrival - TDOA
   o  Uplink Time Difference Of Arrival - U-TDOA
   o  Angle of Arrival - AOA
   o  RF fingerprinting
   o  Advanced Forward Link Trilateration - AFLT
   o  Enhanced Forward Link Trilateration - EFLT
   Sometimes multiple mechanisms are combined, for example A-GPS with
   AFLT.

6.3.  Who adds location, endpoint or proxy

   The IETF emergency call architecture prefers endpoints to learn their
   location and supply it on the call.  Where devices do not support
   location, proxy servers may have to add location to emergency calls.
   Some calling networks have relationships with all access networks the
   device may be connected to, and that may allow the proxy to
   accurately determine the location of the endpoint.  However, NATs and
   other middleboxes often make it impossible to determine a reference
   identifier the access network could provide to a LIS to determine the
   location of the device.  Systems designers are discouraged from
   relying on proxies to add location.  The technique may be useful in
   some limited circumstances as devices are upgraded to meet the
   requirements of this document, or where relationships between access
   networks and calling networks are feasible and can be relied upon to
   get accurate location.

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   Proxy insertion of location complicates dial string recognition.  As
   noted in Section 6, local dial strings depend on the location of the
   caller.  If the device does not know its own location, it cannot use
   the LoST service to learn the local emergency dial strings.  The
   calling network must provide another way for the device to learn the
   local dial string, and update it when the user moves to a location
   where the dial string(s) change, or do the dial string determination
   itself.

6.4.  Location and references to location

   Location information may be expressed as the actual civic or
   geospatial value but can be transmitted as by value (wholly contained
   within the signaling message) or by reference (i.e., as a URI
   pointing to the value residing on a remote node waiting to be
   dereferenced).

   When location is transmitted by value, the location information is
   available to entity in the call path.  On the other hand, location
   objects can be large, and only represent a single snapshot of the
   device's location.  Location references are small and can be used to
   represent a time-varying location, but the added complexity of the
   dereference step introduces a risk that location will not be
   available to parties that need it.

6.5.  End system location configuration

   Unless a user agent has access to provisioned or locally measured
   location information, it must obtain it from the access network.
   There are several location configuration protocols (LCPs) that can be
   used for this purpose including DHCP, HELD and LLDP:
   DHCP  can deliver civic [RFC4776] or geospatial [RFC6225]
      information.  User agents need to support both formats.  Note that
      a user agent can use DHCP, via the DHCP REQUEST or INFORM
      messages, even if it uses other means to acquire its IP address.
   HELD  [RFC5985] can deliver a civic or geo location object, by value
      or by reference, via a layer 7 protocol.  The query typically uses
      the IP address of the requester as an identifier and returns the
      location value or reference associated with that identifier.  HELD
      is typically carried in HTTP.
   Link-Layer Discovery Protocol  [LLDP] with Media Endpoint Device
      extensions [LLDP-MED] can be used to deliver location information
      directly from the Layer 2 network infrastructure, and also
      supports both civic and geo formats identical in format to DHCP
      methods.

   Each LCP has limitations in the kinds of networks that can reasonably
   support it.  For this reason, it is not possible to choose a single

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   mandatory-to-deploy LCP.  For endpoints with common network
   connections (such as an Ethernet jack or a WiFi connection) serious
   incompatibilities would ensue unless every network supported every
   protocol, or alternatively, every device supported every protocol.
   For this reason, a mandatory-to-implement list of LCPs is established
   in [I-D.ietf-ecrit-phonebcp].  Every endpoint that could be used to
   place emergency calls must implement all of the protocols on the
   list.  Every access network must deploy at least one of them.  Since
   it is the variability of the networks that prevent a single protocol
   from being acceptable, it must be the endpoints that implement all of
   them, and to accommodate a wide range of devices, networks must
   deploy at least one of them.

   Often, network operators and device designers believe that they have
   a simpler environment and some other network specific mechanism can
   be used to provide location.  Unfortunately, it is very rare to
   actually be able to limit the range of devices that may be connected
   to a network.  For example, existing mobile networks are being used
   to support routers and LANs behind a wireless data network WAN
   connection, with Ethernet connected phones connected to that.  It is
   possible that the access network could support a protocol not on the
   list, and require every handset in that network to use that protocol
   for emergency calls.  However, the Ethernet-connected phone won't be
   able to acquire location, and the user of the phone is unlikely to be
   dissuaded from placing an emergency call on that phone.  The
   widespread availability of gateways, routers and other network-
   broadening devices means that indirectly connected endpoints are
   possible on nearly every network.  Network operators and vendors are
   cautioned that shortcuts to meeting this requirement are seldom
   successful.

   Location for non-mobile devices is normally expected to be acquired
   at network attachment time and retained by the device.  It should be
   refreshed when the cached value expires.  For example, if DHCP is the
   acquisition protocol, refresh of location may occur when the IP
   address lease is renewed.  At the time of an emergency call, the
   location should be refreshed, with the retained location used if the
   location acquisition does not immediately return a value.  Mobile
   devices may determine location at network attachment time and
   periodically thereafter as a backup in case location determination at
   the time of call does not work.  Mobile device location may be
   refreshed when a TTL expires or the device moves beyond some
   boundaries (as provided by [RFC5222]).  Normally, mobile devices will
   acquire its location at call time for use in an emergency call
   routing.  See Section 6.8 for a further discussion on location
   updates for dispatch location.

   There are many examples of endpoints which are user agent

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   applications running on a more general purpose device, such as a
   personal computer.  On some systems, layer 2 protocols like DHCP and
   LLDP may not be directly accessible to applications.  It is desirable
   for an operating system to have an API which provides the location of
   the device for use by any application, especially those supporting
   emergency calls.

6.6.  When location should be configured

   Devices should get routing location immediately after obtaining local
   network configuration information.  The presence of NAT and VPN
   tunnels (that assign new IP addresses to communications) can obscure
   identifiers used by LCPs to determine location, especially for HELD.
   In some cases, such as residential NAT devices, the NAT is placed
   between the endpoint and the access network demarcation point and
   thus the IP address seen by the access network is the right
   identifier for location of the residence.  However, in many
   enterprise environments, VPN tunnels can obscure the actual IP
   address.  Some VPN mechanisms can be bypassed so that a query to the
   LCP can be designated to go through the direct IP path, using the
   correct IP address, and not through the tunnel.  In other cases, no
   bypass is possible, but location can be configured before the VPN is
   established.  Of course, LCPs that use layer 2 mechanisms (DHCP
   Location options and LLDP-MED) are usually immune from such problems
   because they do not use the IP address as the identifier for the
   device seeking location.

   It is desirable that routing location information be periodically
   refreshed.  A LIS supporting a million subscribers each refreshing
   once per day would need to support a query rate of 1,000,000 / (24 *
   60 * 60) = 12 queries per second.  For networks with mobile devices,
   much higher refresh rates could be expected.

   It is desirable for routing location information to be requested
   immediately before placing an emergency call.  However, if there is
   any significant delay in getting more recent location, the call
   should be placed with the most recent location information the device
   has.  In mobile handsets, routing is often accomplished with the cell
   site and sector of the tower serving the call, because it can take
   many seconds to start up the location determination mechanism and
   obtain an accurate location.

   There is a tradeoff between the time it takes to get a routing
   location and the accuracy (technically, confidence and uncertainty)
   obtained.  Routing an emergency call quickly is required.  However,
   if location can be substantially improved by waiting a short time
   (e.g., for some sort of "quick fix"), it's preferable to wait.  Three
   seconds, the current nominal time for a quick fix, is a very long

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   time add to post dial delay.

   NENA recommends [NENAi3TRD] that IP based systems complete calls in
   two seconds from last dial press to ring at PSAP.

6.7.  Conveying location

   When an emergency call is placed, the endpoint should include
   location in the call signaling.  This is referred to as "conveyance"
   to distinguish it from "configuration".  In SIP, the location
   information is conveyed following the procedures in
   [I-D.ietf-sip-location-conveyance].  Since the form of the location
   information obtained by the acquisition protocol may not be the same
   as the conveyance protocol uses (PIDF-LO [RFC4119]), mapping by the
   endpoint from the LCP form to PIDF may be required.

6.8.  Location updates

   As discussed above, it may take some time for some measurement
   mechanisms to get a location accurate enough for dispatch, and a
   routing location with less accuracy may be provided to get the call
   established quickly.  The PSAP needs the dispatch location before it
   sends the call to the responder.  This requires an update of the
   location.  In addition, the location of some mobile callers, e.g., in
   a vehicle or aircraft, can change significantly during the emergency
   call.

   A PSAP has no way to request an update of a location provided by
   value.  If the UAC gets new location, it must signal the PSAP using a
   new INVITE or an UPDATE transaction with a new Geolocation header to
   supply the new location.

   With the wide variation in determination mechanisms, the PSAP does
   not know when accurate location may be available.  The preferred
   mechanism is that the LIS notifies the PSAP when an accurate location
   is available rather than requiring a poll operation from the PSAP to
   the LIS.  The SIP Presence subscription [RFC3856] provides a suitable
   mechanism.

   When using a HELD dereference, the PSAP must specify the value
   "emergencyDispatch" for the ResponseTime parameter.  Since typically
   the LIS is local relative to the PSAP, the LIS can be aware of the
   update requirements of the PSAP

6.9.  Multiple locations

   Getting multiple locations all purported to describe the location of
   the caller is confusing to all, and should be avoided.  Handling

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   multiple locations at the point where a PIDF is created is discussed
   in [RFC5491].  Conflicting location information is particularly
   harmful if different routes (PSAPs) result from LoST queries for the
   multiple locations.  When they occur anyway, the general guidance is
   that the entity earliest in the chain generally has more knowledge
   than later elements to make an intelligent decision, especially about
   which location will be used for routing.  It is permissible to send
   multiple locations towards the PSAP, but the element that chooses the
   route must select exactly one location to use with LoST.

   Guidelines for dealing with multiple locations are also given in
   [RFC5222].  If a UA gets multiple locations, it must choose the one
   to use for routing, but it may send all of the locations it has in
   the signaling.  If a proxy is inserting location and has multiple
   locations, it must choose exactly one to use for routing, marking it
   as such (per [I-D.ietf-sip-location-conveyance], and send it as well
   as any others it has.

   The UA or proxy should have the ability to understand how and from
   whom it learned its location, and should include this information in
   the location objects that are sent to the PSAP.  That labeling
   provides the call-taker with information to make decisions upon, as
   well as guidance for what to ask the caller and what to tell the
   responders.

   Endpoints or proxies may be tempted to send multiple versions of the
   same location.  For example a database may be used to "geocode" or
   "reverse geocode", that is, convert from civic to geo or vice versa.
   It is very problematic to use derived locations in emergency calls.
   The PSAP and the responders have very accurate databases which they
   use to convert, most commonly from a reported geo to a civic suitable
   for dispatching responders.  If one database is used to convert from,
   say, civic to geo, and another converts from geo to civic, errors
   will often occur where the databases are slightly different.  "Off by
   one" errors are serious when responders go to the wrong location.
   Derived locations should be marked with a "derived" method token
   [RFC4119].  If an entity gets a location which has a measured or
   other original method, and another with a derived method, it must use
   the original value for the emergency call.

6.10.  Location validation

   Validation in this context means both that there is a mapping from
   the address to a PSAP and that the PSAP understands how to direct
   responders to the location.  It is recommended that location be
   validated prior to a device placing an actual emergency call; some
   jurisdictions require that this be done.

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   Determining the addresses that are valid can be difficult.  There
   are, for example, many cases of two names for the same street, or two
   streets with the same name, but different "suffixes" (Avenue, Street,
   Circle) in a city.  In some countries, the current system provides
   validation.  For example, in the United States of America, the Master
   Street Address Guide (MSAG) records all valid street addresses and is
   used to ensure that the service addresses in phone billing records
   correspond to valid emergency service street addresses.  Validation
   is normally only a concern for civic addresses, although there could
   be some determination that a given geo is within at least one PSAP
   service boundary; that is, a "valid" geo is one where there is a
   mapping in the LoST server.

   LoST [RFC5222] includes a location validation function.  Validation
   is normally performed when a location is entered into a Location
   Information Server.  It should be confirmed periodically, because the
   mapping database undergoes slow change and locations which previously
   validated may eventually fail validation.  Endpoints may wish to
   validate locations they receive from the access network, and will
   need to validate manually entered locations.  Proxies that insert
   location may wish to validate locations they receive from a LIS.
   When the test functions (Section 15) are invoked, the location used
   should be validated.

   When validation fails, the location given should not be used for an
   emergency call, unless no other valid location is available.  Bad
   location is better than no location.  If validation is completed when
   location is first loaded into a LIS, any problems can be found and
   fixed before devices could get the bad location.  Failure of
   validation arises because an error is made in determining the
   location, although occasionally the LoST database is not up to date
   or has faulty information.  In either case, the problem must be
   identified and should be corrected before using the location.

6.11.  Default location

   Occasionally, the access network cannot determine the actual location
   of the caller.  In these cases, it must supply a default location.
   The default location should be as accurate as the network can
   determine.  For example, in a cable network, a default location for
   each Cable Modem Termination System (CMTS), with a representative
   location for all cable modems served by that CMTS could be provided
   if the network is unable to resolve the subscriber to anything more
   precise than the CMTS.  Default locations must be marked as such so
   that the PSAP knows that the location is not accurate.

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6.12.  Location format conversion

   The endpoint is responsible for mapping any form of location it
   receives from an LCP into PIDF-LO form if the LCP did not directly
   return a PIDF-LO.

7.  LIS and LoST discovery

   Endpoints must be able to discover a LIS if the HELD protocol is
   used, and a LoST server.  DHCP options are defined for this purpose,
   namely [RFC5986] and [RFC5223].

   Until such DHCP records are widely available, it may be necessary for
   the service provider to provision a LoST server address in the
   device.  The endpoint can also do a DNS SRV query to find a LoST
   server.  In any environment, more than one of these mechanisms may
   yield a LoST server, and they may be different.  The recommended
   priority is DHCP first, provisioned value second, and DNS SRV query
   in the SIP domain third.

8.  Routing the call to the PSAP

   Emergency calls are routed based on one or more of the following
   criteria expressed in the call setup request (INVITE):
   Location:  Since each PSAP serves a limited geographic region and
      transferring existing calls delays the emergency response, calls
      need to be routed to the most appropriate PSAP.  In this
      architecture, emergency call setup requests contain location
      information, expressed in civic or geospatial coordinates, that
      allows such routing.
   Type of emergency service:  In some jurisdictions, emergency calls
      for specific emergency services such as fire, police, ambulance or
      mountain rescue are directed to just those emergency-specific
      PSAPs.  This mechanism is supported by marking emergency calls
      with the proper service identifier [RFC5031].  Even in single
      number jurisdictions, not all services are dispatched by PSAPs and
      may need alternate URNs to route calls to the appropriate call
      center.
   Media capabilities of caller:  In some cases, emergency call centers
      for specific caller media preferences, such as typed text or
      video, are separate from PSAPs serving voice calls.  ESRPs are
      expected to be able to provide routing based on media.  Also, even
      if media capability does not affect the selection of the PSAP,
      there may be call takers within the PSAP that are specifically
      trained, e.g., in interactive text or sign language
      communications, where routing within the PSAP based on the media

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      offer would be provided.

   Providing a URL to route emergency calls by location and by type of
   service is the primary function LoST [RFC5222] provides.  LoST
   accepts a query with location (by-value) in either civic or geo form,
   plus a service identifier, and returns a URI (or set of URIs) to
   route the call to.  Normal SIP [RFC3261] routing functions are used
   to resolve the URI to a next hop destination.

   The endpoint can complete the LoST mapping from its location at boot
   time, and periodically thereafter.  It should attempt to obtain a
   "fresh" location, and from that a current mapping when it places an
   emergency call.  If accessing either its location acquisition or
   mapping functions fail, it should use its cached value.  The call
   would follow its normal outbound call processing.

   Determining when the device leaves the area provided by the LoST
   service can tax small mobile devices.  For this reason, the LoST
   server should return a simple (small number of points) polygon for
   geospatial location.  This can be a simple enclosing rectangle of the
   PSAP service area when the reported point is not near an edge, or a
   smaller polygonal edge section when the reported location is near an
   edge.  Civic location is uncommon for mobile devices, but reporting
   that the same mapping is good within a community name, or even a
   street, may be very helpful for WiFi connected devices that roam and
   obtain civic location from the access point they are connected to.

   Networks that support devices that do not implement LoST mapping
   themselves may need the outbound proxy do the mapping.  If the
   endpoint recognized the call was an emergency call, provided the
   correct service URN and/or included location on the call in a
   Geolocation header, a proxy server could easily accomplish the
   mapping.

   However, if the endpoint did not recognize the call was an emergency
   call, and thus did not include location, the proxy's task is more
   difficult.  It is often difficult for the calling network to
   accurately determine the endpoint's location.  The endpoint may have
   its own location, but would not normally include it on the call
   signaling unless it knew it was an emergency call.  There is no
   mechanism provided in [I-D.ietf-sip-location-conveyance] for a proxy
   to request the endpoint supply its location, because that would open
   the endpoint to an attack by any proxy on the path to get it to
   reveal location.  The proxy can attempt to redirect a call to the
   service URN which, if the device recognizes the significance, would
   include location in the redirected call from the device.  All
   networks elements should detect emergency calls and supply default
   location and/or routing if it is not already present.

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   The LoST server would normally be provided by the local emergency
   authorities, although the access network or calling network might run
   its own server using data provided by the emergency authorities.
   Some enterprises may have local responders and call centers, and
   could operate their own LoST server, providing URIs to in-house
   "PSAPs".  Local regulations might limit the ability of enterprises to
   direct emergency calls to in-house services.

   The ESRP, which is a normal SIP proxy server in the signaling path of
   the call, may use a variety of PSAP state information, the location
   of the caller, and other criteria to onward route the call to the
   PSAP.  In order for the ESRP to route on media choice, the initial
   INVITE request has to supply an SDP offer.

9.  Signaling of emergency calls

9.1.  Use of TLS

   Best Current Practice for SIP user agents [RFC4504] including
   handling of audio, video and real-time text [RFC4103] should be
   applied.  As discussed above, location is carried in all emergency
   calls in the call signaling.  Since emergency calls carry privacy-
   sensitive information, they are subject to the requirements for
   geospatial protocols [RFC3693].  In particular, signaling information
   should be carried in TLS, i.e., in 'sips' mode with a ciphersuite
   which includes strong encryption (e.g., AES).  There are exceptions
   in [RFC3693] for emergency calls.  For example, local policy may
   dictate that location is sent with an emergency call even if the
   user's policy would otherwise prohibit that.  Nevertheless,
   protection from eavesdropping of location by encryption should be
   provided.

   It is unacceptable to have an emergency call fail to complete because
   a TLS connection was not created for any reason.  Thus, the call
   should be attempted with TLS, but if the TLS session establishment
   fails, the call should be automatically retried without TLS.
   [RFC5630] recommends that to achieve this effect the target specifies
   a sip URI, but use TLS on the outbound connection.  An element that
   receives a request over a TLS connection should attempt to create a
   TLS connection to the next hop.

   In many cases, persistent TLS connections can be maintained between
   elements to minimize the time needed to establish them [RFC5626].  In
   other circumstances, use of session resumption [RFC5077] is
   recommended.  IPsec [RFC4301] is an acceptable alternative to TLS
   when used with an equivalent crypto suite.

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   Location may be used for routing by multiple proxy servers on the
   path.  Confidentiality mechanisms such as S/MIME encryption of SIP
   signaling [RFC3261] cannot be used because they obscure location.
   Only hop-by-hop mechanisms such as TLS should be used.  Implementing
   location conveyance in SIP mandates inclusion of TLS support.

9.2.  SIP signaling requirements for User Agents

   SIP UAs that recognize local dial strings, insert location, and
   perform emergency call routing will create SIP INVITE messages with
   the Service URN in the Request URI, the LoST-determined URI for the
   PSAP in a Route header, and the location in a Geolocation header.
   The INVITE request must also have appropriate call back identifiers
   (in Contact and From headers).  To enable media sensitive routing,
   the call should include an SDP offer.

   SIP caller preferences [RFC3841] can be used to signal how the PSAP
   should handle the call.  For example, a language preference expressed
   in an Accept-Language header may be used as a hint to cause the PSAP
   to route the call to a call taker who speaks the requested language.
   SIP caller preferences may also be used to indicate a need to invoke
   a relay service for communication with people with disabilities in
   the call.

9.3.  SIP signaling requirements for proxy servers

   At least one SIP proxy server in the path of an emergency call must
   be able to assist UAs that are unable to provide any of the location
   based routing steps and recognition of dial strings.  A Proxy can
   recognize the lack of location awareness by the lack of a Geolocation
   header.  They can recognize the lack of dial string recognition by
   the presence of the local emergency call dial string in the From
   header without the service URN being present.  They should obtain the
   location of the endpoint if possible, and use a default location if
   they can not, inserting it in a Geolocation header.  They should
   query LoST with the location and put the resulting URI in a Route,
   with the appropriate service URN in the Request URI.  In any event,
   they are also expected to provide information for the caller using
   SIP Identity or P-Asserted-Identity.  It is often a regulatory matter
   whether calls normally marked as anonymous are passed as anonymous
   when they are emergency calls.  Proxies must conform to the local
   regulation or practice.

10.  Call backs

   The call-taker must be able to reach the emergency caller if the
   original call is disconnected.  In traditional emergency calls,

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   wireline and wireless emergency calls include a callback identifier
   for this purpose.  There are two kinds of call backs.  When a call is
   dropped, or the call taker realizes that some important information
   is needed that it doesn't have, it must call back the device that
   placed the emergency call.  The PSAP, or a responder, may need to
   call back the caller much later, and for that purpose, it wants a
   normal SIP Address of Record.  In SIP systems, the caller must
   include a Contact header field in an emergency call containing a
   globally routable URI, possibly a GRUU [RFC5627].  This identifier
   would be used to initiate call-backs immediately by the call-taker
   if, for example, the call is prematurely dropped.  A concern arises
   with B2BUAs that manipulate Contact headers.  Such B2BUAs should
   always include a Contact header that routes to the same device.

   In addition, a call-back identifier as an Address of Record (AoR)
   must be included either as the URI in the From header field [RFC3261]
   verified by SIP Identity [RFC4474] or as a network asserted URI
   [RFC3325].  If the latter, the PSAP will need to establish a suitable
   spec(t) with the proxies that send it emergency calls.  This
   identifier would be used to initiate a call-back at a later time and
   may reach the caller, not necessarily on the same device (and at the
   same location) as the original emergency call as per normal SIP
   rules.  It is often a regulatory matter whether calls normally marked
   as anonymous are passed as anonymous when they are emergency calls.
   Proxies must conform to the local regulation or practice.

11.  Mid-call behavior

   Some PSAPs often include dispatchers, responders or specialists on a
   call.  Some responder's dispatchers are not located in the primary
   PSAP, the call may have to be transferred to another PSAP.  Most
   often this will be an attended transfer, or a bridged transfer.
   Therefore a PSAP may need to a REFER request [RFC3515] a call to a
   bridge for conferencing.  Devices which normally involve the user in
   transfer operations should consider the effect of such interactions
   when a stressed user places an emergency call.  Requiring UI
   manipulation during such events may not be desirable.  Relay services
   for communication with people with disabilities may be included in
   the call with the bridge.  The UA should be prepared to have the call
   transferred (usually attended, but possibly blind) per [RFC5359].

12.  Call termination

   It is undesirable for the caller to terminate an emergency call.
   PSAP terminates a call using the normal SIP call termination
   procedures, i.e., with a BYE request.

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13.  Disabling of features

   Certain features that can be invoked while a normal call is active
   are not permitted when the call is an emergency call.  Services such
   as call waiting, call transfer, three way call and hold should be
   disabled.

   Certain features such as call forwarding can interfere with calls
   from a PSAP and should be disabled.  There is no way to reliably
   determine a PSAP call back.  A UA may be able to determine a PSAP
   call back by examining the domain of incoming calls after placing an
   emergency call and comparing that to the domain of the answering PSAP
   from the emergency call.  Any call from the same domain and directed
   to the supplied Contact header or AoR after an emergency call should
   be accepted as a call-back from the PSAP if it occurs within a
   reasonable time after an emergency call was placed.

14.  Media

   PSAPs should always accept RTP media streams [RFC3550].
   Traditionally, voice has been the only media stream accepted by
   PSAPs.  In some countries, text, in the form of Baudot codes or
   similar tone encoded signaling within a voiceband is accepted ("TTY")
   for persons who have hearing disabilities.  Using SIP signaling
   includes the capability to negotiate media.  Normal SIP offer/answer
   [RFC3264] negotiations should be used to agree on the media streams
   to be used.  PSAPs should accept real-time text [RFC4103].  All PSAPs
   should accept G.711 A-law (and mu-law in North America) encoded voice
   as described in [RFC3551].  Newer text forms are rapidly appearing,
   with instant messaging now very common, PSAPs should accept IM with
   at least "pager-mode" MESSAGE request [RFC3428] as well as Message
   Session Relay Protocol [RFC4975].  Video may be important to support
   Video Relay Service (sign language interpretation) as well as modern
   video phones.

   It is desirable for media to be kept secure by the use of Secure RTP
   [RFC3711], using DTLS [RFC5764] for keying.

15.  Testing

   Since the emergency calling architecture consists of a number of
   pieces operated by independent entities, it is important to be able
   to test whether an emergency call is likely to succeed without
   actually occupying the human resources at a PSAP.  Both signaling and
   media paths need to be tested since NATs and firewalls may allow the
   session setup request to reach the PSAP, while preventing the

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   exchange of media.

   [I-D.ietf-ecrit-phonebcp]includes a description of an automated test
   procedure that validates routing, signaling and media path
   continuity.  This test would be used within some random interval
   after boot time, and whenever the device location changes enough that
   a new PSAP mapping is returned by the LoST server.

   The PSAP needs to be able to control frequency and duration of the
   test, and since the process could be abused, it may temporarily or
   permanently suspend its operation.

   There is a concern associated with testing during a so-called
   "avalanche-restart" event where, for example a large power outage
   affects a large number of endpoints, that, when power is restored,
   all attempt to reboot and, possibly, test.  Devices need to randomize
   their initiation of a boot time test to avoid the problem.

16.  Security Considerations

   Security considerations for emergency calling have been documented in
   [RFC5069] and [RFC6280].

   This document suggests that security (TLS or IPsec) be used hop by
   hop on a SIP call to protect location information, identity, etc.  It
   also suggests that if the attempt to create a security association
   fails, the call be retried without the security.  It's more important
   to get an emergency call through than to protect the data; indeed, in
   many jurisdictions privacy is explicitly waived when making emergency
   calls.  Placing a call without security may reveal user information,
   including location.  The alternative - failing the call if security
   cannot be established, is considered unacceptable.

17.  IANA Considerations

   This document has no actions for IANA.

18.  Acknowledgments

   This draft was created from a
   draft-schulzrinne-sipping-emergency-arch-02 together with sections
   from draft-polk-newton-ecrit-arch-considerations-02.

   Design Team members participating in this draft creation include
   Martin Dolly, Stu Goldman, Ted Hardie, Marc Linsner, Roger Marshall,

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   Shida Schubert, Tom Taylor and Hannes Tschofenig,.  Further comments
   and input were provided by Richard Barnes, Barbara Stark and James
   Winterbottom.

19.  Informative References

   [I-D.ietf-ecrit-phonebcp]
              Rosen, B. and J. Polk, "Best Current Practice for
              Communications Services in support of Emergency Calling",
              draft-ietf-ecrit-phonebcp-20 (work in progress),
              September 2011.

   [I-D.ietf-sip-location-conveyance]
              Polk, J. and B. Rosen, "Location Conveyance for the
              Session Initiation Protocol",
              draft-ietf-sip-location-conveyance-13 (work in progress),
              March 2009.

   [LLDP]     IEEE, "IEEE802.1ab Station and Media Access Control",
              Dec 2004.

   [LLDP-MED]
              TIA, "ANSI/TIA-1057 Link Layer Discovery Protocol - Media
              Endpoint Discovery".

   [NENAi3TRD]
              NENA, "08-751 NENA i3 Technical Requirements for", 2006.

   [RFC3261]  Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston,
              A., Peterson, J., Sparks, R., Handley, M., and E.
              Schooler, "SIP: Session Initiation Protocol", RFC 3261,
              June 2002.

   [RFC3264]  Rosenberg, J. and H. Schulzrinne, "An Offer/Answer Model
              with Session Description Protocol (SDP)", RFC 3264,
              June 2002.

   [RFC3325]  Jennings, C., Peterson, J., and M. Watson, "Private
              Extensions to the Session Initiation Protocol (SIP) for
              Asserted Identity within Trusted Networks", RFC 3325,
              November 2002.

   [RFC3428]  Campbell, B., Rosenberg, J., Schulzrinne, H., Huitema, C.,
              and D. Gurle, "Session Initiation Protocol (SIP) Extension
              for Instant Messaging", RFC 3428, December 2002.

   [RFC3515]  Sparks, R., "The Session Initiation Protocol (SIP) Refer

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              Method", RFC 3515, April 2003.

   [RFC3550]  Schulzrinne, H., Casner, S., Frederick, R., and V.
              Jacobson, "RTP: A Transport Protocol for Real-Time
              Applications", STD 64, RFC 3550, July 2003.

   [RFC3551]  Schulzrinne, H. and S. Casner, "RTP Profile for Audio and
              Video Conferences with Minimal Control", STD 65, RFC 3551,
              July 2003.

   [RFC3693]  Cuellar, J., Morris, J., Mulligan, D., Peterson, J., and
              J. Polk, "Geopriv Requirements", RFC 3693, February 2004.

   [RFC3711]  Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K.
              Norrman, "The Secure Real-time Transport Protocol (SRTP)",
              RFC 3711, March 2004.

   [RFC3841]  Rosenberg, J., Schulzrinne, H., and P. Kyzivat, "Caller
              Preferences for the Session Initiation Protocol (SIP)",
              RFC 3841, August 2004.

   [RFC3856]  Rosenberg, J., "A Presence Event Package for the Session
              Initiation Protocol (SIP)", RFC 3856, August 2004.

   [RFC3986]  Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform
              Resource Identifier (URI): Generic Syntax", STD 66,
              RFC 3986, January 2005.

   [RFC4103]  Hellstrom, G. and P. Jones, "RTP Payload for Text
              Conversation", RFC 4103, June 2005.

   [RFC4119]  Peterson, J., "A Presence-based GEOPRIV Location Object
              Format", RFC 4119, December 2005.

   [RFC4190]  Carlberg, K., Brown, I., and C. Beard, "Framework for
              Supporting Emergency Telecommunications Service (ETS) in
              IP Telephony", RFC 4190, November 2005.

   [RFC4301]  Kent, S. and K. Seo, "Security Architecture for the
              Internet Protocol", RFC 4301, December 2005.

   [RFC4474]  Peterson, J. and C. Jennings, "Enhancements for
              Authenticated Identity Management in the Session
              Initiation Protocol (SIP)", RFC 4474, August 2006.

   [RFC4504]  Sinnreich, H., Lass, S., and C. Stredicke, "SIP Telephony
              Device Requirements and Configuration", RFC 4504,
              May 2006.

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   [RFC4776]  Schulzrinne, H., "Dynamic Host Configuration Protocol
              (DHCPv4 and DHCPv6) Option for Civic Addresses
              Configuration Information", RFC 4776, November 2006.

   [RFC4967]  Rosen, B., "Dial String Parameter for the Session
              Initiation Protocol Uniform Resource Identifier",
              RFC 4967, July 2007.

   [RFC4975]  Campbell, B., Mahy, R., and C. Jennings, "The Message
              Session Relay Protocol (MSRP)", RFC 4975, September 2007.

   [RFC5012]  Schulzrinne, H. and R. Marshall, "Requirements for
              Emergency Context Resolution with Internet Technologies",
              RFC 5012, January 2008.

   [RFC5031]  Schulzrinne, H., "A Uniform Resource Name (URN) for
              Emergency and Other Well-Known Services", RFC 5031,
              January 2008.

   [RFC5069]  Taylor, T., Tschofenig, H., Schulzrinne, H., and M.
              Shanmugam, "Security Threats and Requirements for
              Emergency Call Marking and Mapping", RFC 5069,
              January 2008.

   [RFC5077]  Salowey, J., Zhou, H., Eronen, P., and H. Tschofenig,
              "Transport Layer Security (TLS) Session Resumption without
              Server-Side State", RFC 5077, January 2008.

   [RFC5139]  Thomson, M. and J. Winterbottom, "Revised Civic Location
              Format for Presence Information Data Format Location
              Object (PIDF-LO)", RFC 5139, February 2008.

   [RFC5222]  Hardie, T., Newton, A., Schulzrinne, H., and H.
              Tschofenig, "LoST: A Location-to-Service Translation
              Protocol", RFC 5222, August 2008.

   [RFC5223]  Schulzrinne, H., Polk, J., and H. Tschofenig, "Discovering
              Location-to-Service Translation (LoST) Servers Using the
              Dynamic Host Configuration Protocol (DHCP)", RFC 5223,
              August 2008.

   [RFC5359]  Johnston, A., Sparks, R., Cunningham, C., Donovan, S., and
              K. Summers, "Session Initiation Protocol Service
              Examples", BCP 144, RFC 5359, October 2008.

   [RFC5491]  Winterbottom, J., Thomson, M., and H. Tschofenig, "GEOPRIV
              Presence Information Data Format Location Object (PIDF-LO)
              Usage Clarification, Considerations, and Recommendations",

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              RFC 5491, March 2009.

   [RFC5626]  Jennings, C., Mahy, R., and F. Audet, "Managing Client-
              Initiated Connections in the Session Initiation Protocol
              (SIP)", RFC 5626, October 2009.

   [RFC5627]  Rosenberg, J., "Obtaining and Using Globally Routable User
              Agent URIs (GRUUs) in the Session Initiation Protocol
              (SIP)", RFC 5627, October 2009.

   [RFC5630]  Audet, F., "The Use of the SIPS URI Scheme in the Session
              Initiation Protocol (SIP)", RFC 5630, October 2009.

   [RFC5764]  McGrew, D. and E. Rescorla, "Datagram Transport Layer
              Security (DTLS) Extension to Establish Keys for the Secure
              Real-time Transport Protocol (SRTP)", RFC 5764, May 2010.

   [RFC5985]  Barnes, M., "HTTP-Enabled Location Delivery (HELD)",
              RFC 5985, September 2010.

   [RFC5986]  Thomson, M. and J. Winterbottom, "Discovering the Local
              Location Information Server (LIS)", RFC 5986,
              September 2010.

   [RFC6225]  Polk, J., Linsner, M., Thomson, M., and B. Aboba, "Dynamic
              Host Configuration Protocol Options for Coordinate-Based
              Location Configuration Information", RFC 6225, July 2011.

   [RFC6280]  Barnes, R., Lepinski, M., Cooper, A., Morris, J.,
              Tschofenig, H., and H. Schulzrinne, "An Architecture for
              Location and Location Privacy in Internet Applications",
              BCP 160, RFC 6280, July 2011.

   [WGS84]    NIMA, "NIMA Technical Report TR8350.2, Department of
              Defense World Geodetic System 1984, Its Definition and
              Relationships With Local Geodetic Systems, Third Edition",
              July 1997.

Rosen, et al.            Expires March 11, 2012                [Page 36]
Internet-Draft          Emergency Call Framework          September 2011

Authors' Addresses

   Brian Rosen
   NeuStar, Inc.
   470 Conrad Dr
   Mars, PA  16046
   USA

   Email: br@brianrosen.net

   Henning Schulzrinne
   Columbia University
   Department of Computer Science
   450 Computer Science Building
   New York, NY  10027
   USA

   Phone: +1 212 939 7042
   Email: hgs@cs.columbia.edu
   URI:   http://www.cs.columbia.edu

   James Polk
   Cisco Systems
   3913 Treemont Circle
   Colleyville, Texas  76034
   USA

   Phone: +1-817-271-3552
   Email: jmpolk@cisco.com

   Andrew Newton
   TranTech/MediaSolv
   4900 Seminary Road
   Alexandria, VA  22311
   USA

   Phone: +1 703 845 0656
   Email: andy@hxr.us

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