Internet DRAFT - draft-ivov-mmusic-multiple-sources
draft-ivov-mmusic-multiple-sources
Network Working Group E. Ivov
Internet-Draft Jitsi
Intended status: Standards Track July 15, 2013
Expires: January 16, 2014
Economical Use of the Offer/Answer Model in Sessions with Multiple Media
Sources
draft-ivov-mmusic-multiple-sources-00
Abstract
The Session Description Protocol (SDP) Offer/Answer model describes a
mechanism that allows two entities to negotiate a multimedia session.
The SDP syntax of the Offer/Answer model uses constructs known as
media (m=) lines to describe each medium. In SDP itself these "m="
lines were designed to describe RTP sessions with any number of
streams (SSRCs). Yet, Offer/Answer implementations in SIP
applications have most often used them as an envelope for a maximum
of two RTP streams (SSRCs) at a time: one in each direction. The
most common reason for this has been the fact these applications
could not meaningfully render multiple SSRCs simultaneously.
The above situation has led to difficulties once the need to
represent multiple (SSRCs) in an interoperable manner became more
common.
This document explores the use of "m=" lines for the negotiation of
sessions with multiple media sources, as per their original design in
SDP. It presents the advantages of such an approach as well as the
challenges that it implies in terms of interoperability with already
deployed legacy devices.
The model described here was first presented in the RTCWEB No Plan
proposal. The reason to spin it off into this new document is mainly
to separate the parts related to Offer/Answer and "m=" line
semantics, from those that are specific to WebRTC.
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/.
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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 January 16, 2014.
Copyright Notice
Copyright (c) 2013 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
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publication of this document. Please review these documents
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the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
2. Mechanism . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.1. Discovery . . . . . . . . . . . . . . . . . . . . . . . . 7
2.2. Advantages . . . . . . . . . . . . . . . . . . . . . . . 8
3. Additional Session Control and Signalling . . . . . . . . . . 8
4. Demultiplexing and Identifying Streams
(Use of Bundle) . . . . . . . . . . . . . . . . . . . . . . . 9
5. Simulcasting, FEC, Layering and RTX (Open Issue) . . . . . . 10
6. Problems with Plans A and B . . . . . . . . . . . . . . . . . 11
7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 12
8. Informative References . . . . . . . . . . . . . . . . . . . 13
Appendix A. Acknowledgements . . . . . . . . . . . . . . . . . . 14
Author's Address . . . . . . . . . . . . . . . . . . . . . . . . 15
1. Introduction
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Since its early days the Session Description Protocol (SDP) Offer/
Answer (O/A) model [RFC3264] has mainly been used for the negotiation
of Real-time Transport Protocol (RTP) [RFC3550] sessions between
endpoints that only use a single media source per medium. Examples
of such sources include microphones, cameras, desktop streamers etc.
The list can be extended to cases where multiple sources are mixed at
the media level by an audio or video mixer and then appear as a
single stream, i.e. RTP Synchronisation Source (SSRC) on the RTP and
SDP [RFC4566] levels.
In such sessions each medium and its corresponding device are
described by the SDP "m=" line construct and each media source is
mapped to exactly one "m=" line. The exchanges that lead to the
establishment of such sessions are relatively well covered by the
specifications and most implementations.
Unfortunately, the situation becomes relatively confusing when it
comes to transporting multiple media sources (SSRCs) per medium.
Streaming any number of RTP streams is an inherent part of the
protocol and describing such multi-stream RTP sessions is directly
supported by SDP. Still, the Offer/Answer model [RFC3264] is
relatively vague on the subject and relying on the multi-stream
capabilities of an SDP "m=" line is likely to lead to unexpected
results with most endpoints.
At the time of writing of this document, the MMUSIC working group is
considering two approaches to addressing the issue. The approaches
emerged in the RTCWEB working group and are often referred to as Plan
A [PlanA] and Plan B [PlanB]. Both of them impose semantics and
syntax that allow for detailed description and fine-grained control
of multiple media sources entirely through SDP and Offer/Answer.
Both plans A and B present a number of problems most of which are due
to the heavy reliance on SDP O/A. The problems are discussed in more
detail in Section 6.
The goal of this document is to propose an alternative approach that
simply uses "m=" lines in the way they were originally designed with
SDP: descriptors of RTP sessions with any number of sources. Such an
approach keeps the use of SDP Offer/Answer to the initialization of
transport and media chains and delegates stream control to other,
upper layer protocols.
The model described in this specification is intended for
applications that require reliability, flexibility and scalability.
It therefore tries to satisfy the following constraints
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o the addition and removal of media sources (e.g. conference
participants, multiple web cams or "slides" ) must be possible
without the need of Offer/Answer exchanges;
o the addition or removal of simulcast or layered streams must be
possible without the need for Offer/Answer exchanges beyond the
initial declaration of such capabilities for either direction.
o call establishment must not require preliminary announcement or
even knowledge of all potentially participating media sources;
o application specific signalling should be used to cover most
semantics following call establishment, such as adding, removing
or identifying SSRCs;
o straightforward interoperability with widely deployed legacy
endpoints with rudimentary support for Offer/Answer. This
includes devices that allow for one audio and potentially one
video m= line and that expect to only ever be required to render a
single RTP stream at a time for any of them. (Note that this does
NOT include devices that expect to see multiple "m=video" lines
for different SSRCs as they can hardly be viewed as "widely
deployed legacy").
To achieve the above requirements this specification expects that
endpoints will only use SDP Offer/Answer to establish transport
channels and initialize an RTP stack and codec/processing chains.
This also includes any renegotiation that requires the re-
initialisation of these chains. For example, adding VP8 to a session
that was setup with only H.264, would obviously still require an
Offer/Answer exchange.
All other session control and signalling are to be left to upper
layer protocol mechanisms.
2. Mechanism
The model presented in this specification relies on use of standard
SDP and Offer/Answer for negotiating formats, establishing transport
channels and exchanging, in a declarative way, media and transport
parameters that are then used for the initialization of the
corresponding stacks. It does not add new concepts and simply
requires applications to abide by the original design of SDP and the
"m=" line construct.
The following is an example presenting what this specification views
as a typical offer sent by a multistream endpoint following this
specification:
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v=0
o=- 0 0 IN IP4 198.51.100.33
s=
t=0 0
a=group:BUNDLE audio video // declaring BUNDLE Support
c=IN IP4 198.51.100.33
a=ice-ufrag:Qq8o/jZwknkmXpIh // initializing ICE
a=ice-pwd:gTMACiJcZv1xdPrjfbTHL5qo
a=ice-options:trickle
a=fingerprint:sha-1 // DTLS-SRTP keying
a4:b1:97:ab:c7:12:9b:02:12:b8:47:45:df:d8:3a:97:54:08:3f:16
m=audio 5000 RTP/SAVPF 96 0 8
a=mid:audio
a=rtcp-mux
a=rtpmap:96 opus/48000/2 // PT mappings
a=rtpmap:0 PCMU/8000
a=rtpmap:8 PCMA/8000
a=extmap:1 urn:ietf:params:rtp-hdrext:csrc-audio-level //5825 header
a=extmap:2 urn:ietf:params:rtp-hdrext:ssrc-audio-level //extensions
[ICE Candidates]
m=video 5002 RTP/SAVPF 97 98
a=mid:video
a=rtcp-mux
a=rtpmap:97 VP8/90000 // PT mappings and resolutions capabilities
a=imageattr:97 \
send [x=[480:16:800],y=[320:16:640],par=[1.2-1.3],q=0.6] \
[x=[176:8:208],y=[144:8:176],par=[1.2-1.3]] \
recv *
a=rtpmap:98 H264/90000
a=imageattr:98 send [x=800,y=640,sar=1.1,q=0.6] [x=480,y=320] \
recv [x=330,y=250]
a=extmap:3 urn:ietf:params:rtp-hdrext:fec-source-ssrc //5825 header
a=extmap:4 urn:ietf:params:rtp-hdrext:rtx-source-ssrc //extensions
a=max-send-ssrc:{*:1} // declaring maximum
a=max-recv-ssrc:{*:4} // number of SSRCs
[ICE Candidates]
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The answer to the offer above would have substantially the same
structure and content. For the sake of clarity:
v=0
o=- 0 0 IN IP4 203.0.113.12
s=
t=0 0
a=group:BUNDLE audio video // declaring BUNDLE Support
c=IN IP4 203.0.113.12
a=ice-ufrag:Qq8o/jZwknkmXpIh // initializing ICE
a=ice-pwd:gTMACiJcZv1xdPrjfbTHL5qo
a=ice-options:trickle
a=fingerprint:sha-1 // DTLS-SRTP keying
a4:b1:97:ab:c7:12:9b:02:12:b8:47:45:df:d8:3a:97:54:08:3f:16
m=audio 5000 RTP/SAVPF 96 0 8
a=mid:audio
a=rtcp-mux
a=rtpmap:96 opus/48000/2 // PT mappings
a=rtpmap:0 PCMU/8000
a=rtpmap:8 PCMA/8000
a=extmap:1 urn:ietf:params:rtp-hdrext:csrc-audio-level //5825 header
a=extmap:2 urn:ietf:params:rtp-hdrext:ssrc-audio-level //extensions
[ICE Candidates]
m=video 5002 RTP/SAVPF 97 98
a=mid:video
a=rtcp-mux
a=rtpmap:97 VP8/90000 // PT mappings and resolutions capabilities
a=imageattr:97 \
send [x=[480:16:800],y=[320:16:640],par=[1.2-1.3],q=0.6] \
[x=[176:8:208],y=[144:8:176],par=[1.2-1.3]] \
recv *
a=rtpmap:98 H264/90000
a=imageattr:98 send [x=800,y=640,sar=1.1,q=0.6] [x=480,y=320] \
recv [x=330,y=250]
a=extmap:3 urn:ietf:params:rtp-hdrext:fec-source-ssrc //5825 header
a=extmap:4 urn:ietf:params:rtp-hdrext:rtx-source-ssrc //extensions
a=max-send-ssrc:{*:4} // declaring maximum
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a=max-recv-ssrc:{*:4} // number of SSRCs
[ICE Candidates]
As already noted, the Offer/Answer exchange above remains essentially
the same regardless of whether the following media session is going
to contain one or multiple RTP streams (SSRCs) per medium in either
direction.
The exchange also has the following important characteristics:
o Preserves interoperability with most kinds of legacy endpoints.
o Allows the negotiation of most parameters that concern the media/
RTP stack (typically the browser).
o Only a single Offer/Answer exchange is required for session
establishment and, in most cases, for the entire duration of a
session.
o Leaves complete freedom to applications as to the way that they
are going to signal any other information such as SSRC
identification information or the addition or removal of RTP
streams.
2.1. Discovery
It is important that an implementation using "m=" lines as an
envelope for multiple RTP media streams, be able to reliably detect
whether its peer is capable of receiving them. One way of achieving
this would be the use of upper-layer protocols as explained in
Section 3.
In cases where endpoints need to be able to detect this from the SDP
Offer/Answer they could use the "max-send-ssrc" and "max-recv-ssrc"
attributes defined in [MAX-SSRC]. It has to be noted however that
this mechanism is still a work in progress and as such it would still
need to be extended to provide ways of distinguishing between
independent flows and complementary ones such as layered FEC and RTX.
Unless an endpoint detects the corresponding max-ssrc or upper level
protocol indicators that a remote peer can actually handle multiple
streams within a single "m=" line, it MUST assume that such support
is unavailable.
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2.2. Advantages
The advantages of using "m=" lines to represent multiple media
sources in the way they were originally intended by SDP can be
roughly summarized to the follwoing:
o It works. Existing implementations are already successfully using
the approach.
o No Offer/Answer when adding/removing streams. Improves
flexibility for applications allowing them to only signal
information that they really need to.
o No added glare risk. Improves scalability and reliability.
o No need to pre-announce SSRCs. Improves scalability.
o Allows apps to choose fine-tuned signalling: Custom, XCON,
RFC4575, WebRTC JavaScript, CLUE channels, or even Plan A and Plan
B.
Combined, the above set of characteristics allow for a multi-stream
management method that gives scalability, flexibility and
reliability.
3. Additional Session Control and Signalling
o Adding and removing RTP streams to an existing session.
o Accepting and refusing some of them.
o Identifying SSRCs and obtaining additional metadata for them (e.g.
the user corresponding to a specific SSRC).
o Requesting that additional SSRCs be added.
o Requesting that specific processing be applied on some SSRCs.
Support for any subset of the above semantics is highly dependent on
the use cases and applications where they are employed. The position
of this specification is that they should therefore be left to
protocols that target more specific scenarios. There are numerous
existing or emerging solutions, some of them developed by the IETF,
that already cover this. This includes CLUE channels [CLUE], the SIP
Event Package For Conference State [RFC4575] and its XMPP variant
[COIN], as well as the protocols defined within the Centralised
Conferencing IETF working group [XCON]. Additional mechanisms are
very likely to emerge in the future as various applications address
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specific use cases, scenarios and topologies. Examples for this
could be WebRTC JavaScript applications using proprietary JSON
descriptors, XMPP clients with new XML schemas and many others.
The most important part of this specification is hence to prevent
certain assumptions or topologies from being imposed on applications.
One example of this is the need to know and include in the Offer/
Answer exchange, all the SSRCs that can show up in a session. This
can be particularly problematic for scenarios that involve endpoints
with varying constraints.
Large scale conference calls, potentially federated through RTP
translator-like bridges, would be another problematic scenario.
Being able to always pre-announce SSRCs in such situations could of
course be made to work but it would come at a price. It would either
require a very high number of Offer/Answer updates that propagate the
information through the entire topology, or use of tricks such as
pre-allocating a range of "fake" SSRCs, announcing them to
participants and then overwriting the actual SSRCs with them.
Depending on the scenario both options could prove inappropriate or
inefficient while some applications may not even need such
information. Others could be retrieving it through simplistic means
such as access to a centralized resource (e.g. an URL pointing to a
JSON description of the conference).
4. Demultiplexing and Identifying Streams (Use of Bundle)
For reasons of optimising traversal of Network Address Translation
(NAT) gateways, it is likely for endpoints to use [BUNDLE]. This
implies that all RTP streams would in many cases end up being
received on the same port. A demuxing mechanism is therefore
necessary in order for these packets to then be fed into the
appropriate processing chain (i.e. matched to an "m=" line).
Note: it is important to distinguish between the demultiplexing
and the identification of incoming flows. Throughout this
specification the former is used to refer to the process of
choosing selecting a depacketizing/decoding/processing chain to
feed incoming packets to. Such decisions depend solely on the
format that is used to encode the content of incoming packets.
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The above is not to be confused with the process of making
rendering decision about a processed flow. Such decisions include
showing a "current speaker" flow at a specific location, window or
video tag, while choosing a different one for a second, "slides"
flow. Another example would be the possibility to attach "Alice",
"Bob" and "Carol" labels on top of the appropriate UI components.
This specification leaves such rendering choices entirely to
application-specific signalling as described in Section 3.
This specification uses demuxing based on RTP payload types. When
creating offers and answers applications MUST therefore allocate RTP
payload types only once per bundle group. In cases where rtcp-mux is
in use this would mean a maximum of 96 payload types per bundle
[RFC5761]. It has been pointed out that some legacy devices may have
unpredictable behaviour with payload types that are outside the
96-127 range reserved by [RFC3551] for dynamic use. Some
applications or implementations may therefore choose not to use
values outside this range. Whatever the reason, offerers that find
they need more than the available payload type numbers, will simply
need to either use a second bundle group or not use BUNDLE at all
(which in the case of a single audio and a single video "m=" line
amounts to roughly the same thing). This would also imply building a
dynamic table, mapping SSRCs to PTs and m= lines, in order to then
also allow for RTCP demuxing.
While not desirable, the implications of such a decision would be
relatively limited. Use of trickle ICE [TRICKLE-ICE] is going to
lessen the impact on call establishment latency. Also, the fact that
this would only occur in a limited number of cases makes it unlikely
to have a significant effect on port consumption.
An additional requirement that has been expressed toward demuxing is
the ability to assign incoming packets with the same payload type to
different processing chains depending on their SSRCs. A possible
example for this is a scenario where two video streams are being
rendered on different video screens that each have their own decoding
hardware.
While the above may appear as a demuxing and a decoding related
problem it is really mostly a rendering policy specific to an
application. As such it should be handled by app. specific
signalling that could involve custom-formatted, per-SSRC information
that accompanies SDP offers and answers.
5. Simulcasting, FEC, Layering and RTX (Open Issue)
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Repair flows such as layering, FEC, RTX and to some extent
simulcasting, present an interesting challenge, which is why they are
considered an open issue by this specification.
On the one hand they are transport utilities that need to be
understood, supported and used by the level of the media libraries in
a way that is mostly transparent to applications. On the other, some
applications may need to be made aware of them and given the option
to control their use. This could be necessary in cases where their
use needs to be signalled to endpoints through application-specific
non-SDP mechanisms. Another example is the possibility for an
application to choose to disable some or all repair flows because it
has been made aware by application-specific signalling that they are
temporarily not being used/rendered by the remote end (e.g. because
it is only displaying a thumbnail or because a corresponding video
tag is not currently visible).
One way of handling such flows would be to advertise them in the way
suggested by [RFC5956] and to then control them through application
specific signalling. This options has the merit of already existing
but it also implies the pre-announcement and propagation of SSRCs and
the bloated signalling that this incurs. Also, relying solely on
Offer/Answer here would expose an offerer to the typical race
condition of repair SSRCs arriving before the answer and the
processing ambiguity that this would imply.
Another approach could be a combination of RTCP and RTP header
extensions [RFC5285] in a way similar to the one employed by the
Rapid Synchronisation of RTP Flows [RFC6051]. While such a mechanism
is not currently defined by the IETF, specifying it could be
relatively straightforward:
Every packet belonging to a repair flow could carry an RTP header
extension [RFC5285] that points to the source stream (or source layer
in case of layered mechanisms).
Again, these are just some possibilities. Different mechanisms may
and probably will require different extensions or signalling
([SRCNAME] will likely be an option for some). In some cases, where
layering information is provided by the codec, an extensions is not
going to be necessary at all.
In cases where FEC or simulcast relations are not immediately needed
by the recipient, this information could also be delayed until the
reception of the first RTCP packet.
6. Problems with Plans A and B
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As already mentioned both Plans A and B heavily rely on SDP and Offer
/Answer for advanced stream control. They both require Offer/Answer
exchanges in a number of situations where this could be avoided,
particularly when adding or removing media sources to a session.
This requirement applies equally to cases where a client adds the
stream of a newly activated web cam, a simulcast flow or upon the
arrival or departure of a conference participant.
Plan A handles such notifications with the addition or removal of
independent m= lines [PlanA], while Plan B relies on the use of
multiplexed m= lines but still depends on the Offer/Answer exchanges
for the addition or removal of media stream identifiers [MSID].
By taking the Offer/Answer approach, both Plan A and Plan B take away
from the application the opportunity to handle such events in a way
that is most fitting for the use case, which, among other things,
also goes against the working group's decision to not to define a
specific signalling protocol. (It could be argued that it is
therefore only natural how proponents of each plan, having different
use cases in mind, are remarkably far from reaching consensus).
Reliance on preliminary announcement of SSRC identifiers is another
issue. While this could be perceived as relatively straightforward
in one-to-one sessions or even conference calls within controlled
environments, it can be a problem in the following cases:
o interoperability with legacy endpoints
o use within non-controlled and potentially federated conference
environments where new RTP streams may appear relatively often.
In such cases the signalling required to describe all of them
through Offer/Answer may represent substantial overhead while none
or only a part of it (e.g. the description of a main, active
speaker stream) may be required by the application.
By increasing the number of Offer/Answer exchanges Both Plan A and
Plan B also increase the risk of encountering glare situations (i.e.
cases where both parties attempt to modify a session at the same
time). While glare is also possible with basic Offer/Answer and
resolution of such situations must be implemented anyway, the need to
frequently resort to such code may either negatively impact user
experience (e.g. when "back off" resolution is used) or require
substantial modifications in the Offer/Answer model and/or further
venturing into the land of signalling protocols
[ROACH-GLARELESS-ADD].
7. IANA Considerations
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None.
8. Informative References
[BUNDLE] Holmberg, C., Alvestrand, H., and C. Jennings,
"Multiplexing Negotiation Using Session Description
Protocol (SDP) Port Numbers", reference.I-D.ietf-clue-
framework (work in progress), June 2013, <reference.I-D
.ietf-mmusic-sdp-bundle-negotiation>.
[CLUE] Duckworth, M., Pepperell, A., and S. Wenger, "Framework
for Telepresence Multi-Streams", reference.I-D.ietf-clue-
framework (work in progress), May 2013, <reference.I-D
.ietf-clue-framework>.
[COIN] Ivov, E. and E. Marocco, "XEP-0298: Delivering Conference
Information to Jingle Participants (Coin)", XSF XEP 0298,
June 2011, <reference.I-D.ietf-coin-framework>.
[MAX-SSRC]
Westerlund, M., Burman, B., and F. Jansson, "Multiple
Synchronization sources (SSRC) in RTP Session Signaling ",
reference.I-D.westerlund-avtcore-max-ssrc (work in
progress), July 2012, <reference.I-D.westerlund-avtcore-
max-ssrc>.
[MSID] Alvestrand, H., "Cross Session Stream Identification in
the Session Description Protocol", reference.I-D.ietf-
mmusic-msid (work in progress), February 2013,
<reference.I-D.ietf-mmusic-msid>.
[PlanA] Roach, A. and M. Thomson, "Using SDP with Large Numbers of
Media Flows", reference.I-D.roach-rtcweb-plan-a (work in
progress), May 2013, <reference.I-D.roach-rtcweb-plan-a>.
[PlanB] Uberti, J., "Plan B: a proposal for signaling multiple
media sources in WebRTC.", reference.I-D.uberti-rtcweb-
plan (work in progress), May 2013, <reference.I-D.uberti-
rtcweb-plan>.
[RFC3264] Rosenberg, J. and H. Schulzrinne, "An Offer/Answer Model
with Session Description Protocol (SDP)", RFC 3264, June
2002.
[RFC3550] Schulzrinne, H., Casner, S., Frederick, R., and V.
Jacobson, "RTP: A Transport Protocol for Real-Time
Applications", STD 64, RFC 3550, July 2003.
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[RFC3551] Schulzrinne, H. and S. Casner, "RTP Profile for Audio and
Video Conferences with Minimal Control", STD 65, RFC 3551,
July 2003.
[RFC4566] Handley, M., Jacobson, V., and C. Perkins, "SDP: Session
Description Protocol", RFC 4566, July 2006.
[RFC4575] Rosenberg, J., Schulzrinne, H., and O. Levin, "A Session
Initiation Protocol (SIP) Event Package for Conference
State", RFC 4575, August 2006.
[RFC5285] Singer, D. and H. Desineni, "A General Mechanism for RTP
Header Extensions", RFC 5285, July 2008.
[RFC5761] Perkins, C. and M. Westerlund, "Multiplexing RTP Data and
Control Packets on a Single Port", RFC 5761, April 2010.
[RFC5956] Begen, A., "Forward Error Correction Grouping Semantics in
the Session Description Protocol", RFC 5956, September
2010.
[RFC6051] Perkins, C. and T. Schierl, "Rapid Synchronisation of RTP
Flows", RFC 6051, November 2010.
[ROACH-GLARELESS-ADD]
Roach, A., "An Approach for Adding RTCWEB Media Streams
without Glare", reference.I-D.roach-rtcweb-glareless-add
(work in progress), May 2013, <reference.I-D.roach-rtcweb-
glareless-add>.
[SRCNAME] Westerlund, M., Burman, B., and P. Sandgren, "RTCP SDES
Item SRCNAME to Label Individual Sources ", reference.I-D
.westerlund-avtext-rtcp-sdes-srcname (work in progress),
October 2012, <reference.I-D.westerlund-avtext-rtcp-sdes-
srcname>.
[TRICKLE-ICE]
Ivov, E., Rescorla, E., and J. Uberti, "Trickle ICE:
Incremental Provisioning of Candidates for the Interactive
Connectivity Establishment (ICE) Protocol ", reference.I-D
.ivov-mmusic-trickle-ice (work in progress), March 2013,
<reference.I-D.ivov-mmusic-trickle-ice>.
[XCON] , "Centralized Conferencing (XCON) Status Pages", ,
<http://tools.ietf.org/wg/xcon/>.
Appendix A. Acknowledgements
Ivov Expires January 16, 2014 [Page 14]
Internet-Draft SDP O/A with Multiple SSRCs July 2013
Many thanks to Jonathan Lennox for reviewing the document and
providing valuable feedback.
Author's Address
Emil Ivov
Jitsi
Strasbourg 67000
France
Phone: +33-177-624-330
Email: emcho@jitsi.org
Ivov Expires January 16, 2014 [Page 15]