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Versions: (draft-schulzrinne-atoca-requirements) 00 01 02 03

ATOCA                                                     H. Schulzrinne
Internet-Draft                                       Columbia University
Intended status: Informational                                S. Norreys
Expires: September 13, 2012                                     BT Group
                                                                B. Rosen
                                                           NeuStar, Inc.
                                                           H. Tschofenig
                                                  Nokia Siemens Networks
                                                          March 12, 2012


   Requirements, Terminology and Framework for Exigent Communications
                  draft-ietf-atoca-requirements-03.txt

Abstract

   Before, during and after emergency situations various agencies need
   to provide information to a group of persons or to the public within
   a geographical area.  While many aspects of such systems are specific
   to national or local jurisdictions, emergencies span such boundaries
   and notifications need to reach visitors from other jurisdictions.

   This document provides terminology, requirements and an architectural
   description for protocols exchanging alerts between IP-based end
   points.

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 September 13, 2012.

Copyright Notice

   Copyright (c) 2012 IETF Trust and the persons identified as the
   document authors.  All rights reserved.




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   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
   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.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  3
     1.1.  Classical Early Warning Situations . . . . . . . . . . . .  3
     1.2.  Exigent Communications . . . . . . . . . . . . . . . . . .  3
   2.  Terminology  . . . . . . . . . . . . . . . . . . . . . . . . .  5
     2.1.  Originator . . . . . . . . . . . . . . . . . . . . . . . .  6
     2.2.  Relay  . . . . . . . . . . . . . . . . . . . . . . . . . .  7
     2.3.  Gateway  . . . . . . . . . . . . . . . . . . . . . . . . .  7
     2.4.  Receiver . . . . . . . . . . . . . . . . . . . . . . . . .  7
   3.  Framework  . . . . . . . . . . . . . . . . . . . . . . . . . .  7
     3.1.  Small Group Alert Delivery . . . . . . . . . . . . . . . .  8
     3.2.  Mass Alert Delivery  . . . . . . . . . . . . . . . . . . .  8
   4.  Requirements . . . . . . . . . . . . . . . . . . . . . . . . . 10
     4.1.  Requirements for the Discovery of an Alert
           Distribution Server  . . . . . . . . . . . . . . . . . . . 10
     4.2.  Requirements for Multicast/Broadcast Alert Message
           Delivery . . . . . . . . . . . . . . . . . . . . . . . . . 11
   5.  IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 11
   6.  Security Considerations  . . . . . . . . . . . . . . . . . . . 11
   7.  Acknowledgments  . . . . . . . . . . . . . . . . . . . . . . . 13
   8.  References . . . . . . . . . . . . . . . . . . . . . . . . . . 13
     8.1.  Normative References . . . . . . . . . . . . . . . . . . . 13
     8.2.  Informative References . . . . . . . . . . . . . . . . . . 13
   Appendix A.  Supplementary Requirements  . . . . . . . . . . . . . 14
     A.1.  Requirements for Alert Subscription  . . . . . . . . . . . 14
     A.2.  Point-to-Point Alert Delivery  . . . . . . . . . . . . . . 15
   Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 15












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1.  Introduction

1.1.  Classical Early Warning Situations

   During large-scale emergencies, public safety authorities need to
   reliably communicate with citizens in the affected areas, to provide
   warnings, indicate whether citizens should evacuate and how, and to
   dispel misinformation.  Accurate information can reduce the impact of
   such emergencies.

   Traditionally, emergency alerting has used church bells, sirens,
   loudspeakers, radio and television to warn citizens and to provide
   information.  However, techniques, such as sirens and bells, provide
   limited information content; loud speakers cover only very small
   areas and are often hard to understand, even for those not hearing
   impaired or fluent in the local language.  Radio and television offer
   larger information volume, but are hard to target geographically and
   do not work well to address the "walking wounded" or other
   pedestrians.  Both are not suitable for warnings, as many of those
   needing the information will not be listening or watching at any
   given time, particularly during work/school and sleep hours.

   This problem has been illustrated by the London underground bombing
   on July 7, 2006, as described in a government report [July2005].  The
   UK authorities could only use broadcast media and could not, for
   example, easily announce to the "walking wounded" where to assemble.

1.2.  Exigent Communications

   With the usage of the term 'Exigent Communications' this document
   aims to generalize the concept of conveying alerts to IP-based
   systems and at the same time to describe the actors that participate
   in the messaging communication.  More precisely, exigent
   communications is defined as:

      Communication that requirs immediate action or remedy.
      Information about the reason for action and details about the
      steps that have to be taken are provided in the alert message.

      An alert message (or warning message) is a cautionary advice about
      something imminent (especially imminent danger or other
      unpleasantness).  In the context of exigent communication such an
      alert message refers to a future, ongoing or past event as the
      signaling exchange itself may relate to different stages of the
      lifecycle of the event.  The alert message itself, and not the
      signaling protocol that convey it, provides sufficient context
      about the specific state of the lifecycle the alert message refers
      to.



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   On a high level the communication occurs in two phases with the
   subscription phase sometimes being implicit:

   Subscription:

      In this step Recipients express their interest in receiving
      certain types of alerts.  This step happens prior to the actual
      delivery of the alert.  This expression of interest may be in form
      of an explicit communication step by having the Receiver send a
      subscribe message (potentially with an indication of the type of
      alerts they are interested in, the duration of the subscription
      and a number of other indicators).  For example, parents may want
      to be alerted of emergencies affecting the school attended by
      their children and adult children may need to know about
      emergencies affecting elderly parents.  The subscription step may,
      however, also happen outside the Internet communication
      infrastructure and instead by the Recipient signing a contract and
      thereby agreeing to receive certain alerts.  The Receiver, a
      software application, still needs to be configured in such a way
      that incoming alerts are accepted, processed and passed up to the
      user interface alerting a Recipient.  Additionally, certain
      subscriptions may happen without the Recipient's explicit consent
      and without the Receiver sending a subscription.  For example, a
      Tsunami flood alert may be delivered to all Receivers in case they
      are located in a specific geographical area.

      It is important to note that a protocol interaction initiated by
      the Receiver may need to take place to subscribe to certain types
      of alerts.  In some other cases the subscription does not require
      such interaction from the Receiver.  Orthogonal to the need to
      have a protocol interaction is the question of opt-in vs. opt-out.
      Whether the Recipient, as a human actor, needs to consent to
      receive certain types of alerts is a policy decision that is
      largely outside the scope of a technical specification.

   Alert Delivery:

      In this step the alert message is distributed to one or multiple
      Receivers.  The Receiver as a software module that presents the
      alert message to the Recipient.  The alert encoding is
      accomplished via the Common Alerting Protocol (CAP) and such an
      alert message contains useful information needed for dealing with
      the imminent danger.

   Note that an alert receiver software modules may not necessarily only
   be executed on end devices humans typically carry around, such as
   mobile phones, Internet tablets, or laptops.  Instead, alerts may
   well be directly sent to displays in subway stations, or electronic



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   bill boards.  Furthermore, a software module that obtains an alert
   may not necessarily need to interact with a human (as the Recipient)
   but may instead use it as input to another process to trigger
   automated behaviors, such as closing vents during a chemical spill or
   activating sirens or other warning systems in commercial buildings.

   This document provides terminology, requirements and an architectural
   description.  Note that the requirements focus on the communication
   protocols for subscription and alert delivery rather than on the
   content of the alert message itself.  With the usage of CAP these
   alert message content requirements are delegated to the Authors and
   Originators of alerts.


2.  Terminology

   The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in [RFC2119], with the
   important qualification that, unless otherwise stated, these terms
   apply to the design of a protocol conveying warning messages, not its
   implementation or application.

   Alert messages are typically produced by humans and consumed by
   users, Authors and Recipients in our system, are the sources and
   sinks of alert messages.

   The Author is a human responsible for creating the content of the
   alert message, and to make a decision about the intended recipients,
   even though the exact list of recipients may be unknown to the Author
   at the time of writing the alert message.  Instead, the recipients
   may, for example, be described in terms of a geographical region, or
   recipients with interest in a specific alert type.

   The Recipient is a consumer of the delivered alert message.  It is a
   human reading the alert message.

   From the user's perspective, all alert message transfer activities
   are performed by a monolithic Message Handling Service (MHS), even
   though the actual service can be provided by many independent
   organizations.  The Message Handling Service (MHS) performs a single
   end-to-end transfer of warning messages on behalf of the Author to
   reach the Recipients.

   Figure 1 shows the relationships among transfer participants.
   Transfers typically entail one or more Relays.  However, direct
   delivery from the Originator to Receiver is possible.




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       ++==========++                        ++===========++
       ||  Author  ||                        || Recipient ||
       ++====++====++                        ++===========++
             ||                                     /\
             ||                                     ||
             \/                                     ||
        +----------+                            +---++----+
        |          |                            |         |
      /-+----------+----------------------------+---------+---\
      | |          |     Message Handling       |         |   |
      | |Originator|       System (MHS)         |Receiver |   |
      | |          |                            |         |   |
      | +---++-----+                            +---------+   |
      |     ||                                      /\        |
      |     ||                                      ||        |
      |     \/                                      ||        |
      | +---------+         +---------+        +-+--++---+    |
      | |  Relay  +======-=>|  Relay  +=======>|  Relay  |    |
      | +---------+         +----++---+        +---------+    |
      |                          ||                           |
      |                          ||                           |
      |                          \/                           |
      |                     +---------+                       |
      |                     | Gateway +-->                    |
      |                     +---------+                       |
      \-------------------------------------------------------/

     Legend: === and || lines indicate primary (possibly
                 indirect) transfers or roles

                 Figure 1: Relationships Among MHS Actors

2.1.  Originator

   The Originator ensures that a warning message is valid for transfer
   and then submits it to a Relay.  A message is valid if it conforms to
   both communication and warning message encapsulation standards and
   local operational policies.  The Originator can simply review the
   message for conformance and reject it if it finds errors, or it can
   create some or all of the necessary information.

   The Originator serves the Author and can be the same entity in
   absence of a human crafting alert messages.

   The Originator also performs any post-submission, Author-related
   administrative tasks associated with message transfer and delivery.
   Notably, these tasks pertain to sending error and delivery notices,
   and enforcing local policies.  The Author creates the message, but



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   the Originator handles any transmission issues with it.

2.2.  Relay

   The Relay performs MHS-level transfer-service routing and store-and-
   forward, by transmitting or retransmitting the message to its
   Recipients.  The Relay may add history information (e.g., the SIP
   History Info [RFC4244] serves as a good example of the type of
   information that may be conveyed) or security related protection
   (e.g., as available with SIP Identity [RFC4474]) but does not modify
   the envelope information or the message content semantics.

   A Message Handling System (MHS) network consists of a set of Relays.
   This MHS network is typically above any underlying IP network but may
   involve technologies like IP multicast.

2.3.  Gateway

   A Gateway connects heterogeneous communication infrastructures and
   its purpose is to emulate a Relay and the closer it comes to this,
   the better.  A Gateway needs the ability to modify message content.

   Differences between the different communication systems can be as
   small as minor syntax variations, but they usually encompass
   significant, semantic distinctions.  Hence, the Relay function in a
   Gateway presents a significant design challenge, if the resulting
   performance is to be seen as nearly seamless.  The challenge is to
   ensure end-to-end communication between the communication services,
   despite differences in their syntax and semantics.

2.4.  Receiver

   The Receiver performs final delivery and is typically responsible for
   ensuring that the appropriate user interface rendering is executed to
   interact with the Recipient.


3.  Framework

   Section 1 describes the basic two steps that are involved with the
   alert message handling, namely subscription and alert delivery.  From
   an architectural point of view there are, however, a few variations
   possible depending on the characteristics of the subscription process
   and the style of message delivery.  This section offers more details
   on the communication architecture.  Note that this document does not
   mandate a specific deployment architecture.  Instead it aims to
   illustrate how various different protocol components fit together to
   present the reader with the 'big picture'.



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3.1.  Small Group Alert Delivery

   We start our description with the so-called "school closed" example
   where school authorities send alerts to all parents to notify them
   about the fact that their children cannot attend school.  Parents
   subscribe to these events when their children start attending the
   school and unsubscribe when they are finished with a particular
   school.  The subscription procedures establishes some form of group
   communication by requiring an initial registration procedure.
   Typically, alert messages stay within the closed group and are not
   shared with others and alert message delivery is point-to-point with
   whatever communication protocol is most suitable.  This also means
   that the alerts reach those who have subscribed rather than those who
   are in the vicinity of the school.  The number of Recipients is
   typically rather small, in the order of hundreds to several
   thousands.

   A variation of the "school closed" example is an explicit
   subscription model where no closed group pattern exists.  The main
   difference to the former case is in the authorization model.
   Consider a traveler who would like to receive weather alerts about a
   specific geographical region.  He may have to manually search for how
   to subscribe to alerts for the desired region, potentially looking a
   different subscription points for different types of alerts.  As an
   automated version of this procedure some form of discovery may help
   to find these subscription servers.  The approach described in
   [I-D.rosen-ecrit-lost-early-warning] is one possible way to discovery
   such alert subscription servers.  The number of alert message
   Recipients is much larger than in the previous school example but
   will typically stay below the millions.

   These alert delivery examples are supported by a number of
   standardized communication protocols, such as SIP, XMPP, eMail, or
   RSS feeds.

   Note that there are optimizations for application layer alert
   delivery that mimic a multicast delivery with the help of Relays.
   However, a subscription is still necessary by the Receiver and the
   last-hop delivery of the alert is still done using unicast
   transmission.

   While these two examples are important for many deployments they are
   not in focus of the ATOCA working group.

3.2.  Mass Alert Delivery

   With the next category we move to a scenario where large number of
   Recipients shall be notified but the subscription itself is implicit,



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   as it is the case when persons are within a specific region that can
   easily be reached by making use of broadcast link layer technologies.
   The placement of the actors from Figure 1 is thereby important.  An
   Originator distributes the alert message to Relays within the
   geographically affected area.  Those Relays are located within
   Internet Service Providers so that multicast and broadcast
   communication protocols can be utilized for efficient distribution to
   a large number of Recipients within the affected area.  When the
   alert message delivery has to be accomplished at the network layer
   then various requirements, such as the ability to traverse NATs and
   firewalls, have to be met by such a protocol.  In this scenario the
   number of alert message Recipients is very large, potentially in the
   millions.

   As a variation of the previously described model consider an alert
   distribution with subscriptions to the alerts.  Figure 2 shows the
   architecture.

   A discovery server ensures that Receivers are able to learn the local
   alert distribution servers.  Once a Receiver had discovered a local
   alert distribution server it sends a subscribe message to it.  As a
   response, it will receive information about the security credentials
   the alert distribution server is going to use for subsequent alert
   delivery.

   When an Author creates an alert for distribution the affected region
   will be indicated and so the alert will be sent to a Relay within the
   realm of the local alert distribution server and a notification will
   be sent to all the subscribed Receivers.






















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                           ,-----------.
                           | Discovery |
                           | Server    |
                           `...........'
                                :
                                :
    ,''''''''''''''''''''''''\  :
    | Local         ,------. |  :
    | Alert         | Local| |  :                ...................
    | Distribution  | Relay|.|..:   Alert        | +------+ Author |
    | Server        `......'-+<------------------+-|Sender|    O   |
    |                  |     |     Notification  | |      |   /|\  |
    '`'''''''''''''''''+''''''                   | +------+   / \  |
       ^        Alert  |                         `-----------------'
    Subscr.  +---------+
       |     |  Notification
       |     |
       |     V
    .....................
    | +------+ Recipient|
    | |Recvr |    O     |
    | |      |   /|\    |
    | +------+   / \    |
    `-------------------'

   Figure 2: Multicast/Broadcast Alert Delivery Mechanism with Explicit
                               Subscription


4.  Requirements

   The requirements listed below focus on the goal of mass alert
   distribution, which has to utilize multicast/broadcast communication
   for scalability reasons.  The requirements for point-to-point alert
   delivery are shown in Appendix A for completeness reasons only since
   the focus of the IETF ATOCA working group is on the multicast/
   broadcast alert delivery.

4.1.  Requirements for the Discovery of an Alert Distribution Server

   Req-D1:

      The protocol solution MUST allow a receiver to discover a local
      alert distribution server, as discussed in Section 3 and shown in
      Figure 2, and to discover the necessary security credentials for
      subsequent alert message distribution.





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4.2.  Requirements for Multicast/Broadcast Alert Message Delivery

   Req-B1:

      The protocol solution MUST leverage multicast/broadcast
      technologies.  This implies non-TCP transport and congestion
      control being considered.

   Req-B2:

      The protocol solution MUST allow delivery of messages
      simultaneously to a large audience.

   Req-B3:

      The protocol solution MUST be able to traverse firewalls and NATs
      as they are common in today's deployments.


5.  IANA Considerations

   This document does not require actions by IANA.


6.  Security Considerations

   Figure 1 shows the actors for delivering an alert message assuming
   that a prior subscription has taken place already.  The desired
   security properties of an MHS for conveying alerts will depend on the
   number of administrative domains involved.  Each administrative
   domain can have vastly different operating policies and trust-based
   decision-making.  One obvious example is the distinction between
   alert messages that are exchanged within an closed group (such as
   alert messages received by parents affecting the school attended by
   their children) and alert messages that are exchanged between
   independent organizations (e.g., in case of large scale disasters).
   The rules for handling both types of communication architectures tend
   to be quite different.  That difference requires defining the
   boundaries of each.

   Operation of communication systems that are used to convey alert
   messages are typically carried out by different providers (or
   operators).  Since each be in operated in an independent
   administrative domain it is useful to consider administrative domain
   boundaries in the description to facilitate discussion about designs,
   policies and operations that need to distinguish between internal
   issues and external entities.  Most significant is that the entities
   communicating across administrative boundaries typically have the



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   added burden of enforcing organizational policies concerning external
   communications.  For example, routing alerts between administrative
   domains can create requirements, such as needing to route alert
   messages between organizational partners over specially trusted
   paths.

   The communication interactions are subject to the policies of that
   domain, which cover concerns such as these:

   o  Reliability
   o  Access control
   o  Accountability
   o  Content evaluation, adaptation, and modification

   Many communication systems make the distinction of administrative
   domains since they impact the requirements on security solutions.
   However, with the distribution of alert messages a number of
   additional security threats need to be addressed.  Due to the nature
   of alerts it is quite likely that end device implementations will
   offer user interface enhancements to get the Recipients attention
   whenever an alert arrives, which is an attractive property for
   adversaries to exploit.  Below we list the most important threats any
   solution will have to deal with.

   Originator Impersonation:

      An attacker could then conceivably attempt to impersonate the
      Originator of an alert message.  This threat is particularly
      applicable to those deployment environments where authorization
      decisions are based on the identity of the Originator.

   Alert Message Forgery:

      An attacker could forge or alter an alert message in order to
      convey custom messages to Recipients to get their immediate
      attention.

   Replay:

      An attacker could obtain previously distributed alert messages and
      to replay them at a later time in the hope that Recipients could
      be tricked into believing they are fresh.

   Unauthorized Distribution:

      When a Receiver receives an alert message it has to determine
      whether the Author distributing the alert messages is genuine to
      avoid accepting messages that are injected by malicious entities



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      with the potential desire to at least get the immediate attention
      of the Recipient.

   Amplification Attack:

      An attacker may use the Message Handling System to inject a single
      alert message for distribution that may then be instantly turned
      into potentially millions of alert messages for distribution.

   One important security challenge is related to authorization.  When
   an alert message arrives at the Receiver then certain security checks
   may need to be performed to ensure that the alert message meets
   certain criteria.  The final consumer of the alert message is,
   however, the Recipient - a human.  From a security point of view the
   work split between the Recipient and the Receiver for making the
   authorization decision is important, particularly when an alert
   message is rejected due to a failed security verification by the
   Receiver.  False positives may be fatal but accepting every alert
   message lowers the trustworthiness in the overall system.


7.  Acknowledgments

   This document re-uses text from [RFC5598].  The authors would like to
   thank Dave Crocker for his work.

   The authors would like to thank Martin Thomson, Carl Reed, Leopold
   Murhammer, and Tony Rutkowski for their comments.

   At IETF#79 the following persons provided feedback leading to changes
   in this document: Keith Drage, Scott Bradner, Ken Carberg, Keeping
   Li, Martin Thomson, Igor Faynberg, Mark Wood, Peter Saint-Andre.


8.  References

8.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC5598]  Crocker, D., "Internet Mail Architecture", RFC 5598,
              July 2009.

8.2.  Informative References

   [I-D.rosen-ecrit-lost-early-warning]
              Rosen, B., Schulzrinne, H., and H. Tschofenig, "A Uniform



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              Resource Name (URN) for Early Warning Emergency Services
              and Location-to-Service Translation (LoST) Protocol
              Usage", draft-rosen-ecrit-lost-early-warning-01 (work in
              progress), July 2009.

   [July2005]
               ,  ., "Report of the 7 July Review Committee, ISBN 1
              85261 878 7", (PDF document), http://www.london.gov.uk/
              assembly/reports/7july/report.pdf, June 2006.

   [RFC4244]  Barnes, M., "An Extension to the Session Initiation
              Protocol (SIP) for Request History Information", RFC 4244,
              November 2005.

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

   [RFC5582]  Schulzrinne, H., "Location-to-URL Mapping Architecture and
              Framework", RFC 5582, September 2009.


Appendix A.  Supplementary Requirements

A.1.  Requirements for Alert Subscription

   The requirements listed below refer to the alert subscription phase
   as it is used to tailor alert message delivery in a point-to-point
   alert delivery scenario.  As noted in the main part of the document
   these requirements are not the main focus of the ATOCA work.

   Req-S1:

      The protocol solution MUST allow a potential Recipient to indicate
      the language used by alert messages.

   Req-S2:

      The protocol solution MUST allow a potential Recipient to express
      the geographical area it wants to receive alerts about.

   Req-S3:

      The protocol solution MUST allow a potential Recipient to indicate
      preferences about the type of alerts it wants to receive.






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   Req-S4:

      The protocol solution MUST allow a potential Recipient to express
      preference for certain media types.  The support for different
      media types depends on the content of the warning message but also
      impacts the communication protocol.  This functionality is, for
      example, useful for hearing and vision impaired persons.

A.2.  Point-to-Point Alert Delivery

   Req-P1:

      The protocol solution MUST build on existing communication
      protocols and support the delivery of alert messages.  Examples of
      such protocols are SIP, XMPP, Atom, eMail.

   Req-P2:

      The protocol solution MUST allow targeting notifications to
      specific subscribers.


Authors' Addresses

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

   Phone: +1 212 939 7004
   Email: hgs+ecrit@cs.columbia.edu
   URI:   http://www.cs.columbia.edu


   Steve Norreys
   BT Group
   1 London Road
   Brentwood, Essex  CM14 4QP
   UK

   Phone: +44 1277 32 32 20
   Email: steve.norreys@bt.com







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

   Phone:
   Email: br@brianrosen.net


   Hannes Tschhofenig
   Nokia Siemens Networks
   Linnoitustie 6
   Espoo  02600
   Finland

   Phone: +358 (50) 4871445
   Email: Hannes.Tschofenig@gmx.net
   URI:   http://www.tschofenig.priv.at
































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