One document matched: draft-schulzrinne-sipping-emergency-req-00.txt
Internet Engineering Task Force SIPPING
Internet Draft Schulzrinne
Columbia U.
draft-schulzrinne-sipping-emergency-req-00.txt
February 21, 2003
Expires: August 2003
Requirements for Session Initiation Protocol (SIP)-based
Emergency Calls
STATUS OF THIS MEMO
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of RFC2026.
Internet-Drafts are working documents of the Internet Engineering
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Abstract
This document enumerates requirements for emergency calls in VoIP and
general Internet multimedia systems. We divide the requirements into
"last-mile" and "end-to-end". Last-mile solutions only exchange the
emergency call center's circuit-switched access by an IP-based
system. The requirements for end-to-end IP-based emergency calling
address functional and security issues for determining the correct
emergency address, for identifying the appropriate emergency call
center and for identifying the caller and its location. While we
focus on systems that employ the Session Initiation Protocol (SIP),
many of the requirements also apply to other environments, such as
those using H.248/Megaco or H.323.
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1 Conventions used in this document
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119 [1].
2 Introduction
Users of telephone-like services expect to be able to call for
emergency help, such as police, the fire department or an ambulance,
regardless of where they are, what (if any) service provider they are
using and what kind of device they are using. Unfortunately, the
mechanisms for emergency calls that have evolved in the public
circuit-switched telephone network (PSTN) are not quite appropriate
for evolving IP-based voice and real-time multimedia communications.
This document outlines some of the requirements that end systems and
network elements such as SIP proxies need to satisfy in order to
provide emergency call services that offer at least the same
functionality as existing PSTN services, while hopefully making
emergency calling more robust, cheaper to implement and multimedia-
capable.
In the future, users of other real-time and near real-time services
may also expect to be able to summon emergency help. For example,
instant messaging (IM) users may want to use such services. IM is
particularly helpful for hearing-disabled users [3] and in cases
where bandwidth is scarce. For lack of a better term, we will use the
term "caller" or "emergency caller" to refer to the person placing an
emergency call or sending an emergency IM.
The emergency calls described in this document differ from the
emergency telecommunications service (ETS) described in [4]. In ETS,
relatively small numbers of emergency workers need to maintain
communication even when parts of the infrastructure are destroyed or
disabled. Emergency calls, on the other hand, are placed by civilians
to call for emergency services such as fire, ambulance and police
services. Thus, these two services are complementary.
3 Definitions
Emergency call center (ECC): An emergency call center (ECC)
receives emergency calls within a specific geographic area
and dispatches emergency services, such as fire, police and
rescue services. An ECC may also serve as a backup for
another ECC and, in backup mode, dispatch emergency
services outside of its normal service region. In the
United States and Canada, ECCs are called Public Safety
Access Points (PSAPs).
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Internet Protocol ECC (IECC): An Internet protocol emergency
call center (IECC) is an ECC that uses Internet protocols,
such as SIP for call signaling, RTP for media delivery, to
receive emergency calls.
Call taker: A call taker is an agent, typically a government
employee, at the ECC that accepts calls and may dispatch
emergency help. (Sometimes the functions of call taking
and dispatching are handled by different groups of people,
but these divisions of labor are not generally visible to
the outside and thus do not concern us here.)
Basic emergency service: Basic emergency service allows a user
to reach an ECC serving its current location, but the ECC
may not be able to determine the identity or geographic
location of the caller (except by having the call taker ask
the caller).
Enhanced emergency service: Enhanced emergency services add the
ability to identify the caller identity and/or caller
location to basic emergency services. (Sometimes, only the
caller location may be known, e.g., from a public access
point that is not owned by an individual.)
Last-mile emergency service: In last-mile emergency service, the
caller uses the existing PSTN infrastructure to place an
emergency call. Only the path from the "selective router"
to the ECC uses IP-based communications. The call may well
be placed from a VoIP device, but is assumed to enter the
PSTN very close to the location of the caller. The use of
Internet protocols is invisible to the caller.
End-to-end emergency service: In end-to-end emergency service,
the caller and ECC both use Internet protocols end-to-end.
4 Last-Mile Access
In last-mile access, an ECC replaces an analog (CAMA) or digital
(ISDN) trunk with packet-based access, typically over one or more
high-speed access lines such as DSL or leased lines. The packet-based
access terminates in the "selective router" that normally hands off
calls to the ECC. Thus, the ECC becomes an EICC, but no larger scale
infrastructure changes are required.
Last-mile access is motivated by cost and call setup
considerations. It may be cheaper to use IP-based
technology for the access link and ECC-internal
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communications. Also, many existing (US) PSAPs use analog
technology, so-called CAMA trunks, to receive emergency
calls. These trunks, originally designed for operator
positions, can pulse out the ten or 20-digit (for wireless)
caller's number, but as dialed digits. Thus, they add
several seconds of call setup delay. This can be
particularly disconcerting since it affects the time until
the call taker can pick up the call. IP-based
communications, using, for example, SIP as a call signaling
protocol, can effectively eliminate this extra caller
identification delay. (Additional delays are caused by the
often very low speed access to the mapping database that
maps caller identity to geographic location.) Finally,
since pending calls do not consume access network
resources, such systems may be more robust in the face of
overload.
M1: Coexistence: Due to the investment required, not all ECCs
will convert to IP-based access at the same time. Thus,
emergency calls MUST work in a network where some ECCs use
existing (analog) technology, some ISDN, others IP. In
particular, existing back-up relationships between ECCs
must continue to work.
M2: Call setup delay: The call setup delay MUST NOT be no larger
than for existing analog trunks and SHOULD be significantly
smaller.
M3: Call identification: Signaling from the PSTN switch must be
able to convey both ten and 20-digit caller identities (ANI
-- automatic number identification) used in North America
and other digit strings used elsewhere.
M4: Call transfer: Call takers MUST be able to transfer active
sessions to other call takers within the same ECC and to
other ECCs, even those not using Internet
M5: Conferencing: Occasionally, supervisors, translators or
other specialists need to participate in an emergency call.
Thus, it MUST be possible to add one or more parties, not
necessarily located in the IECC, to any emergency call at
any time.
M6: Monitoring and recording: In many jurisdictions, both sides
of all emergency calls are automatically recorded as
potential legal evidence. Thus, it MUST be possible to
record and timestamp all signaling and media from all
successful, failed and aborted calls.
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M7: Transition to end-to-end: Protocols and architecture SHOULD
be chosen so that a last-mile IECC can receive emergency
calls placed by IP endpoints without major system changes
or hardware upgrades.
M8: Authentication of incoming calls: The IECC MUST be able to
ascertain that the calls it receives are indeed originating
from the selective router.
M9: Authentication of the IECC: The selective router MUST be
able to be assured that the calls it places reach the
desired IECC rather than an impostor.
M10: Confidentiality: Call signaling and media streams MUST be
protected against unauthorized disclosure to third parties.
M11: Robustness: An IECC SHOULD be able to automatically route
all incoming calls to another backup IECC, even if the
access link(s) to the primary IECC are inoperative. Any
such redirection MUST be authenticated.
M12: Overflow handling: An IECC SHOULD be able to automatically
route calls to another IECC if the (expected) waiting time
exceeds a configured threshold.
5 End-to-End IP-Based Emergency Calls
End-to-end emergency calls originate on an Internet device, traverse
IP networks and terminate on an IP-capable ECC (IECC).
As noted, emergency calls need to be identified as such (Section 5.1)
and be routed to the appropriate emergency call center (Section 5.2).
The ECC needs to determine who (Section 5.3) placed the call from
where (Section 5.4). Emergency calls may not be subject to access
restrictions placed on non-emergency calls. Also, some call features
may interfere with emergency calls, particularly if triggerd
accidentally (Section 6).
5.1 Emergency Address
The emergency address is used by the emergency caller to declare a
call to be an emergency call and to guide the call to an ECC. The
emergency address could a be "sip", "sips" or "tel" URI, or some
other, yet-to-be-defined URI scheme.
A1: Universal: Each device and all network elements MUST
recognize one or more global emergency call identifiers,
regardless of the location of the device, the service
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provider used (if any) or other factors.
SIP is not specific to one country or service provider
and devices are likely to be used across national or
service provider boundaries. Since services such as
disabling mandatory authentication for emergency calls
(S1) requires the cooperation of outbound proxies, the
outbound proxy has to be able to recognize the
emergency address and be assured that it will be
routed as an emergency call. Thus, a simple
declaration on a random URI that it is an emergency
call will likely lead to fraud and possibly attacks on
the network infrastructure. A universal address also
makes it possible to create user interface elements
that are correctly configured without user
intervention. UA features could be made to work
without such an identifier, but the user interface
would then have to provide an unambiguous way to
declare a particular call an emergency call.
A2: Local: Since many countries have already deployed national
emergency numbers, such as 911 in North America and 112 in
large parts of Europe, UAs, proxies and call routers MUST
recognize local emergency numbers. In addition, they SHOULD
recognize emergency numbers that are found elsewhere.
The latter requirement is meant to help travelers that
may not know the local emergency number and
instinctively dial the number they are used to from
home. However, it is unlikely that all systems could
be programmed to recognize any emergency number used
anywhere as some of these numbers are used for non-
emergency purposes, in particular extensions and
service numbers.
A3: Recognizable: Emergency calls MUST be recognizable by user
agents, proxies and other network elements. To prevent
fraud, an address identified as an emergency number for
call features or authentication override MUST also cause
routing to an ECC.
A5: Minimal configuration: Any local emergency numbers SHOULD be
configured automatically, without user intervention.
A new UA "unofficially imported" into an organization
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from elsewhere should have the same emergency
capabilities as one officially installed.
A6: Secure configuration: Devices SHOULD be assured of the
correctness of the local emergency numbers that are
automatically configured.
If we assume a fixed, global emergency service
identifier that requires no configuration and only
configure local "traditional" emergency numbers, users
are not likely to suddenly dial some random number if
a rogue configuration server introduces this as an
additional emergency number. The ability to override
all locally configured emergency number is of more
concern.
A7: Testable: A user SHOULD be able to test whether a particular
address reaches emergency help, without actually causing
emergency help to be dispatched or consuming ECC call taker
resources.
5.2 Identifying the Appropriate Emergency Call Center
From the previous section, we take the requirement of a single (or
small number of) emergency addresses which are independent of the
caller's location. However, since for reasons of robustness,
jurisdiction and local knowledge, ECCs only serve a small region,
having the call reach the correct ECC is crucial. While an ECC may be
able to transfer an errant call, any such transfer is likely to add
tens of seconds to call setup latency and is prone to errors. (In the
United States, there are about 5,000 PSAPs.)
There appear to be two basic architectures for translating an
emergency address into the correct IECC. We refer to these as
caller-based and mediated. In caller-based resolution, the caller's
UA consults a directory and determines the correct IECC based on its
location. For mediated resolution, a SIP (outbound) proxy or redirect
server performs this function. Note that the latter case includes the
architecture where the call is effectively routed to a copy of the
database, rather than having some non-SIP protocol query the
database. (It appears undesirable to have either the UA or every
outbound proxy server contain a copy of the location-to-ECC mapping
since this table changes frequently.)
The problem is harder than for traditional web or email services.
There, the originator knows which entity it wants to reach,
identified by the email address or HTTP URL. However, the emergency
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caller only dialed an emergency address. Depending on the location,
any of several ten thousand destinations could be valid. In addition,
the caller probably does not care which specific ECC answers the
call, but rather that it be an accredited ECC, e.g., one run by the
local government authorities. (Many ECCs are run by private entities.
For example, universities and corporations with large campuses often
have their own emergency response centers.)
I1: Correct IECC: The system MUST reach the correct IECC
regardless of the location of the caller. In particular,
the location determination should not be fooled by the
location of IP telephony gateways or dial-in lines into a
corporate LAN (and dispatch emergency help to the gateway
or campus, rather than the caller), multi-site LANs and
similar arrangements.
I2: Choice of IECCs: The system SHOULD offer the emergency
caller a choice as to whether he wants to reach a local
private emergency response center, e.g., on a corporate
campus, or the government-run emergency call center
responsible for his current location.
This choice is often, but not always, provided today.
For example, in some cases, the local campus emergency
center is reachable by a different number or 9-911
reaches the external ECC, while 911 reaches campus
security.
I3: Assuring IECC identity: The emergency caller SHOULD be able
to determine conclusively that he has reached an accredited
emergency call center.
This requirement is meant to address the threat that a
rogue, possibly criminal, entity pretends to accept
emergency calls.
Implementations SHOULD allow callers to proceed, with
appropriate warnings or user confirmations, if the identity
of the destination IECC cannot be verified.
Verification can fail for any number of reasons, such
as lack of a common certificate chain, especially when
traveling, call forwarding, or the expiration of
certificates. Accreditation, e.g., in the case of
corporate or university campuses, may not exist.
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I4: Traceable resolution: Particularly for mediated resolution,
the caller SHOULD be able to definitively and securely
determine who provided the resolution answer.
I5: Assuring directory identity: The querier (UA or server) MUST
be able to assure that it is querying the intended
directory.
I6: Query response integrity: The querier MUST be able to be
confident that the query or response has not been tampered
with.
I7: Assuring update integrity: Any update mechanism for the
directory MUST ensure that only authorized users can change
directory information. An audit trail MUST be provided.
I8: Call setup latency: The directory lookup SHOULD add minimal
delay to the call setup. Since outbound proxies will likely
be asked to resolve the same geographic coordinates
repeatedly, a suitable time-limited caching mechanism
SHOULD be supported (see also "Ix").
I9: Multiple directories: A UA or proxy SHOULD be able to use
multiple different directories to resolve the emergency
address. We do not assume that a single directory has
worldwide or even nationwide coverage.
This allows competing or regional data sources.
I10: Referral: All directories SHOULD refer out-of-area queries
to an appropriate default or region-specific directory.
This requirement alleviates the potential for
misconfigurations to cause calls to fail, particularly
for caller-based queries.
I9: Multiple protocols: It MAY be useful if directories support
multiple query protocols, such as SIP (for proxying), LDAP,
a SOAP-based query and others. A mandatory-to-implement
protocol
It appears likely that the resolution mechanism will
be needed by a variety of session protocols and user
applications.
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I11: Robustness: The resolution mechanism MUST allow to deploy
systems that are robust in the face of partial network and
directory server failures. Caching MAY be used to mitigate
temporary unavailability of directories or network
connectivity.
I12: Incrementally deployable: An Internet-based emergency call
system MUST be able to deployed incrementally. In the
initial stages of deployment, an emergency call may not
reach the optimal ECC.
5.3 Identifying the Caller
Enhanced emergency call systems provide the ECC with the identity and
location of the caller. In PSTN-based systems, the identity is
represented by the number of the terminal the call is placed from. In
a SIP-based system, we have two distinct identities, namely the
address of the terminal (Contact header field) and the identity (name
and/or AOR) of the person using the terminal. Depending on the
circumstances, only one of them may be available. For example, from a
public terminal ("Internet payphone"), only the Contact address may
be useful.
In most jurisdictions, callers do not have a choice as to whether
they want to reveal their location or identity; such disclosure is
typically mandated by law. Emergency numbers are generally not meant
for anonymous tips. [TBD: Are there any exceptions?]
C1: Identity: The system SHOULD allow to identify both the
caller's identity and his or her terminal address.
C2: Privacy override: The end system MUST be able to
automatically detect that a call is an emergency call so
that it can override any privacy settings that conflict
with emergency calling. (Whether this override can be
configured by the user or is considered a condition of
service is considered a legal matter, not a protocol
issue.)
Since emergency calls are often placed by children, by
people using somebody else's end system or by people
in panic, any configuration should be automated rather
than relying on user interaction at the time of the
call. Delaying a call until the user discovers that
they have to answer some screen prompt or deal with a
voice prompt in an unfamiliar language is likely to
lead to large call setup delays or call failures. This
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does not preclude that end systems can allow, on a
call-by-call basis, to configure special call
parameters.
5.4 Identifying the Caller Location
This section supplements the requirements outlined in [2]. Thus, the
requirements enumerated there are not repeated here. In general, we
can distinguish two modes of operation: direct and indirect location
provision. In direct location provision, the calling end system knows
its own location and can convey this location to the ECC. In an
indirect system, the caller is identified by a permanent or temporary
identifier, which the ECC then uses to map the caller to a current
location. (In the current North American enhanced emergency calling
system, the landline terminal phone number is mapped to a location
using the so-called ALI database. For wireless phones, a temporary
identifier is created and then mapped to the location information.)
(This is somewhat similar to terminal-based and network-based
location services in wireless "911' services. However, even in direct
location provision, the terminal may well acquire the location
information from a third party, e.g., a wireless location beacon or a
DHCP server.)
L1: Multiple location providers: For indirect locations, ECCs
MUST be able to access different location providers. The
location provider may be tied to the service provider or
may be independent of the service provider.
This requirement avoids that all users have to rely on
a single location provider. This requirement is hard
to avoid if there are no traditional national
application-layer service providers.
L2: Civil and geographic: Where possible, both civil (street
address) and geographic (longitude/latitude) information
SHOULD be provided.
While geographic information can usually be translated
into civil coordinates, some coordinates, such as
building numbers and floors, are more easily provided
as civil coordinates since they do not require a
detailed surveying operation. For direct location
determination, it may also be easier for the user to
check civil coordinates for correctness.
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6 Call Setup and Call Features
S1: Authentication override: In many jurisdictions, emergency
calls can be placed by any device, regardless of whether it
has subscribed for service. Similarly, outbound proxies and
other call filtering elements MUST be able to be configured
so that they allow unauthenticated emergency calls.
S2: Mid-call features: The end system MUST be able to recognize
an emergency call and allow configuration so that certain
call features are not triggered accidentally. For example,
it may be inappropriate to transfer the ECC or put it on
hold. An end system MAY make it more difficult to
disconnect an on-going emergency call or accept other
incoming calls while in an emergency call.
Call transfer initiated by the emergency caller is
likely only to be a problem if a PSTN gateway or B2BUa
is in the call path. It is not clear how much effort
should be expended on preventing intentional, as
opposed to accidental, disconnection, since callers
can typically find physical-layer means to terminate
the call.
S3: Testable: Users SHOULD be able to test the ability to place
an emergency call without actually invoking an emergency
response.
This capability is unfortunately missing from the
current PSTN.
7 Security Considerations
Confidentiality, integrity and authentication are core requirements
for multiple aspects of emergency calling. Threats exist at the
infrastructure and individual call level. Security threats are
identified throughout this document.
An adversary could corrupt call information or ECC resolution to
cause emergency calls to fail subtly, without the caller necessarily
noticing. This can be done on a call-by-call basis or by corrupting
elements that perform the resolution, including the directory
described in Section 5.2, Internet routing tables or DNS.
(Obviously, there are typically other ways to make emergency calls
fail completely, an approach phone-wire cutting burglars have
practiced for years. However, the ability to spoof an ECC requires
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physical access to the PSTN cable plant, while this may not be
required in the IP case.)
Here, we do not consider attacks on the emergency call infrastructure
itself. The techniques for dealing with such attacks are likely to be
similar as those for protecting other network infrastructure,
although the stakes may well be higher.
8 References
9 Normative References
[1] S. Bradner, "Key words for use in rfcs to indicate requirement
levels," RFC 2119, Internet Engineering Task Force, Mar. 1997.
[2] J. Cuellar, J. Morris, and D. Mulligan, "Geopriv requirements,"
internet draft, Internet Engineering Task Force, Jan. 2003. Work in
progress.
10 Informative References
[3] N. Charlton, M. Gasson, G. Gybels, M. Spanner, and A. van Wijk,
"User requirements for the session initiation protocol (SIP) in
support of deaf, hard of hearing and speech-impaired individuals,"
RFC 3351, Internet Engineering Task Force, Aug. 2002.
[4] H. C. Folts, C. Beard, and K. Carlberg, "Requirements for
emergency telecommunication capabilities in the Internet," internet
draft, Internet Engineering Task Force, Oct. 2002. Work in progress.
11 Acknowledgments
Your name here.
12 Authors' Addresses
Henning Schulzrinne
Dept. of Computer Science
Columbia University
1214 Amsterdam Avenue
New York, NY 10027
USA
electronic mail: schulzrinne@cs.columbia.edu
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Table of Contents
1 Conventions used in this document ................... 2
2 Introduction ........................................ 2
3 Definitions ......................................... 2
4 Last-Mile Access .................................... 3
5 End-to-End IP-Based Emergency Calls ................. 5
5.1 Emergency Address ................................... 5
5.2 Identifying the Appropriate Emergency Call Center
................................................................ 7
5.3 Identifying the Caller .............................. 10
5.4 Identifying the Caller Location ..................... 11
6 Call Setup and Call Features ........................ 12
7 Security Considerations ............................. 12
8 References .......................................... 13
9 Normative References ................................ 13
10 Informative References .............................. 13
11 Acknowledgments ..................................... 13
12 Authors' Addresses .................................. 13
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