One document matched: draft-pierce-ieprep-assured-service-req-00.txt
Internet Engineering Task Force Mike Pierce
Internet Draft Artel
draft-pierce-ieprep-assured-service-req-00.txt Don Choi
October 2002 DISA
Expires April 2003
Requirements for Assured Service Capabilities in Voice over IP
draft-pierce-ieprep-assured-service-req-00.txt
Status of this memo
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of RFC2026.
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Copyright
Copyright (C) Internet Society 2002. All rights reserved.
Reproduction or translation of the complete document, but not of
extracts, including this notice, is freely permitted.
Abstract
Assured Service refers to the set of capabilities used to ensure
that mission critical communications are setup and remain connected.
This memo describes the requirements for such capabilities in
support of specific networks such as those used by the US military
and government.
Table of Contents
0. Changes............................................................2
1. Introduction.......................................................3
2. Background.........................................................4
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3. High Level Requirements............................................5
4. Functional Requirements............................................5
4.1. Precedence Level Marking.......................................5
4.2. Authentication/Authorization...................................6
4.3. Preferential Treatment.........................................6
4.4. Diversion if Not Answered......................................7
4.5. Notifications to Preempted Party...............................7
4.6. Acknowledge by Preempted Party.................................7
4.7. Protection of Signaling Information from Disclosure............7
4.8. Accounting.....................................................7
4.9. Call Control Signaling Precedence..............................8
4.10. Interworking...................................................8
5. Current Situation..................................................8
5.1. IPv4...........................................................8
5.2. DiffServ.......................................................8
5.3. IntServ/RSVP...................................................9
5.4. MPLS...........................................................9
5.5. SIP............................................................9
6. Possible Approaches...............................................10
6.1. Precedence Level Marking......................................10
6.2. Authentication/Authorization..................................11
6.2.1. Architecture..............................................11
6.2.2. Authentication Procedures.................................12
6.2.3. Authorization Procedures..................................12
6.3. Preferential Treatment........................................12
6.4. Diversion if Not Answered.....................................13
6.5. Notification to Preempted Party...............................13
6.6. Acknowledge by Preempted Party................................13
6.7. Protection of Signaling Information from Disclosure...........13
6.8. Accounting....................................................13
6.9. Call Control Signaling Precedence.............................14
6.10. Interworking..................................................14
7. Security Considerations...........................................15
7.1. Authentication/authorization of User Access...................15
7.2. Security of Signaling Information.............................15
7.3. Security of Routing Data......................................16
8. IANA Considerations...............................................16
9. References........................................................16
10. Authors' Addresses................................................17
0. Changes
This draft was originally submitted under SIPPING. This revision is
being resubmitted to IEPREP in order to ensure that the Assured
Service requirements are considered along with those of the related
IEPS discussions
(SIPPING) 00 Original draft
(SIPPING) 01 Indicated informative material which would not be a
part of final. Moved some to Annex.
(SIPPING) 02 Removed material to draft-pierce-sipping-pref-treat-
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examples-00 and draft-pierce-sipping-assured-service-arch-00.
Added requirement to maintain records of use of service.
(IEPREP) 00
. Updated references.
. Added additional requirements related to preferential treatment
in 4.3.
. Added requirement in 4.8 for accounting records.
. Added requirement in 4.9 that preferential treatment must be
applied to call control signaling as well as to voice packets.
. Added requirement in 4.10 for interworking between Assured
Service and other priority schemes (e.g., IEPS)
1. Introduction
Throughout many decades of evolution of the telephony network and
its supporting protocols, there has been a need to provide special
services to a limited subset of the users and calls within a network
or domain in order to ensure completion of important calls. Examples
of this need have been in support of emergency traffic for natural
disasters, network restoration traffic, and high priority traffic in
a military network. Provision of the required capabilities with the
signaling protocols and within the switching systems has been
defined in a number of national and international standards, most
notably a service referred to as Multi-Level Precedence and
Preemption as defined in an American National Standard [T1.619] in
the US and in corresponding ITU-T Recommendations [I.255.3, Q.735.3,
and Q.955.3]. In addition, a service called High Probability of
Completion (HPC) was defined in [T1.631] and, most recently, two
ITU-T Recommendations define the requirements for the International
Emergency Preference Scheme (IEPS) [E.106] and the International
Emergency Multimedia Service (IEMS) [F.706].
Other drafts submitted to the IETF have addressed aspects of IEPS.
Some of these are [Folts], which presents the functional
requirements for the Emergency Telecommunications Service (ETS); and
[Carlberg], which provides a framework for IEPS for telephony over
IP.
MLPP was the solution to providing Assured Service capabilities
within the circuit switched environment. It is essential that
equivalent Assured Service capabilities are defined and implemented
for the packet-based, connectionless environment of the Internet,
and specifically SIP. Without these capabilities, SIP can not be
used for those applications which require such capabilities, and is
less than optimal for many other uses.
This memo builds on these references and identifies the specific
requirements for Assured Service capabilities in support of these
specific types of environments. The term "Assured Service" is used
to refer to the required capabilities, rather than the previous term
of MLPP or the related but different IEPS, since the envisioned set
of capabilities and protocols to achieve them are not expected to be
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exactly the same as those other services.
Although these requirements are derived from previous military and
government applications, many of the same requirements and
capabilities may be applied for non-military or government networks,
for example, in support of commercial network restoration efforts. A
presentation in the TEWG during the August 2001 meeting demonstrated
real-life situations from the past in which total network failures
required extensive efforts, presumably including communication via
other unaffected networks, to bring the affected network back on
line. If one considered a situation in which the very network which
had failed was needed to carry the network management traffic
required to get it back on line, it would be hard to imagine how it
could ever be brought back up in the face of overwhelming customer
attempts. Capabilities would be required to give priority to the
network management traffic, even to the extent of blocking all non-
emergency traffic for a period of time.
2. Background
In the circuit switched environment, specific circuits or channels
were used for each call. These were typically 64 kbit/s channels
which were a part of a TDM transmission structure. Later
developments used packet/cell based transport instead of dedicated
64 kbit/s channels, however, the effect was the same. There was
still a dedicated transport capacity assigned for each call.
Assured Service in the circuit switched environment may be provided
by one or more of the following techniques. Note that the
capabilities included within IEPS [E.106], are included here for
reference but not dealt with further in this memo. They are further
dealt with in [Folts]:
- Giving priority to return of dial tone (IEPS).
- Marking of signaling messages for better handling, for example,
being last to be dropped in case of congestion in the signaling
network (HPC).
- Extra routing possibilities for higher priority calls. (IEPS)
- Exemption from restrictive management controls (IEPS) such as
hard-to-reach codes and code gapping.
- Reservation of specific facilities (trunks) for higher priority
traffic (IEPS).
- Higher priority calls may preempt existing lower priority calls,
causing the network to release the lower priority call to free
up resources for immediate reuse by the higher priority call
(MLPP).
Identification of traffic authorized to use one or more of these
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techniques may be via the following methods:
- Calls placed from physical lines or devices authorized for its
use
- Calls placed to specific telephone numbers or blocks of numbers
- Entry of a special ID code and PIN from any telephone device
3. High Level Requirements
While the existing requirements and capabilities have been developed
with the circuit switched environment in mind, many are directly
applicable to the packet environment and specifically the Voice over
IP application being defined using SIP. Some of the capabilities
need to be adapted or modified for application in the packet mode
environment. In addition, there will likely be new techniques which
can be defined specifically for the SIP case.
At a high level, the Assured Service requirements can be stated as
the need to ensure that mission critical voice-mode calls get set up
and remain connected.
(While this draft focuses on Voice over IP, there should be a
consideration of the impact/solutions for other media flows which
carry mission critical communication, for example, video and instant
messaging. Most of the following requirements can be equally applied
to these other media.)
4. Functional Requirements
The functional requirements for Assured Service being detailed here
are specifically those needed to support the US government
requirements, primarily for the military environment. This memo
concentrates on those portions mentioned in Section 2 which are
derived from the requirements for MLPP as defined in [T1.619].
Many of these requirements are the same as, or very similar to,
those of the IEPREP work as described in [Baker].
The basic requirements can be defined as follows;
4.1. Precedence Level Marking
It must be possible for the originator to select and signal one of
five precedence levels for a call, with the call defaulting to the
lowest if none is specified. It must be possible to carry this call
associated precedence level though the IP network. It must be
possible to deliver the originally signaled precedence level to the
called party.
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4.2. Authentication/Authorization
It must be possible to verify that the calling party is authorized
to use the Assured Service and the requested precedence level value
and to take the appropriate action if the calling party attempts to
use a higher level. The preferred action is to reject the call, and
send an indication of the reason to the caller.
4.3. Preferential Treatment
It must be possible to provide preferential treatment to higher
precedence calls in relation to lower precedence calls. Examples of
preferential treatments are:
- reservation of network resources for precedence calls
- usage of higher Call Acceptance limits for higher precedence
calls
- preferential queuing of signaling messages based on precedence
level
- preferential queuing of user data packets based on precedence
level
- discarding of packets of lower precedence call
- preemption of one or more existing calls of lower precedence
level
- preemption of some of the resources being used by a call of
lower precedence level
- preemption of the reservation of resources being held for other
traffic
The provision of preferential treatment must be in place before the
need to use it occurs. That is, initiation of the appropriate
measures must not require manual intervention or configuration of
network entities, for example, establishment of dedicated bandwidth
for high priority traffic. It is not desirable for preferential
treatment to be provided through any scheme of dedicated or pre-
reserved bandwidth or resources. In those cases in which such
dedicated bandwidth or resources for a higher priority level must be
used, when such dedicated or pre-reserved bandwidth or resources
have been consumed by the high priority traffic, further traffic of
that same high priority must be provided the same treatment as the
next lower priority level.
Possible methods of providing Preferential Treatment using the
provisions of this memo, as well as other existing IETF protocols,
are described in [Pierce1].
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4.4. Diversion if Not Answered
If a precedence call (one higher that the lowest level) does not
answer within a designated time or the called party is busy with a
call of equal or higher precedence such that an indication of the
new call can not be given to the intended called party, the call
must be diverted to a predetermined alternate party. In general,
this must operate similar to a normal "Call Forwarding on No Answer"
service.
4.5. Notifications to Preempted Party
All preempted parties must be provided with a distinct notification
informing them that their call has been preempted.
4.6. Acknowledge by Preempted Party
When an existing call is preempted for delivery of a higher
precedence call to the same party, after the party is notified that
a new call is being presented, the party must acknowledge the
preemption before the new call is connected. That is, there must be
a positive acknowledgement before any audio information is
transferred in either direction.
4.7. Protection of Signaling Information from Disclosure
Although protection is not actually an integral part of the Assured
Service functionality, it is specifically identified here since this
capability is always required in those networks which are assumed to
be the primary users of Assured Service.
It is required that sensitive information not be made available to
non-secure portions of the network or to any non-secure network
through which the traffic passes. It is also important that it not
be accessible by users connected to the network. This non-disclosure
requirement especially applies to information which is used to
control link state routing protocols based on knowledge of the
current traffic load at each precedence level on each route.
Further, it is desirable that the precedence information regarding
each call (as well as the other information such as calling/called
party identity) be protected from disclosure to the greatest extent
possible.
4.8. Accounting
Proper administration of the Assured Service capability requires
that use of the service can be reviewed after the fact for potential
abuse. Therefore, it is required that appropriate records be kept of
calls made, including the calling and called parties' identity, time
of the call, and the precedence level used. This is similar to the
requirements for Call Detail Recording (CDR) for billing purposes
for other services in a commercial environment.
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4.9. Call Control Signaling Precedence
It is necessary to apply preferential treatment to the call control
signaling, since it competes for the same transport resources as the
voice packets. It is essential that:
- the call control signaling does not adversely affect the voice
(e.g., by introducing excessive packet delay variation due to
extremely long messages).
- the voice traffic does not significantly delay important call
control signaling (e.g., by preventing release messages from
getting through).
4.10. Interworking
Assured Service calls will need to interwork with other priority
schemes such as the one defined for IEPS []. This includes the
following two cases:
- both types of traffic may exist in a single network, for example,
an IEPS call may be originated from within a military network which
also supports "Assured Service" calls. Procedures to determine the
relative priority are required.
- a network which provides "Assured Service" needs to support
interworking of calls to and from a network which provides another
scheme such as IEPS. Mapping between the priority values must be
supported.
5. Current Situation
Current support for Assured Service within various IETF defined
protocols and ongoing initiatives is not considered to be
sufficient.
5.1. IPv4
Although support for the traditional five precedence levels was
included in the TOS field of IPv4 from the earliest days, support
for this field is not universal, and it only provides packet level
priority. It does not provide call setup priority or control of call
retention.
5.2. DiffServ
Within DiffServ, Assured Forwarding defined in RFC 2597 provides
four classes and three drop precedences for each class. One of these
classes could be used for the signaling messages for session
establishment and release. The multiple drop precedences could be
used for various signaling messages, as is being done with the
equivalent call control messages in ISUP for SS#7.
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Expedited Forwarding defined in RFC 3246 is intended for voice, but
it treats all such voice packets the same. It does not define
multiple drop precedences as AF does.
5.3. IntServ/RSVP
Although RSVP includes mention of preemption of existing
reservations in favor of other higher priority ones, it does not
provide detailed procedures for doing so. In principle, it should be
straightforward to do so. However, it is not believed that the
procedures required for establishment of a path using RSVP, and the
additional procedures that would be necessary for preemption of an
existing path, would allow this to be useful for the provision of
Assured Service capabilities to individual calls.
5.4. MPLS
Since MPLS is fundamentally a means to emulate circuit-mode
operation by establishment of a "path" which then functions like a
"connection", the principles of priority and preemption could be
applied to the setup and retention of this path the same as they are
in the circuit-mode environment. RFC 2702 describes the requirements
for such capabilities as applied to "traffic trunks". However, it
uses the term "traffic trunk" to refer to a facility which is
established to carry an aggregate of traffic, i.e., many telephone
calls. This is the equivalent of a "trunk group" in standard
telephony terminology [T1.523]. Because of the extensive procedures
that are required to establish and remove such a Label Switched
Path, it is believed that this prevents MPLS from being used to
setup paths for individual calls.
MPLS may be applicable for the establishment of the equivalent of
dedicated trunk groups between switching entities. Each of these
"trunk groups" or "traffic trunks" could exist to support a specific
precedence level of traffic between two points and could be setup
using the procedures defined in [RFC3212] or those in [RFC3209].
These documents allow the signaling of the required five levels of
precedence as well as separate setup and holding priorities.
5.5. SIP
SIP [RFC3261] defines four tokens for priority levels, however, they
are not intended to be used to control call setup nor do they equate
to the levels required for Assured Service.
The proposed Resource Priority Header [Polk] provides for the five
precedence levels required for per call marking.
Security is discussed in [RFC3261] and many drafts, but it has been
recognized in various Working Group discussions that security for
all aspects of call control needs to be considered in a unified
manner. Security for each individual component of call setup and
release can not be designed separately.
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The procedure being proposed for authorization of call set-up and
media allocation [SIP-CALL-AUTH] appears to be too time consuming to
expect it to occur each time a user attempts to place a telephone
call, especially a high-priority one. The probable delay in
establishing this authorization would be contrary to the goals and
requirements for Assured Service. Use of this type of procedure
would require that preferential treatments also be applied to all
message interactions and proxy processing of the sequence of
messages required for the authorization. Overloads of the proxies
responsible for the Call Authorization would prevent or unacceptably
delay setup of the high precedence call.
6. Possible Approaches
The following identify possible approaches to meeting the
requirements stated above. This section is included in the draft to
stimulate discussion on ways of meeting the requirements, but is not
expected to be included in the final version when it is advanced
toward RFC status.
6.1. Precedence Level Marking
The approaches to be used for precedence level marking are different
for each of the following cases:
A. Individual call setup:
There needs to be a definition of a field to be carried in SIP which
identifies the precedence levels of 0-4 of the call setup.
Currently, the US military uses five values which have specific
meanings (as currently defined in MLPP) and the standard may reflect
these meanings. However, it is preferable to provide easy support
for other network applications which utilize a different number of
levels or different meanings.
The specification may allow more than 5 levels. There is no need for
the 65k levels defined in [RFC2751] nor is there currently a
requirement to carry the separate preemption and defending
priorities of [RFC2751] or the separate setup and holding priorities
proposed in [RFC3212] and [RFC3209].
[Polk] is expected to result in a specification which satisfies this
requirement.
B. Packet forwarding:
To support preferential treatment on the packet transfer level, the
current lack of any priority mechanism within the single Expedited
Forwarding class of DiffServ will need additional capabilities to
provide the required functionality. Just as Assured Forwarding
includes multiple drop precedences for each class, there should be
multiple drop precedences for EF, which is intended for voice. In
fact, voice transport is more tolerable to dropped packets than many
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of the intended uses of AF classes.
(It should be emphasized again that such multiple "drop precedence"
levels for EF would not provide an actual priority forwarding
mechanisms per packet, e.g., priority queuing of some packets ahead
of other within that EF class, just as there is no such capability
included within the AF PHB definition.)
In order to provide the required preferential treatments for the
five call precedence levels, it is required to provide five
corresponding drop precedence levels for the voice packet handling.
C. Trunk group establishment:
For MPLS, RFC 2702 defines the idea of a "traffic trunk" for which a
priority may be signaled by the label distribution protocol in order
to establish telephony "trunk groups". If LDP is used for label
distribution, the priority defined in [RFC3212] should be used. If
RSVP is used for label distribution, the priority defined in
[RFC3209] should be used.
It should be noted that the traditional definition of a "trunk
group" does not include the notion of a "priority" associated with a
trunk group. The priority is only associated with individual calls
placed on that trunk group. It is possible that the routing logic
could reserve a trunk group for higher priority traffic, but this is
also not the normal application, since it wastes facilities during
periods when very little high priority traffic exists and it can not
support the heavier load of high priority traffic when conditions
cause such a high volume.
6.2. Authentication/Authorization
This draft uses the following definitions from draft-ietf-aaa-
transport-07:
- Authentication: The act of verifying a claimed identity, in the
form of a pre-existing label from a mutually known name space,
as the originator of a message (message authentication) or as
the end-point of a channel (entity authentication).
- Authorization: The act of determining if a particular right,
such as access to some resource, can be granted to the presenter
of a particular credential.
6.2.1. Architecture
In many other cases besides call setup for Assured Service it is
also necessary to perform authentication and authorization.
Appropriate security mechanisms have already been defined which may
be used.
Refer to [pierce2] for a discussion of the architecture required to
support the authentication/authorization requirements.
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6.2.2. Authentication Procedures
It is essential that a framework for security for SIP be established
that allows a security association to be established between a
user's terminal and their dedicated SIP proxy at the time of an
initial registration. This initial registration, which includes
authentication, may require an extensive number of messages and
interactions with numerous network elements, including a Policy
Server, and may require a rather large time as a password is
verified. This registration and authentication would normally be
done when a terminal is turned on, activated, or places the first
call. It is not performed for each call. This reduces the need to
apply preferential treatment procedures to the authentication
process.
For the purpose of Assured Service provision, as with other SIP-
based services, it is expected that Authentication may be performed
based on the entry of an ID and password or the use of terminal
resident biometrics (e.g., iris scan) so that permission to use the
services can be associated with an individual, not a device. Once
registration is done, this permission is then associated with the
device.
6.2.3. Authorization Procedures
Authorization per call must consist only of added fields/information
within the normal messages used for basic call setup as defined in
[RFC3261]. It should not require additional messages to be added to
the call setup sequence.
6.3. Preferential Treatment
The preferential treatments would not be standardized unless they
require signaling between network elements. Currently, most
treatments envisioned are local matters within a proxy or router.
Consideration of preferential treatments depends on the case:
A. Per call:
Preemption of existing calls, if done, would require coordination
between network elements, and therefore protocol standards,
especially if distinct actions are expected to reserve the preempted
resources for setup of the higher precedence call.
It is not expected that network initiated preemption of calls
(sessions) within the IP environment will be necessary. Instead,
sufficient preferential treatment can be provided by applying higher
call admission control limits and lower drop precedence procedures
to higher precedence calls. Examples of these procedures are shown
in [Pierce1].
B. Packet Level:
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Current capabilities of DiffServ, with additional code points for
drop precedences within the EF class, will provide the necessary
preferential treatments regarding voice packet transfer, including
indications of discard priority. It will also be necessary to define
new capabilities to provide the necessary preferential treatment for
call control signaling.
C. MPLS/RSVP Paths:
There should be no need for preemption of MPLS/RSVP established
traffic trunks (trunk groups) as described in [RFC2702] and
[RFC2205]. The required capability should be provided by mechanisms
to reduce the traffic engineering limits placed on lower priority
trunk groups (even by reducing to zero) to allow the capacity to be
used for the establishment of higher priority calls in other traffic
engineered traffic trunks.
6.4. Diversion if Not Answered
Diversion should be based on procedures that are developed for a
Call Forwarding on No Answer type service. However, it must not be
dependent on a timing performed by the original called party. It
must be the function of a proxy serving the called party as shown in
draft-ietf-sipping-service-examples-02.
6.5. Notification to Preempted Party
Notification to the preempted party should follow whatever is done
for notifications for any network-initiated release. Since it is
expected that actual call preemption will only be needed in the
circuit mode environment, the gateway between it and the IP
environment should deal with such preemption by application of the
required notification (in-band) to party on the IP side.
6.6. Acknowledge by Preempted Party
Acknowledge by the preempted party (before connection of a new call)
should follow the same general procedures as done for normal call
presentation, that is, the new call must be acknowledged (answered)
before any audio is transferred in either direction between end
users. (Note that this does not refer to the transfer of "media"
between the terminals, only the transfer of actual audio between the
persons using the terminals.)
6.7. Protection of Signaling Information from Disclosure
See Section 7.
6.8. Accounting
Call detail records (CDR) can be maintained by the proxy, since it
knows which users are authorized to place Assured Service calls and
knows when they do. Since not actually done to support billing
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functions, it is not expected that a record of call duration is
required.
6.9. Call Control Signaling Precedence
Adequate precedence (and preferential treatment) can be provided to
call control signaling, with respect to user data carried by EF, by
utilization of a single AF class (single queue) for all call control
signaling. A weighted queue serving algorithm is then required to
guarantee that this queue receives a minimum percentage of the
bandwidth of the outgoing facility, if it needs it, regardless of
the volume of "higher priority" packers (such as voice in an "EF"
queue). It is expected that this percentage for call control
signaling would be less than 5% of the total bandwidth.
To address the situation in which the signaling traffic exceeds the
minimum guaranteed and there is excessive traffic, thereby blocking
some call control messages, the multiple drop precedence capability
of AF must be available. Relative drop precedences for SIP messages
can be modeled on those use in ISUP.
In order to address the other side of the problem - preventing long
call control messages from adversely affecting the performance of
the voice packets - it may be necessary to utilize a packet
segmentation scheme.
6.10. Interworking
Interworking requirements can be met in the following manner:
Within a single network which supports two or more priority schemes,
the network operator will need to determine the relative priority
and preferential treatments to apply. For example, the operator may
decide that the IEPS priority for "Authorized Emergency" will fall
between the Assured Service levels of Immediate and Flash.
At the gateway between two networks which support two different
priority schemes, the operator of the gateway will need to determine
the mapping between the two schemes. For example, for the priority
schemes defined for Assured Service (in the Defense Switched Network
or DSN) and for IEPS [] (in the public network), the mapping could
be:
From DSN To public network
------------ ---------------------
Routine --> Normal
Priority --> Normal
Immediate --> Normal
Flash --> Authorized Emergency
Flash Override --> Authorized Emergency
and
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From Public network TO DSN
-------------------- -------
Normal --> Routine
Authorized Emergency --> Flash
7. Security Considerations
7.1. Authentication/authorization of User Access
Discussions within SIP continue to identify the need to
authenticate/authorize all access to capabilities, since virtually
any function could be misused, resulting in harm to the network or
to other users. Because Assured Service is intended to provide an
authorized user with better service than other users, including the
potential of actually preempting resources, it is even more
important to authenticate/authorize the user's access to the Assured
Service capabilities. However, the requirement definitely exists for
all cases, not just Assured Service, therefore the solution is not
unique to Assured Service.
[RFC3261] describes the use of a stateless challenged-based
mechanism for authentication in which a proxy server or user agent
may challenge the initiator of a request to provide assurance of
their identity. For real-time needs such as placing telephone calls,
especially those for which Assured Service capabilities are being
applied, such a challenge-based system will likely be too slow, or
would itself be hampered by the very network condition which
requires Assured Service to be applied. Pre-establishment of
security associations is required, in order to allow for the timely
exchange of security information needed to perform authentication/
authorization of individual actions.
7.2. Security of Signaling Information
The need to protect signaling information from disclosure is
independent from the provision of Assured Service. Military/
government networks have long been built on the premise that such
information needs to be protected. Bulk encryption of signaling
links (as well as the user data channels) between secure switches
provided much of this protection. In addition, the Signal Transfer
Points of the SS#7 network could be secured against unauthorized
access. It should be noted that commercial networks have recognized
the need for the same level of protection previously only applied to
military networks.
In the IP environment, the signaling packets as well as the user
data traverse many routers and could be accessed by unauthorized
persons at any one of them. While the contents of the individual
signaling messages could be hidden by encryption of the request and
response for end-to-end protection of information, the header must
be visible to intermediate routers. It is preferable to not require
decryption/ encryption at each router. The approach has been to
encrypt the contents of the signaling message but not the headers
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which are needed by the routers. However, the headers themselves may
contain sensitive information such as precedence level and called
party identification.
[RFC3261] describes the transport and network layer security methods
which may be used to protect signaling traffic.
7.3. Security of Routing Data
Of more concern than the information about an individual call is the
information normally needed by Link State routing logic used by an
originating device to select a route though an entire network. Such
a routing function requires knowledge of the state (busy or not) of
various portions of the network. When Assured Service based on
precedence levels is added, this requires that the routing point
also know the current loading of various precedence levels for each
portion of the network. Especially in a large network, this is
highly sensitive information and must not be revealed to
unauthorized network elements.
It should be noted that the constraint-based LSP setup proposed in
[RFC3212] depends on the routing point knowing this information.
8. IANA Considerations
It is not expected that there will be any IANA involvement in
support of Assured Service beyond what is described in [Polk].
9. References
[T1.523] ANSI T1.523-2001, "Telecommunications Glossary".
[T1.619] ANSI T1.619-1992 (R1999), "Multi-Level Precedence and
Preemption (MLPP) Service, ISDN Supplementary Service Description".
[T1.619a] ANSI T1.619a-1994 (R1999), "Addendum to MLPP".
[T1.631] ANSI T1.631-1993 (R1999), "Telecommunications - Signalling
System No. 7 (SS7) - High Probability of Completion (HPC) Network
Capability".
[E.106] ITU-T Recommendation E.106 (2000), "International Emergency
Preference Scheme (IEPS)".
[F.706] ITU-T Recommendation F.706 (draft), "International Emergency
Multimedia Service (IEMS)".
[I.255.3] ITU-T Recommendation I.255.3 (1990), "Multilevel
precedence and preemption service (MLPP)".
[Q.735.3] ITU-T Recommendation Q.735.3 (1993), "Description for
community of interest supplementary services using SS No. 7 -
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Multilevel precedence and preemption (MLPP)".
[Q.955.3] ITU-T Recommendation Q.955.3 (1993), "Description for
community of interest supplementary services using DSS1 - Multilevel
precedence and preemption (MLPP)".
[RFC2205] RFC 2205, "Resource ReSerVation Protocol (RSVP)",
September 1997
[RFC2597] RFC 2597, "Assured Forwarding PHB Group", June 1999.
[RFC3246] RFC 3246, "An Expedited Forwarding PHB", March 2002.
[RFC2702] RFC 2702, "Requirements for Traffic Engineering Over
MPLS", September 1999.
[RFC2751] RFC 2751, "Signaled Preemption Priority Policy Element",
January 2000.
[RFC3209] RFC 3209, "RSVP-TE: Extensions to RSVP for LSP Tunnels",
December 2001.
[RFC3212] RFC 3212, "CR-LDP: Constraint-based LSP Setup using LDP",
January 2002.
[SIP-CALL-AUTH] draft-ietf-sip-call-auth-05, "SIP Extension for
Media Authorization", May 2002. RFC ????
[RFC3261] RFC 3261, "SIP: Session Initiation Protocol", June 2002.
[Baker] draft-baker-ieprep-requirements-00, "IEPS Requirement
Statement", February 2002.
[Carlberg] draft-ietf-ieprep-framework-02, "Framework for Supporting
IEPS in IP Telephony", Ken Carlberg, June 2002.
[Folts] draft-folts-ieprep-requirements-00, "Requirements for
Emergency Telecommunication Capabilities in the Internet ", Hal
Folts, May 2002.
[Pierce1] draft-pierce-ieprep-pref-treat-examples-00, "Examples for
Provision of Preferential Treatment in Voice over IP", October 2002.
[Pierce2] draft-pierce-ieprep-assured-service-arch-00, "Architecture
for Assured Service Capabilities in Voice over IP", October 2002.
[Polk] draft-polk-sipping-resource-00, "SIP Communications Resource
Priority Header", February 2002.
10. Authors' Addresses
Michael Pierce
Artel
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1893 Preston White Drive
Reston, VA 20191
Phone: +1 410.817.4795
Email: pierce1m@ncr.disa.mil
Don Choi
DISA
5600 Columbia Pike
Falls Church, VA 22041-2717
Phone: +1 703.681.2312
Email: choid@ncr.disa.mil
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Mike Pierce Expires April 2003 [Page 18]
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