Using Simulcast in SDP and RTP SessionsEricssonKistavagen 25SE-164 80 StockholmSwedenbo.burman@ericsson.comEricssonFarogatan 2SE-164 80 StockholmSweden+46 10 714 82 87magnus.westerlund@ericsson.comCisco170 West Tasman DriveSan JoseCA95134USAsnandaku@cisco.comCisco170 West Tasman DriveSan JoseCA95134USAmzanaty@cisco.comIn some application scenarios it may be desirable to send multiple
differently encoded versions of the same media source in different RTP
streams. This is called simulcast. This document discusses the best way
of accomplishing simulcast in RTP and how to signal it in SDP. A
solution is defined by making an extension to SDP, and using RTP/RTCP
identification methods to relate RTP streams belonging to the same media
source. The SDP extension consists of a new media level SDP attribute
that expresses capability to send and/or receive simulcast RTP streams.
RTP/RTCP identification using either payload types or a separately
defined method for RTP stream configuration are defined.Most of today's multiparty video conference solutions make use of
centralized servers to reduce the bandwidth and CPU consumption in the
endpoints. Those servers receive RTP streams from each participant and
send some suitable set of possibly modified RTP streams to the rest of
the participants, which usually have heterogeneous capabilities (screen
size, CPU, bandwidth, codec, etc). One of the biggest issues is how to
perform RTP stream adaptation to different participants' constraints
with the minimum possible impact on both video quality and server
performance.Simulcast is defined in this memo as the act of simultaneously
sending multiple different encoded streams of the same media source,
e.g. the same video source encoded with different video encoder types or
image resolutions. This can be done in several ways and for different
purposes. This document focuses on the case where it is desirable to
provide a media source as multiple encoded streams over RTP towards an intermediary so that the
intermediary can provide the wanted functionality by selecting which RTP
stream to forward to other participants in the session, and more
specifically how the identification and grouping of the involved RTP
streams are done. From an RTP perspective, simulcast is a specific
application of the aspects discussed in RTP Multiplexing
Guidelines.This document describes a few scenarios where it is motivated to use
simulcast, and also defines the needed SDP signaling for it.This document makes use of the terminology defined in RTP Taxonomy,
RTP Topology and RTP Topologies
Update. In addition, the following terms are used:An RTP middle node, defined in (Section 3.4: Topo-Mixer), further elaborated
and extended with other topologies in (Section 3.6 to
3.9).A common short term for the terms
"switching RTP mixer", "source projecting middlebox", and "video
switching MCU" as discussed in .One Encoded Stream or Dependent
Stream from a set of concurrently transmitted Encoded Streams and
optional Dependent Streams, all sharing a common Media Source, as
defined in .
Decoding a Dependent Stream also requires the related (Dependent
and) Encoded Stream(s), but in the context of simulcast that is
considered a property of the Dependent Stream constituting the
simulcast stream. For example, HD and thumbnail video simulcast
versions of a single Media Source sent concurrently as separate
RTP Streams.Different formats of a simulcast
stream serve the same purpose as alternative RTP payload types in
non-simulcast SDP, to allow multiple alternative media formats for
a given RTP Stream. As for multiple RTP payload types on the
m-line, any one of the alternative formats can be used at a given
point in time, but not more than one (based on RTP timestamp), and
what format is used can change dynamically from one RTP packet to
another. For example, if all participants in a group video call
can decode H.264 and H.265 video, but only some can encode H.265,
both H.264 and H.265 can be kept as alternative formats, and the
format may dynamically switch between H.264 and H.265 as different
participants become active speaker.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.Many use cases of simulcast as described in this document relate to a
multi-party communication session where one or more central nodes are
used to adapt the view of the communication session towards individual
participants, and facilitate the media transport between participants.
Thus, these cases targets the RTP Mixer type of topology.There are two principle approaches for an RTP Mixer to provide this
adapted view of the communication session to each receiving
participant:Transcoding (decoding and re-encoding) received RTP streams with
characteristics adapted to each receiving participant. This often
include mixing or composition of media sources from multiple
participants into a mixed media source originated by the RTP Mixer.
The main advantage of this approach is that it achieves close to
optimal adaptation to individual receiving participants. The main
disadvantages are that it can be very computationally expensive to
the RTP Mixer and typically also degrades media Quality of
Experience (QoE) such as end-to-end delay for the receiving
participants.Switching a subset of all received RTP streams or sub-streams to
each receiving participant, where the used subset is typically
specific to each receiving participant. The main advantages of this
approach are that it is computationally cheap to the RTP Mixer and
it has very limited impact on media QoE. The main disadvantage is
that it can be difficult to combine a subset of received RTP streams
into a perfect fit to the resource situation of a receiving
participant.The use of simulcast relates to the latter approach, where it is more
important to reduce the load on the RTP Mixer and/or minimize QoE impact
than to achieve an optimal adaptation of resource usage.A multicast/broadcast case where the receivers themselves selects the
most appropriate simulcast stream and tune in to the right media
transport to receive that stream is also considered . This enables large,
heterogeneous receiver populations, when it comes to capabilities and
the use of network path bandwidth resources.The media sources provided by a sending participant potentially
need to reach several receiving participants that differ in terms of
available resources. The receiver resources that typically differ
include, but are not limited to:This includes codec type (such as SDP MIME
type) and can include codec configuration options (e.g. SDP fmtp
parameters). A couple of codec resources that differ only in codec
configuration will be "different" if they are somehow not
"compatible", like if they differ in video codec profile, or the
transport packetization configuration.This relates to how the media source is
sampled, in spatial as well as in temporal domain. For video
streams, spatial sampling affects image resolution and temporal
sampling affects video frame rate. For audio, spatial sampling
relates to the number of audio channels and temporal sampling
affects audio bandwidth. This may be used to suit different
rendering capabilities or needs at the receiving endpoints, as
well as a method to achieve different transport capabilities,
bitrates and eventually QoE by controlling the amount of source
data.This relates to the amount of bits spent
per second to transmit the media source as an RTP stream, which
typically also affects the Quality of Experience (QoE) for the
receiving user.Letting the sending participant create a simulcast of a few
differently configured RTP streams per media source can be a good
tradeoff when using an RTP switch as middlebox, instead of sending a
single RTP stream and using an RTP mixer to create individual
transcodings to each receiving participant.This requires that the receiving participants can be categorized in
terms of available resources and that the sending participant can
choose a matching configuration for a single RTP stream per category
and media source.For example, assume for simplicity a set of receiving participants
that differ only in that some have support to receive Codec A, and the
others have support to receive Codec B. Further assume that the
sending participant can send both Codec A and B. It can then reach all
receivers by creating two simulcasted RTP streams from each media
source; one for Codec A and one for Codec B.In another simple example, a set of receiving participants differ
only in screen resolution; some are able to display video with at most
360p resolution and some support 720p resolution. A sending
participant can then reach all receivers by creating a simulcast of
RTP streams with 360p and 720p resolution for each sent video media
source.In more elaborate cases, the receiving participants differ both in
available sampling and bitrate, and maybe also codec, and it is up to
the RTP switch to find a good trade-off in which simulcasted stream to
choose for each intended receiver. It is also the responsibility of
the RTP switch to negotiate a good fit of simulcast streams with the
sending participant.The maximum number of simulcasted RTP streams that can be sent is
mainly limited by the amount of processing and uplink network
resources available to the sending participant.The application logic that controls the communication session may
include special handling of some media sources. It is for example
commonly the case that the media from a sending participant is not
sent back to itself.It is also common that a currently active speaker participant is
shown in larger size or higher quality than other participants (the
sampling or bitrate aspects of ). Not sending the active speaker
media back to itself means there is some other participant's media
that instead has to receive special handling towards the active
speaker; typically the previous active speaker. This way, the
previously active speaker is needed both in larger size (to current
active speaker) and in small size (to the rest of the participants),
which can be solved with a simulcast from the previously active
speaker to the RTP switch.When using broadcast or multicast technology to distribute
real-time media streams to large populations of receivers, there can
still be significant heterogeneity among the receiver population. This
can depend on several factors:The network paths to individual
receivers will have variations in the bandwidth, thus putting
different limits on the supported bit-rates that can be
received.The end point's hardware and
software can have varying capabilities in relation to screen
resolution, decoding capabilities, and supported media codecs.To handle these variations, a transmitter of real-time media may
want to apply simulcast to a media source and provide it as a set of
different encoded streams, enabling the receivers to select the best
fit from this set themselves. The end point capabilities will usually
result in a single initial choice. However, the network bandwidth can
vary over time, which requires a client to continuously monitor its
reception to determine if the received RTP streams still fit within
the available bandwidth. If not, another set of encoded streams from
the ones offered in the simulcast will have to be chosen.When using IP multicast, the level of granularity that the receiver
can select from is decided by its ability to choose different
multicast addresses. Thus, different simulcast streams need to be put
on different media transports using different multicast addresses. If
these simulcast streams are described using SDP, they need to be part
of different SDP media descriptions, as SDP binds to transport on
media description level.The application logic that controls the communication session may
allow receiving participants to apply preferences to the
characteristics of the RTP stream they receive, for example in terms
of the aspects listed in .
Sending a simulcast of RTP streams is one way of accommodating
receivers with conflicting or otherwise incompatible preferences.The following requirements need to be met to support the use cases in
previous sections:Identification. It must be
possible to identify a set of simulcasted RTP streams as originating
from the same media source:In SDP signaling.On RTP/RTCP level.Transport usage. The solution
must work when using:Legacy SDP with separate
media transports per SDP media description.Bundled
SDP media descriptions.Capability negotiation. It must
be possible that:Sender can express
capability of sending simulcast.Receiver can express
capability of receiving simulcast.Sender can express
maximum number of simulcast streams that can be provided.Receiver can express
maximum number of simulcast streams that can be received.Sender can detail the
characteristics of the simulcast streams that can be
provided.Receiver can detail the
characteristics of the simulcast streams that it prefers to
receive.Distinguishing features. It must
be possible to have different simulcast streams use different codec
parameters, as can be expressed by SDP format values and RTP payload
types.Compatibility. It must be
possible to use simulcast in combination with other RTP mechanisms
that generate additional RTP streams:RTP Retransmission.RTP Forward Error Correction.Related payload types
such as audio Comfort Noise and/or DTMF.Interoperability. The solution
must be possible to use in:Interworking with
non-simulcast legacy clients using a single media source per
media type.WebRTC "Unified Plan"
environment with a single media source per SDP media
description.As an overview, the above requirements are met by signaling simulcast
capability and configurations in SDP:An offer or answer can contain a number of simulcast streams,
separate for send and receive directions.An offer or answer can contain multiple, alternative simulcast
streams in the same fashion as multiple, alternative codecs can be
offered in a media description.A single media source per SDP media description is assumed, which
makes the solution work in an Unified Plan context
(although different from what is currently defined there), both with
and without BUNDLE
grouping. This is also aligned with the concepts defined in .The codec configuration for each simulcast stream is expressed in
terms of existing SDP formats (and typically RTP payload types).
Some codecs may rely on codec configuration based on general
attributes that apply for all formats within a media description,
and which could thus not be used to separate different simulcast
streams. When many different media formats and/or simulcast streams
are used in the SDP, the available RTP payload type number space may
not be sufficient. This can be particularly prominent when BUNDLE is
used. To mitigate those limitations, this memo also allows optional
use of a separately specified RTP-level identification
mechanism, which complements and effectively extends the
available simulcast stream identification number space. This also
specifies a number of codec agnostic constraint attributes that may
be used to define simulcast streams.It is possible, but not required to use source-specific signaling with the proposed
solution.This section further details the overview above.Simulcast capability is expressed as a new media level SDP
attribute, "a=simulcast". For each desired direction
(send/recv/sendrecv), the simulcast attribute defines a list of
simulcast streams (separated by semicolons), each of which is a list
of simulcast formats (separated by commas). The meaning of the
attribute on SDP session level is undefined and MUST NOT be used.
There MUST NOT be more than one "a=simulcast" attribute per media
description. The ABNF for this attribute
is:There are separate and independent sets of parameters for simulcast
in send and receive directions. When listing multiple directions, each
direction MUST NOT occur more than once on the same line.Two simulcast stream identification methods are defined; "pt" using
RTP payload type (SDP format), and "rid" using an additional RTP-level identification
mechanism.Attribute parameters are grouped by direction and consist of a
listing of simulcast stream identifications to be used. The number of
(non-alternative, see below) identifications in the list sets a limit
to the number of supported simulcast streams in that direction.
Simulcast stream identifications present in "sendrecv" direction MUST
NOT be present also in "send" or "recv" directions, since the meaning
of that would be ambiguous. The order of the listed simulcast streams
in the "send" direction is not significant. The order of the listed
simulcast streams in the "recv" direction expresses a preference which
simulcast streams that are preferred, with the leftmost being most
preferred. This can be of importance if the number of actually sent
simulcast streams have to be reduced for some reason.Editor's note: Consider to remove the sendrecv definitions, as
they don't match PTs and RIDs unidirectionality.Formats that have explicit dependencies to other formats (even in the same
media description) MAY be listed as different simulcast streams.Alternative simulcast formats MAY be specified as part of the
attribute parameters by expressing each simulcast stream as a
comma-separated list of alternative format identifiers. In this case,
there MUST NOT be any capability restriction in what alternatives can
be used across different simulcast streams, like requiring all
simulcast streams to use the same codec alternative. The order of the
alternatives within a simulcast stream is significant; the
alternatives are listed from (left) most preferred to (right) least
preferred. For the use of simulcast, this overrides the normal codec
preference as expressed by format type ordering on the m-line, using
regular SDP rules. This is to enable a separation of general codec
preferences and simulcast stream codec preferences.A simulcast stream can use a codec defined such that the same RTP
SSRC can change RTP payload type multiple times during a session,
possibly even on a per-packet basis. A typical example can be a speech
codec that makes use of Comfort Noise
and/or DTMF formats. In those cases,
such "related" formats MUST NOT be listed explicitly in the attribute
parameters, since they are not strictly simulcast streams of the media
source, but rather a specific way of generating the RTP stream of a
single simulcast stream with varying RTP payload type. Instead, only a
single simulcast stream identification MUST be used per simulcast
stream or alternative simulcast format (if there are such) in the SDP.
The used simulcast stream identification SHOULD be the codec format
most relevant to the media description, if possible to identify, for
example the audio codec rather than the DTMF. What codec format to
choose in the case of switching between multiple equally "important"
formats is left open, but it is assumed that in the presence of such
strong relation it does not matter which is chosen.Use of the redundant audio data
format could be seen as a form of simulcast for loss protection
purposes, but is not considered conflicting with the mechanisms
described in this memo and MAY therefore be used as any other format.
In this case the "red" format, rather than the carried formats, SHOULD
be the one to list as a simulcast stream on the "a=simulcast"
line.Editor's note: Consider adding the possibility to put an RTP
stream in "paused"
state from the beginning of the session, possibly starting
it at a later point in time by applying RTP/RTCP level procedures
from that specification.When used as a declarative media description, a=simulcast "recv"
direction formats indicates the configured end point's required
capability to recognize and receive a specified set of RTP streams
as simulcast streams. In the same fashion, a=simulcast "send"
direction requests the end point to send a specified set of RTP
streams as simulcast streams. The "sendrecv" direction combines
"send" and "recv" requirements, using the same format values for
both.If multiple simulcast formats are listed, it means that the
configured end point MUST be prepared to receive any of the "recv"
formats, and MAY send any of the "send" formats for that simulcast
stream.Editor's note: The external RTP identification mechanism
currently lacks a declarative use definition. As declarative use
may also not follow unified plan with a single media source per
m= line, it is uncertain if declarative can be defined for the
mechanism in its current shape.An offerer wanting to use simulcast SHALL include the
"a=simulcast" attribute in the offer. An offerer that receives an
answer without "a=simulcast" MUST NOT use simulcast towards the
answerer. An offerer that receives an answer with "a=simulcast" not
listing a direction or without any simulcast stream identifications
in a specified direction MUST NOT use simulcast in that
direction.An answerer that does not understand the concept of simulcast
will also not know the attribute and will remove it in the SDP
answer, as defined in existing SDP
Offer/Answer procedures. An answerer that does understand the
attribute and that wants to support simulcast in an indicated
direction SHALL reverse directionality of the unidirectional
direction parameters; "send" becomes "recv" and vice versa, and
include it in the answer. If the offered direction is "sendrecv",
the answerer MAY keep it, but MAY also change it to "send" or "recv"
to indicate that it is only interested in simulcast for a single
direction. Note that, like all other use of SDP format tags ("pt:")
for the send direction in Offer/Answer, format tags related to the
simulcast stream identification send direction in an offer ("send"
or "sendrecv") are placeholders that refer to information in the
offer SDP, and the actual formats that will be used on the wire
(including RTP Payload Format numbers) depends on information
included in the SDP answer.An offerer listing a set of receive simulcast streams and/or
alternative formats in the offer MUST be prepared to receive RTP
streams for any of those simulcast streams and/or alternative
formats from the answerer.An answerer that receives an offer with simulcast containing an
"a=simulcast" attribute listing alternative formats for simulcast
streams MAY keep all the alternatives in the answer, but it MAY also
choose to remove any non-desirable alternatives per simulcast stream
in the answer. The answerer MUST NOT add any alternatives that were
not present in the offer.An answerer that receives an offer with simulcast that lists a
number of simulcast streams, MAY reduce the number of simulcast
streams in the answer, but MUST NOT add simulcast streams.An offerer that receives an answer where some simulcast formats
are kept MUST be prepared to receive any of the kept send direction
alternatives, and MAY send any of the kept receive direction
alternatives from the answer. Similarly, the answerer MUST be
prepared to receive any of the kept receive direction alternatives,
and MAY send any of the kept send direction alternatives in the
answer.The offerer and answerer MUST NOT send more than a single
alternative format at a time (based on RTP timestamps) per simulcast
stream, but MAY change format on a per-RTP packet basis. This
corresponds to the existing (non-simulcast) SDP offer/answer case
when multiple formats are included on the m-line in the SDP
answer.An offerer that receives an answer where some of the simulcast
streams are removed MAY release the corresponding resources (codec,
transport, etc) in its receive direction and MUST NOT send any RTP
streams corresponding to the removed simulcast streams.Simulcast streams or formats using undefined simulcast stream
identifications MUST NOT be used as valid simulcast streams by an
RTP stream receiver.The media formats and corresponding characteristics of encoded
streams used in a simulcast SHOULD be chosen such that they are
different. If this difference is not required, RTP duplication procedures SHOULD be
considered instead of simulcast.Note: The inclusion of "a=simulcast" or the use of simulcast
does not change any of the interpretation or Offer/Answer
procedures for other SDP attributes, like "a=fmtp" or
"a=rid".As long as there is only a single media source per SDP media
description, simulcast RTP streams can be related on RTP level through
the RTP payload type and (optionally) RID, as specified in the SDP
"a=simulcast" attribute parameters.
When using BUNDLE with
multiple SDP media descriptions to specify a single RTP session, there
is an identification mechanism that allows relating RTP streams back
to individual media descriptions, after which the above RTP payload
type and RID relations can be used.BUNDLE's MID is an RTCP source description (SDES) item. To ensure
rapid initial reception, required to correctly process the RTP
streams, it is also defined as an RTP header
extension.Editor's note: Consider making RID an SDES item too, for the
same reasons as MID.These examples describe a client to video conference service, using
a centralized media topology with an RTP mixer.Alice is calling in to the mixer with a simulcast-enabled Unified
Plan client capable of a single media source per media type. The
client can send a simulcast of 2 video resolutions and frame rates:
HD 1280x720p 30fps and thumbnail 320x180p 15fps. This is defined
below using the "imageattr". Media
formats (RTP payload types) are used as simulcast stream
identification. Alice's Offer:The only thing in the SDP that indicates simulcast capability is
the line in the video media description containing the "simulcast"
attribute. The included format parameters indicates that sent
simulcast streams can differ in video resolution.The Answer from the server indicates that it too is simulcast
capable. Should it not have been simulcast capable, the
"a=simulcast" line would not have been present and communication
would have started with the media negotiated in the SDP.Since the server is the simulcast media receiver, it reverses the
direction of the "simulcast" attribute parameters.Fred is calling in to the same conference as in the example above
with a two-camera, two-display system, thus capable of handling two
separate media sources in each direction, where each media source is
simulcast-enabled in the send direction. Fred's client is a Unified
Plan client, restricted to a single media source per media
description.The first two simulcast streams for the first media source use
different codecs, H264-SVC and H264. These two simulcast streams also have
a temporal dependency. Two different video codecs, VP8 and H264, are offered as
alternatives for the third simulcast stream for the first media
source. RID is used as simulcast stream identification, reducing the
number of media formats needed.The second media source is offered with three different simulcast
streams. All video streams of this second media source are loss
protected by RTP retransmission. RID
is used as simulcast stream identification.Fred's client is also using BUNDLE to send all RTP streams from
all media descriptions in the same RTP session on a single media
transport. Although using many different simulcast streams in this
example, use of RID as simulcast stream identification enables use
of a low number of RTP payload types. Note that the use of both
BUNDLE and RID recommends using the RTP
header extension for carrying these fields.Note: Empty lines in the SDP above are added only for
readability and would not be present in an actual SDP.Simulcast is in this memo defined as the act of sending multiple
alternative encoded streams of the same underlying media source. When
transmitting multiple independent streams that originate from the same
source, it could potentially be done in several different ways using
RTP. A general discussion on considerations for use of the different RTP
multiplexing alternatives can be found in Guidelines for
Multiplexing in RTP. Discussion and clarification on how to
handle multiple streams in an RTP session can be found in .The network aspects that are relevant for simulcast are:When using simulcast it might be
of interest to prioritize a particular simulcast stream, rather than
applying equal treatment to all streams. For example, lower bit-rate
streams may be prioritized over higher bit-rate streams to minimize
congestion or packet losses in the low bit-rate streams. Thus, there
is a benefit to use a simulcast solution that supports QoS as good
as possible. By separating simulcast streams into different RTP
sessions and send those RTP sessions over different media
transports, a simulcast stream can be prioritized by existing flow
based QoS mechanisms. When using unicast, QoS mechanisms based on
individual packet marking are also feasible, which do not require
separation of simulcast streams into different RTP sessions to apply
different QoS. The proposed solution can be extended to support this
functionality with an optional mid: prefix before the RTP payload
types of a simulcast stream, to describe simulcast across multiple
media descriptions.With the chosen approach, it is not
possible to use different simulcast streams on different
transports, so either that description should be removed, or the
solution has to be amended to cater also for that case.Using multiple RTP sessions will
incur more cost for NAT/FW traversal unless they can re-use the same
transport flow, which can be achieved by either one of multiplexing
multiple RTP sessions on a single lower layer transport or
Multiplexing
Negotiation Using SDP Port Numbers. If flow based QoS with
any differentiation is desirable, the cost for additional transport
flows is likely necessary.Multiple RTP sessions will be required to
enable combining simulcast with multicast. Different simulcast
streams have to be separated to different multicast groups to allow
a multicast receiver to pick the stream it wants, rather than
receive all of them. In this case, the only reasonable
implementation is to use different RTP sessions for each multicast
group so that reporting and other RTCP functions operate as
intended. The proposed solution can be extended to support this
functionality with an optional mid: prefix before the RTP payload
types of a simulcast stream, to describe simulcast across multiple
media descriptions.As with QoS above, different
simulcast streams on different multicast groups are not possible
with the chosen approach, and text must be changed
accordingly.This document requests to register a new SDP attribute,
simulcast.Formal registrations to be written.The simulcast capability, configuration attributes and parameters are
vulnerable to attacks in signaling.A false inclusion of the "a=simulcast" attribute may result in
simultaneous transmission of multiple RTP streams that would otherwise
not be generated. The impact is limited by the media description joint
bandwidth, shared by all simulcast streams irrespective of their number.
There may however be a large number of unwanted RTP streams that will
impact the share of bandwidth allocated for the originally wanted RTP
stream.A hostile removal of the "a=simulcast" attribute will result in
simulcast not being used.Neither of the above will likely have any major consequences and can
be mitigated by signaling that is at least integrity and source
authenticated to prevent an attacker to change it.Morgan Lindqvist and Fredrik Jansson, both from Ericsson, have
contributed with important material to the first versions of this
document. Robert Hansen and Cullen Jennings, from Cisco, and Peter
Thatcher, from Google, contributed significantly to subsequent
versions.NOTE TO RFC EDITOR: Please remove this section prior to
publication.Relying on the new RID solution for codec constraints and
configuration identification. This has resulted in changes in
syntax to identify if pt or RID is used to describe the simulcast
stream.Renamed simulcast version and simulcast version alternative to
simulcast stream and simulcast format respectively, and improved
definitions for them.Clarification that it is possible to switch between simulcast
version alternatives, but that only a single one be used at any
point in time.Changed the definition so that ordering of simulcast formats
for a specific simulcast stream do have a preference order.No changes. Only preventing expiry.Added this appendix.