draft-ietf-avtcore-rtp-multi-stream-04

AVTCORE J. Lennox
Internet-Draft Vidyo
Updates: 3550, 4585 (if approved) M. Westerlund
Intended status: Standards Track Ericsson
Expires: November 29, 2014 Q. Wu
 Huawei
 C. Perkins
 University of Glasgow
 May 28, 2014
 Sending Multiple Media Streams in a Single RTP Session
 draft-ietf-avtcore-rtp-multi-stream-04
Abstract
 This document expands and clarifies the behavior of the Real-Time
 Transport Protocol (RTP) endpoints when they are using multiple
 synchronization sources (SSRCs), e.g. for sending multiple media
 streams, in a single RTP session. In particular, issues involving
 RTCP Control Protocol (RTCP) messages are described.
 This document updates RFC 3550 in regards to handling of multiple
 SSRCs per endpoint in RTP sessions. It also updates RFC 4585 to
 update and clarify the calculation of the timeout of SSRCs and the
 inclusion of feeback messages.
Status of This Memo
 This Internet-Draft is submitted in full conformance with the
 provisions of BCP 78 and BCP 79.
 Internet-Drafts are working documents of the Internet Engineering
 Task Force (IETF). Note that other groups may also distribute
 working documents as Internet-Drafts. The list of current Internet-
 Drafts is at http://datatracker.ietf.org/drafts/current/.
 Internet-Drafts are draft documents valid for a maximum of six months
 and may be updated, replaced, or obsoleted by other documents at any
 time. It is inappropriate to use Internet-Drafts as reference
 material or to cite them other than as "work in progress."
 This Internet-Draft will expire on November 29, 2014.
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Copyright Notice
 Copyright (c) 2014 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
 (http://trustee.ietf.org/license-info) in effect on the date of
 publication of this document. Please review these documents
 carefully, as they describe your rights and restrictions with respect
 to this document. Code Components extracted from this document must
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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 . . . . . . . . . . . . . . . . . . . . . . . . 3
 2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 3
 3. Use Cases For Multi-Stream Endpoints . . . . . . . . . . . . 4
 3.1. Multiple-Capturer Endpoints . . . . . . . . . . . . . . . 4
 3.2. Multi-Media Sessions . . . . . . . . . . . . . . . . . . 4
 3.3. Multi-Stream Mixers . . . . . . . . . . . . . . . . . . . 4
 3.4. Multiple SSRCs for a Single Media Source . . . . . . . . 5
 4. Multi-Stream Endpoint RTP Media Recommendations . . . . . . . 5
 5. Multi-Stream Endpoint RTCP Recommendations . . . . . . . . . 5
 5.1. RTCP Reporting Requirement . . . . . . . . . . . . . . . 5
 5.2. Initial Reporting Interval . . . . . . . . . . . . . . . 6
 5.3. Compound RTCP Packets . . . . . . . . . . . . . . . . . . 6
 5.3.1. Maintaining AVG_RTCP_SIZE . . . . . . . . . . . . . . 7
 5.3.2. Scheduling RTCP with Multiple Reporting SSRCs . . . . 8
 5.4. RTP/AVPF Feedback Packets . . . . . . . . . . . . . . . . 10
 5.4.1. The SSRC Used . . . . . . . . . . . . . . . . . . . . 10
 5.4.2. Scheduling a Feedback Packet . . . . . . . . . . . . 11
 6. RTCP Considerations for Streams with Disparate Rates . . . . 12
 6.1. Timing out SSRCs . . . . . . . . . . . . . . . . . . . . 13
 6.1.1. AVPF T_rr_interval Behavior . . . . . . . . . . . . . 13
 6.1.2. Avoiding Pre-mature Timeout . . . . . . . . . . . . . 14
 6.1.3. AVP and AVPF Interoperability . . . . . . . . . . . . 15
 6.1.4. Specified Behavior . . . . . . . . . . . . . . . . . 16
 6.2. Tuning RTCP transmissions . . . . . . . . . . . . . . . . 17
 6.2.1. RTP/AVP and RTP/SAVP . . . . . . . . . . . . . . . . 17
 6.2.2. RT/AVPF and RTP/SAVPF . . . . . . . . . . . . . . . . 18
 7. Security Considerations . . . . . . . . . . . . . . . . . . . 19
 8. Open Issues . . . . . . . . . . . . . . . . . . . . . . . . . 20
 9. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 20
 10. References . . . . . . . . . . . . . . . . . . . . . . . . . 20
 10.1. Normative References . . . . . . . . . . . . . . . . . . 20
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 10.2. Informative References . . . . . . . . . . . . . . . . . 21
 Appendix A. Changes From Earlier Versions . . . . . . . . . . . 22
 A.1. Changes From WG Draft -02 . . . . . . . . . . . . . . . . 22
 A.2. Changes From WG Draft -01 . . . . . . . . . . . . . . . . 22
 A.3. Changes From WG Draft -00 . . . . . . . . . . . . . . . . 22
 A.4. Changes From Individual Draft -02 . . . . . . . . . . . . 23
 A.5. Changes From Individual Draft -01 . . . . . . . . . . . . 23
 A.6. Changes From Individual Draft -00 . . . . . . . . . . . . 23
 Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 24
. Introduction
 At the time The Real-Time Transport Protocol (RTP) [RFC3550] was
 originally written, and for quite some time after, endpoints in RTP
 sessions typically only transmitted a single media stream, and thus
 used a single synchronization source (SSRC) per RTP session, where
 separate RTP sessions were typically used for each distinct media
 type.
 Recently, however, a number of scenarios have emerged (discussed
 further in Section 3) in which endpoints wish to send multiple RTP
 media streams, distinguished by distinct RTP synchronization source
 (SSRC) identifiers, in a single RTP session. Although RTP's initial
 design did consider such scenarios, the specification was not
 consistently written with such use cases in mind. The specifications
 are thus somewhat unclear.
 The purpose of this document is to expand and clarify [RFC3550]'s
 language for these use cases. The authors believe this does not
 result in any major normative changes to the RTP specification,
 however this document defines how the RTP specification is to be
 interpreted. In these cases, this document updates RFC3550. The
 document also updates RFC 4585 in regards to the timeout of inactive
 SSRCs as specificed in Section 6.1 to resolve problematic behavior as
 well as clarifying the inclusion of feedback messages.
 The document starts with terminology and some use cases where
 multiple sources will occur. This is followed by RTP and RTCP
 recommendations to resolve issues. Next are security considerations
 and remaining open issues.
. Terminology
 The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
 "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
 "OPTIONAL" in this document are to be interpreted as described in RFC
 2119 [RFC2119] and indicate requirement levels for compliant
 implementations.
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. Use Cases For Multi-Stream Endpoints
 This section discusses several use cases that have motivated the
 development of endpoints that sends RTP data using multiple SSRCs in
 a single RTP session.
3.1. Multiple-Capturer Endpoints
 The most straightforward motivation for an endpoint to send multiple
 RTP streams in a session is the scenario where an endpoint has
 multiple capture devices, and thus media sources, of the same media
 type and characteristics. For example, telepresence endpoints, of
 the type described by the CLUE Telepresence Framework
 [I-D.ietf-clue-framework], often have multiple cameras or microphones
 covering various areas of a room.
3.2. Multi-Media Sessions
 Recent work has been done in RTP
 [I-D.ietf-avtcore-multi-media-rtp-session] and SDP
 [I-D.ietf-mmusic-sdp-bundle-negotiation] to update RTP's historical
 assumption that media sources of different media types would always
 be sent on different RTP sessions. In this work, a single endpoint's
 audio and video RTP media streams (for example) are instead sent in a
 single RTP session.
3.3. Multi-Stream Mixers
 There are several RTP topologies which can involve a central device
 that itself generates multiple RTP media streams in a session.
 One example is a mixer providing centralized compositing for a multi-
 capture scenario like that described in Section 3.1. In this case,
 the centralized node is behaving much like a multi-capturer endpoint,
 generating several similar and related sources.
 More complicated is the Selective Forwarding Middlebox, see
 Section 3.7 of [I-D.ietf-avtcore-rtp-topologies-update]. This is a
 middlebox that receives media streams from several endpoints, and
 then selectively forwards modified versions of some of the streams
 toward the other endpoints it is connected to. Toward one
 destination, a separate media source appears in the session for every
 other source connected to the middlebox, "projected" from the
 original streams, but at any given time many of them can appear to be
 inactive (and thus are receivers, not senders, in RTP). This sort of
 device is closer to being an RTP mixer than an RTP translator, in
 that it terminates RTCP reporting about the mixed streams, and it can
 re-write SSRCs, timestamps, and sequence numbers, as well as the
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 contents of the RTP payloads, and can turn sources on and off at will
 without appearing to be generating packet loss. Each projected
 stream will typically preserve its original RTCP source description
 (SDES) information.
3.4. Multiple SSRCs for a Single Media Source
 There are also several cases where a single media source results in
 the usage of multiple SSRCs within the same RTP session. Transport
 robustification tools like RTP Retransmission [RFC4588] result in
 multiple SSRCs, one with source data, and another with the repair
 data. Scalable encoders and their RTP payload foramts, like H.264's
 extension for Scalable Video Coding(SVC) [RFC6190] can be transmitted
 in a configuration where the scalable layers are distributed over
 multiple SSRCs within the same session, to enable RTP packet stream
 level (SSRC) selection and routing in conferencing middleboxes.
. Multi-Stream Endpoint RTP Media Recommendations
 While an endpoint MUST (of course) stay within its share of the
 available session bandwidth, as determined by signalling and
 congestion control, this need not be applied independently or
 uniformly to each media stream and its SSRCs. In particular, session
 bandwidth MAY be reallocated among an endpoint's SSRCs, for example
 by varying the bandwidth use of a variable-rate codec, or changing
 the codec used by the media stream, up to the constraints of the
 session's negotiated (or declared) codecs. This includes enabling or
 disabling media streams and their redundancy streams as more or less
 bandwidth becomes available.
. Multi-Stream Endpoint RTCP Recommendations
 This section contains a number of different RTCP clarifications or
 recommendations that enables more efficient and simpler behavior
 without loss of functionality.
 The RTP Control Protocol (RTCP) is defined in Section 6 of [RFC3550],
 but it is largely documented in terms of "participants". In many
 cases, the specification's recommendations for "participants" are to
 be interpreted as applying to individual SSRCs, rather than to
 endpoints. This section describes several concrete cases where this
 applies.
5.1. RTCP Reporting Requirement
 For each of an endpoint's SSRCs, whether or not they are currently
 sending media, SR/RR and SDES packets MUST be sent at least once per
 RTCP report interval. (For discussion of the content of SR or RR
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 packets' reception statistic reports, see
 [I-D.ietf-avtcore-rtp-multi-stream-optimisation].)
5.2. Initial Reporting Interval
 When a new SSRC is added to a unicast session, the sentence in
 [RFC3550]'s Section 6.2 applies: "For unicast sessions ... the delay
 before sending the initial compound RTCP packet MAY be zero." This
 applies to individual SSRCs as well. Thus, endpoints MAY send an
 initial RTCP packet for an SSRC immediately upon adding it to a
 unicast session.
 This allowance also applies, as written, when initially joining a
 unicast session. However, in this case some caution needs to be
 exercised if the end-point or mixer has a large number of sources
 (SSRCs) as this can create a significant burst. How big an issue
 this is depends on the number of sources for which the initial SR or
 RR packets and Session Description CNAME items are to be sent, in
 relation to the RTCP bandwidth.
 (tbd: Maybe some recommendation here? The aim in restricting this to
 unicast sessions was to avoid this burst of traffic, which the usual
 RTCP timing and reconsideration rules will prevent.)
5.3. Compound RTCP Packets
 Section 6.1 in [RFC3550] gives the following advice to RTP
 translators and mixers:
 "It is RECOMMENDED that translators and mixers combine individual
 RTCP packets from the multiple sources they are forwarding into
 one compound packet whenever feasible in order to amortize the
 packet overhead (see Section 7). An example RTCP compound packet
 as might be produced by a mixer is shown in Fig. 1. If the
 overall length of a compound packet would exceed the MTU of the
 network path, it SHOULD be segmented into multiple shorter
 compound packets to be transmitted in separate packets of the
 underlying protocol. This does not impair the RTCP bandwidth
 estimation because each compound packet represents at least one
 distinct participant. Note that each of the compound packets MUST
 begin with an SR or RR packet."
 Note: To avoid confusion, an RTCP packet is an individual item,
 such as a Sender Report (SR), Receiver Report (RR), Source
 Description (SDES), Goodbye (BYE), Application Defined (APP),
 Feedback [RFC4585] or Extended Report (XR) [RFC3611] packet. A
 compound packet is the combination of two or more such RTCP
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 packets where the first packet has to be an SR or an RR packet,
 and which contains a SDES packet containing an CNAME item.
 The above results in compound RTCP packets that contain multiple SR
 or RR packets from different sources (SSRCs) as well as any of the
 other packet types. There are no restrictions on the order in which
 the packets can occur within the compound packet, except the regular
 compound rule, i.e., starting with an SR or RR.
 This advice applies to multi-media-stream endpoints as well, with the
 same restrictions and considerations. (Note, however, that the last
 sentence does not apply to AVPF [RFC4585] or SAVPF [RFC5124] feedback
 packets if Reduced-Size RTCP [RFC5506] is in use.)
5.3.1. Maintaining AVG_RTCP_SIZE
 When multiple local SSRCs are sending their RTCP packets in the same
 compound packet, this obviously results in larger RTCP compound
 packets. This will have an affect on the value of the average RTCP
 packet size metering (avg_rtcp_size) that is done for the purpose of
 RTCP transmission scheduling calculation. This section discusses the
 impact of this and provide recommendations with how to deal with it.
 This section will use the concept of an 'RTCP Compound Packet' to
 represent not just proper RTCP compound packets, i.e. ones that start
 with an SR or RR RTCP packet and include at least one SDES CNAME
 item. For the purpose of the below calculation, other valid lower
 layer datagram units an RTCP implementation can send or receive,
 independently if they are an aggregate or not of RTCP packets are
 also considered. This especially includes Reduced-Size RTCP packets
 [RFC5506].
 The RTCP packet scheduling algorithm that is defined in RTP [RFC3550]
 deals with individual SSRCs. These SSRCs transmit their set of RTCP
 packets at each scheduled interval. Thus, to maintain this per-SSRC
 property of the scheduling, the avg_rtcp_size needs to be updated
 with per-SSRC average RTCP compound packet sizes. The avg_rtcp_size
 value SHALL be updated for each received or sent RTCP compound packet
 with the total size (including packet overhead such as IP/UDP)
 divided by the number of reporting SSRCs. The number of reporting
 SSRCs SHALL be determined by counting the number of different SSRCs
 that are the source of Sender Report (SR) or Receiver Report (RR)
 RTCP packets within the compound. A non-compound RTCP packet, i.e.
 it contains no SR or RR RTCP packets at all -- as can happen with
 Reduced-Size RTCP packets [RFC5506] -- the SSRC count SHALL be
 considered to be 1.
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 Note: The above makes it possible to amortize the packet overhead
 between the number of SSRCs sharing a RTCP compound packet.
 For an RTCP end-point that doesn't follow the above rule, and instead
 uses the full RTCP compound packet size as input, the average RTCP
 reporting interval will be scaled up (i.e. become longer) with a
 factor that is proportional to the number of SSRCs sourcing RTCP
 packets in an RTCP compound packet as well as the set of SSRCs being
 aggregated in proportion to the total number of participants. This
 factor can quite easily become larger than 5, e.g. with an 1500 byte
 MTU and an average per-SSRC sum of RTCP packets of 240 bytes, the MTU
 will fit 6 packets. If the receiver end-point has a single SSRC and
 all other endpoints fill their MTU fully, the factor will be close to
 6. If the RTCP configuration is such that the transmission interval
 is bandwidth limited, rather than any type of minimal interval
 limitation (Tmin or T_RR_INT), then the other end-points will likely
 time out this SSRC due to it using an regular RTCP interval is more
 than 5 times the rest of the endpoints.
5.3.2. Scheduling RTCP with Multiple Reporting SSRCs
 When implementing RTCP packet scheduling for cases where multiple
 reporting SSRCs are aggregating their RTCP packets in the same
 compound packet there are a number of challenges. First of all, we
 have the goal of not changing the general properties of the RTCP
 packet transmissions, which include the general inter-packet
 distribution, and the behavior for dealing with flash joins as well
 as other dynamic events.
 The below specified mechanism deals with:
 o That one can't have a-priori knowledge about which RTCP packets
 are to be sent, or their size, prior to generating the packets.
 In which case, the time from generation to transmission ought to
 be as short as possible to minimize the information that becomes
 stale.
 o That one has an MTU limit, that one ought to avoid exceeding, as
 that requires lower-layer fragmentation (e.g., IP fragmentation)
 which impacts the packets' probability of reaching the
 receiver(s).
 Schedule all the endpoint's local SSRCs individually for transmission
 using the regular calculation of Tn for the profile being used. Each
 time a SSRC's Tn timer expires, do the regular reconsideration. If
 the reconsideration indictes that an RTCP packet is to be sent:
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 1. Consider if an additional SSRC can be added. That consideration
 is done by picking the SSRC which has the Tn value closest in
 time to now (Tc).
 2. Calculate how much space for RTCP packets would be needed to add
 that SSRC.
 3. If the considered SSRC's RTCP Packets fit within the lower layer
 datagram's Maximum Transmission Unit, taking the necessary
 protocol headers into account and the consumed space by prior
 SSRCs, then add that SSRC's RTCP packets to the compound packet
 and go again to Step 1.
 4. If the considered SSRC's RTCP Packets will not fit within the
 compound packet, then transmit the generated compound packet.
 5. Update the RTCP Parameters for each SSRC that has been included
 in the sent RTCP packet. The Tp value for each SSRC MUST be
 updated as follows:
 For the first SSRC: As this SSRC was the one that was
 reconsidered the tp value is set to the tc as defined in RTP
 [RFC3550].
 For any additional SSRC: The tp value SHALL be set to the
 transmission time this SSRC would have had it not been
 aggregated and given the current existing session context.
 This value is derived by taking this SSRC's Tn value and
 performing reconisderation and updating tn until tp + T <= tn.
 Then set tp to this tn value.
 6. For the sent SSRCs calculate new tn values based on the updated
 parameters and reschedule the timers.
 Reverse reconsideration needs to be performed as specified in RTP
 [RFC3550]. It is important to note that under the above algorithm
 when performing reconsideration, the value of tp can actually be
 larger than tc. However, that still has the desired effect of
 proportionally pulling the tp value towards tc (as well as tn) as the
 group size shrinks in direct proportion the reduced group size.
 The above algorithm has been shown in simulations to maintain the
 inter-RTCP-packet transmission distribution for the SSRCs and consume
 the same amount of bandwidth as non-aggregated packets in RTP
 sessions with static sets of participants. With this algorithm the
 actual transmission interval for any SSRC triggering an RTCP compound
 packet transmission is following the regular transmission rules. It
 also handles the cases where the number of SSRCs that can be included
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 in an aggregated packet varies. An SSRC that previously was
 aggregated and fails to fit in a packet still has its own
 transmission scheduled according to normal rules. Thus, it will
 trigger a transmission in due time, or the SSRC will be included in
 another aggregate.
 The algorithm's behavior under SSRC group size changes is under
 investigation. However, it is expected to be well behaved based on
 the following analyses.
 RTP sessions where the number of SSRC are growing: When the group
 size is growing, the Td values grow in proportion to the number of
 new SSRCs in the group. The reconsideration when the timer for
 the tn expires, that SSRC will reconsider the transmission and
 with a certain probability reschedule the tn timer. This part of
 the reconsideration algorithm is only impacted by the above
 algorithm by having tp values that are in the future instead of
 set to the time of the actual last transmission at the time of
 updating tp. Thus the scheduling causes in worst case a plateau
 effect for that SSRC. That effect depends on how far into the
 future tp can advance.
 RTP sessions where the number of SSRC are shrinking: When the group
 shrinks, reverse reconsideration moves the tp and tn values
 towards tc proportionally to the number of SSRCs that leave the
 session compared to the total number of participants when they
 left. Thus the also group size reductions need to be handled.
 In general the potential issue that might exist depends on how far
 into the future the tp value can drift compared to the actual packet
 transmissions that occur. That drift can only occur for an SSRC that
 never is the trigger for RTCP packet transmission and always gets
 aggregated and where the calculcated packet transmission interval
 randomly occurs so that tn - tp for this SSRC is on average larger
 than the ones that gets transmitted.
5.4. RTP/AVPF Feedback Packets
 This section discusses the transmission of RTP/AVPF feedback packets
 when the transmitting endpoint has multiple SSRCs.
5.4.1. The SSRC Used
 When an RTP endpoint has multiple SSRCs, it can make certain choices
 on which SSRC to use as the source of an RTCP Feedback Packet. This
 sub-section discusses some considerations of this.
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 o The media type of the media the SSRC transmits is actually not a
 relevant factor when considering if an SSRC can transmit a
 particular Feedback message.
 o Feedback messages which are Notification or Indications regarding
 the endpoint's own RTP packet stream need to be sent using the
 SSRC transmitting the media it relates to. This also includes
 notifications that are related to a received request or command.
 o The SSRC used to send feedback messages has a role as either a
 media sender or a receiver. The bandwidth pools can be different
 for SSRCs that are senders and receivers. Thus feedback messages
 that expect to be more frequent can be sent from an SSRC that has
 the better possibility of sending frequent RTCP compound packets
 or reduced size packets. This also affects the consideration if
 the SSRC can be used in immediate mode or not.
 o Some Feedback Types requires consistency in the sender. For
 example TMMBR, if one sets a limitation, the same SSRC needs to be
 the one that increases it. Others can simply benefit from having
 this property.
 Note that the source of the feedback RTCP packet does not need to be
 any of the sources (SSRC) including SR/RR packets in a compound
 packet. For Reduced-Size RTCP [RFC5506] the aggregation of feedback
 messages from multiple sources are not limited, beyond the
 consideration in Section 4.2.2 of [RFC5506].
5.4.2. Scheduling a Feedback Packet
 When an SSRC has a need to transmit a feedback packet in early mode
 it follows the scheduling rules defined in Section 3.5 in RTP/AVPF
 [RFC4585]. When following these rules the following clarifications
 need to be taken into account:
 o That a session is considered to be point-to-point or multiparty
 not based on the number of SSRCs, but the number of endpoints
 directly seen in the RTP session by the endpoint. tbd: Clarify
 what is considered to "see" an endpoint?
 o Note that when checking if there is already a scheduled compound
 RTCP packet containing feedback messages (Step 2 in
 Section 3.5.2), that check is done considering all local SSRCs.
 TBD: The above does not allow an SSRC that is unable to send either
 an early or regular RTCP packet with the feedback message within the
 T_max_fb_delay to trigger another SSRC to send an early packet to
 which it could piggyback. Nor does it allow feedback to piggyback on
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 even regular RTCP packet transmissions that occur within
 T_max_fb_delay. A question is if either of these behaviours ought to
 be allowed.
 The latter appears simple and straight forward. Instead of
 discarding a FB message in step 4a: alternative 2, one could place
 such messages in a cache with a discard time equal to T_max_fb_delay,
 and in case any of the SSRCs schedule an RTCP packet for transmission
 within that time, it includes this message.
 The former case can have more widespread impact on the application,
 and possibly also on the RTCP bandwidth consumption as it allows for
 more massive bursts of RTCP packets. Still, on a time scale of a
 regular reporting interval, it ough to have no effect on the RTCP
 bandwidth as the extra feedback messages increase the avg_rtcp_size.
. RTCP Considerations for Streams with Disparate Rates
 It is possible for a single RTP session to carry streams of greatly
 differing bandwidth. There are two scenarios where this can occur.
 The first is when a single RTP session carries multiple flows of the
 same media type, but with very different quality; for example a video
 switching multi-point conference unit might send a full rate high-
 definition video stream of the active speaker but only thumbnails for
 the other participants, all sent in a single RTP session. The second
 scenarios occurs when audio and video flows are sent in a single RTP
 session, as discussed in [I-D.ietf-avtcore-multi-media-rtp-session].
 An RTP session has a single set of parameters that configure the
 session bandwidth, the RTCP sender and receiver fractions (e.g., via
 the SDP "b=RR:" and "b=RS:" lines), and the parameters of the RTP/
 AVPF profile [RFC4585] (e.g., trr-int) if that profile (or its secure
 extension, RTP/SAVPF [RFC5124]) is used. As a consequence, the RTCP
 reporting interval will be the same for every SSRC in an RTP session.
 This uniform RTCP reporting interval can result in RTCP reports being
 sent more often than is considered desirable for a particular media
 type. For example, if an audio flow is multiplexed with a high
 quality video flow where the session bandwidth is configured to match
 the video bandwidth, this can result in the RTCP packets having a
 greater bandwidth allocation than the audio data rate. If the
 reduced minimum RTCP interval described in Section 6.2 of [RFC3550]
 is used in the session, which might be appropriate for video where
 rapid feedback is wanted, the audio sources could be expected to send
 RTCP packets more often than they send audio data packets. This is
 most likely undesirable, and while the mismatch can be reduced
 through careful tuning of the RTCP parameters, particularly trr_int
 in RTP/AVPF sessions, it is inherent in the design of the RTCP timing
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 rules, and affects all RTP sessions containing flows with mismatched
 bandwidth.
 Having multiple media types in one RTP session also results in more
 SSRCs being present in this RTP session. This increasing the amount
 of cross reporting between the SSRCs. From an RTCP perspective, two
 RTP sessions with half the number of SSRCs in each will be slightly
 more efficient. If someone needs either the higher efficiency due to
 the lesser number of SSRCs or the fact that one can't tailor RTCP
 usage per media type, they need to use independent RTP sessions.
 When it comes to configuring RTCP the need for regular periodic
 reporting needs to be weighted against any feedback or control
 messages being sent. Applications using RTP/AVPF or RTP/SAVPF are
 RECOMMENDED to consider setting the trr-int parameter to a value
 suitable for the application's needs, thus potentially reducing the
 need for regular reporting and thus releasing more bandwidth for use
 for feedback or control.
 Another aspect of an RTP session with multiple media types is that
 the RTCP packets, RTCP Feedback Messages, or RTCP XR metrics used
 might not be applicable to all media types. Instead, all RTP/RTCP
 endpoints need to correlate the media type of the SSRC being
 referenced in a message or packet and only use those that apply to
 that particular SSRC and its media type. Signalling solutions might
 have shortcomings when it comes to indicating that a particular set
 of RTCP reports or feedback messages only apply to a particular media
 type within an RTP session.
6.1. Timing out SSRCs
 This section discusses issues around timing out SSRCs. After the
 discussion, clarified and mandated behavior for SSRC timeout is
 specified.
6.1.1. AVPF T_rr_interval Behavior
 The RTP/AVPF profile includes a mechanism for suppressing regular
 RTCP reporting from being sent unnecessarily frequently if sufficient
 RTCP bandwidth is configured. This mechanism is defined in
 Section 3.5.3 of [RFC4585], and can be summarized as follows: if less
 than a randomized T_rr_interval value has passed since the last
 regular report, and no feedback messages need to be sent, then the
 RTCP regular report is suppressed. The randomization is done by a
 linear randomizer in the interval 0.5 to 1.5 times T_rr_interval.
 The randomized T_rr_interval is recalculated after every transmitted
 regular packet, i.e when t_rr_last was updated. The benefit of the
 suppression mechanism is that it avoids wasting bandwidth when there
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 is nothing requiring frequent RTCP transmissions, but still allows
 utilization of the configured bandwidth when feedback is needed.
 Unfortunately this suppression mechanism has some behaviors that are
 less than ideal. First of all, the randomized T_rr_interval is
 distributed over a larger range than the actual transmission interval
 for RTCP would be if T_rr_interval and Td had the same value. The
 reconsideration mechanism and its compensation factor result in the
 actual RTCP transmission intervals for a Td having a distribution
 that is exponentially growing more likely with higher values, and is
 bounded to the interval [0.5/1.21828, 1.5/1.21828]*Td, i.e. with a Td
 value of 5 s [2.052, 6.156]. In comparison, the suppression acts in
 an interval that is 0.5 to 1.5 times the T_rr_interval, i.e. for
 T_rr_interval = 5 s this is [2.5, 7.5].
 The effect of the above is that the time period between two RTCP
 packets when using T_rr_interval suppression can become very long
 compared to the average input values. The longest time interval
 between one transmitted regular RTCP compound packet and the next
 when T_rr_interval suppression is being used are: First the maximum
 T_rr_interval, i.e. 1.5*T_rr_interval. Assuming that the last
 suppressed packet would have been sent at 1.5*T_rr_interval, the
 maximum interval until a packet can be sent under the regular
 scheduling is 1.5/1.21828*Td. Thus, the maximum time in total is
 1.5*T_rr_interval + 1.5/1.21828*Td.
 If Td and T_rr_interval have the same value, i.e. the minimal
 interval desired (T_rr_interval) and the actual actual average
 interval specified by the RTCP scheduling algorithm (Td) are the
 same, one might expect that RTCP packets would be sent according to
 the regular mechanism. Instead, this algorithm results in the RTCP
 packets being sent anywhere from 0.5*Td to ~2.731*Td. The
 probability distribution over that time is also non-trivial in its
 shape, somewhat similar to a saw tooth.
 Thus, we recommend that the AVPF regular transmission mechanism is
 revised in the future. This issue also has further implications as
 discussed in the next section.
6.1.2. Avoiding Pre-mature Timeout
 In RTP/AVP [RFC3550] the timeout behavior is simple and is 5 times
 Td, where Td is calculated with a Tmin value of 5 seconds. In other
 words, if the RTCP bandwidth allowed for an RTCP interval more
 frequent than every 5 seconds on average, then timeout happened after
 5*Td = 25 seconds of no activity from the SSRC (RTP or RTCP),
 otherwise it was 5 average reporting intervals.
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 RTP/AVPF [RFC4585] introduced two different behaviors depending on
 the value of T_rr_interval. When T_rr_interval was 0, it defaulted
 to the same Td calculation in RTP/AVP [RFC3550]. However, when
 T_rr_interval is non-zero the Tmin value become T_rr_interval in that
 calculation, most likely to enable speed up the detection of timed
 out SSRCs. However, using a non-zero T_rr_interval has two
 consequences for RTP's behavior.
 First, the number of actually sent RTCP packets for an SSRC that
 currently is not an active RTP sender can become very low due to the
 issue discussed above in Section 6.1.1. As the RTCP packet interval
 can be as long as 2.73*Td, then during a 5*Td time period an endpoint
 may in fact transmit only a single RTCP packet. The long intervals
 result in fewer RTCP packets, to a point where a one or two packet
 losses in RTCP result in timing out an SSRC.
 Second, the change also increased RTP/AVPF's brittleness to both
 packet loss and configuration errors. In many cases, when one
 desires to use RTP/AVPF for its feedback, one will ensure that RTCP
 is configured for more frequent transmissions on average than every 5
 seconds. Thus, many more RTP and RTCP packets can be transmitted
 during the time interval. Lets consider an implementation that would
 follow the AVP or AVPF with T_rr_interval = 0 rules for timeout, also
 when T_rr_interval is not zero. In such a case when the configured
 value of the T_rr_interval is significantly smaller than 5 seconds,
 e.g. less than 1 second, then a difference between using 0.1 seconds
 and 0.6 seconds has no significant impact on when an SSRC will be
 timed out. However, such a configuration difference between two
 endpoints following RFC 4585 will result in that the endpoint
 configured with T_rr_interval = 0.1 will frequently timeout SSRCs
 currently not sending RTP, from the endpoint configured with 0.6, as
 that is six times the Td value used by the endpoint configured with
 T_rr_interval=0.1, assuming sufficient bandwidth. For this reason
 such a change is implemented below in Section 6.1.4.
6.1.3. AVP and AVPF Interoperability
 If endpoints implementing the RTP/AVP and RTP/AVPF profiles (or their
 secure variants) are combined in a single RTP session, and the RTP/
 AVPF endpoints use a non-zero T_rr_interval that is significantly
 lower than 5 seconds, then there is a risk that the RTP/AVPF
 endpoints will prematurely timeout the RTP/AVP SSRCs due to their
 different RTCP timeout intervals. Conversely, if the RTP/AVPF
 endpoints use a T_rr_interval that is significant larger than 5
 seconds, there is a risk that the RTP/AVP endpoints will timeout the
 RTP/AVPF SSRCs.
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 If such mixed RTP profiles are used, (though this is NOT
 RECOMMENDED), and the AVPF endpoint is not updated to follow this
 specification, then the RTP/AVPF session SHOULD use a non-zero
 T_rr_interval that is 4 seconds.
 It might appear strange to use a T_rr_interval of 4 seconds. It
 might be intuitive that this value ought to be 5 seconds, as then
 both the RTP/AVP and RTP/AVPF would use the same timeout period.
 However, considering regular RTCP transmission and their packet
 intervals for RTP/AVPF its mean value will (with non-zero
 T_rr_interval) be larger than T_rr_interval due to the scheduling
 algorithm's behavior as discussed in Section 6.1.1. Thus, to enable
 an equal amount of regular RTCP transmissions in each directions
 between RTP/AVP and RTP/AVPF endpoints, taking the altered timeout
 intervals into account, the optimal value is around four (4), where
 almost four transmissions will on average occur in each direction
 between the different profile types given an otherwise good
 configuration of parameters in regards to T_rr_interval. If the RTCP
 bandwidth parameters are selected so that Td based on bandwidth is
 close to 4, i.e. close to T_rr_interval the risk increases that RTP/
 AVPF SSRCs will be timed out by RTP/AVP endpoints, as the RTP/AVPF
 SSRC might only manage two transmissions in the timeout period.
6.1.4. Specified Behavior
 The above considerations result in the following clarification and
 RTP/AVPF specification change.
 All SSRCs used in an RTP session MUST use the same timeout behaviour
 to avoid premature timeouts. This will depend on the RTP profile and
 its configuration. The RTP specification provides several options
 that can influence the values used when calculating the time
 interval. To avoid interoperability issues when using this
 specification, this document makes several clarifications to the
 calculations.
 For RTP/AVP, RTP/SAVP, RTP/AVPF, and RTP/SAVPF, the timeout interval
 SHALL be calculated using a multiplier of 5, i.e. the timeout
 interval becomes 5*Td. The Td calculation SHALL be done using a Tmin
 value of 5 seconds, not the reduced minimal interval even if used to
 calculate RTCP packet transmission intervals. This changes the
 behavior for the RTP/AVPF or RTP/SAVPF profiles when T_rr_interval !=
 0, a behavior defined in Section 3.5.4 of RFC 4585, i.e. Tmin in the
 Td calculation is the T_rr_interval.
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6.2. Tuning RTCP transmissions
 This sub-section discusses what tuning can be done to reduce the
 downsides of the shared RTCP packet intervals. First, it is
 considered what possibilites exist for the RTP/AVP [RFC3551] profile,
 then what additional tools are provided by RTP/AVPF [RFC4585].
6.2.1. RTP/AVP and RTP/SAVP
 When using the RTP/AVP or RTP/SAVP profiles the tuning one can do is
 very limited. The controls one has are limited to the RTCP bandwidth
 values and whether the minimum RTCP interval is scaled according to
 the bandwidth. As the scheduling algorithm includes both random
 factors and reconsideration, one can't simply calculate the expected
 average transmission interval using the formula for Td. But it does
 indicate the important factors affecting the transmission interval,
 namely the RTCP bandwidth available for the role (Active Sender or
 Participant), the average RTCP packet size, and the number of SSRCs
 classified in the relevant role. Note that if the ratio of senders
 to total number of session participants is larger than the ratio of
 RTCP bandwidth for senders in relation to the total RTCP bandwidth,
 then senders and receivers are treated together.
 Let's start with some basic observations:
 a. Unless the scaled minimum RTCP interval is used, then Td prior to
 randomization and reconsideration can never be less than 5
 seconds (assuming default Tmin of 5 seconds).
 b. If the scaled minimum RTCP interval is used, Td can become as low
 as 360 divided by RTP Session bandwidth in kilobits. In SDP the
 RTP session bandwidth is signalled using b=AS. An RTP Session
 bandwidth of 72 kbps results in Tmin being 5 seconds. An RTP
 session bandwidth of 360 kbps of course gives a Tmin of 1 second,
 and to achieve a Tmin equal to once every frame for a 25 Hz video
 stream requires an RTP session bandwidth of 9 Mbps! (The use of
 the RTP/AVPF or RTP/SAVPF profile allows a smaller Tmin, and
 hence more frequent RTCP reports, as discussed below).
 c. Let's calculate the number (n) of SSRCs in the RTP session that
 5% of the session bandwidth can support to yield a Td value equal
 to Tmin with minimal scaling. For this calculation we have to
 make two assumptions. The first is that we will consider most or
 all SSRC being senders, resulting in everyone sharing the
 available bandwidth. Secondly we will select an average RTCP
 packet size. This packet will consist of an SR, containing (n-1)
 report blocks up to 31 report blocks, and an SDES item with at
 least a CNAME (17 bytes in size) in it. Such a basic packet will
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 be 800 bytes for n>=32. With these parameters, and as the
 bandwidth goes up the time interval is proportionally decreased
 (due to minimal scaling), thus all the example bandwidths 72
 kbps, 360 kbps and 9 Mbps all support 9 SSRCs.
 d. The actual transmission interval for a Td value is
 [0.5*Td/1.21828,1.5*Td/1.21828], which means that for Td = 5
 seconds, the interval is actually [2.052,6.156] and the
 distribution is not uniform, but rather exponentially-increasing.
 The probability for sending at time X, given it is within the
 interval, is probability of picking X in the interval times the
 probability to randomly picking a number that is <=X within the
 interval with an uniform probability distribution. This results
 in that the majority of the probability mass is above the Td
 value.
 To conclude, with RTP/AVP and RTP/SAVP the key limitation for small
 unicast sessions is going to be the Tmin value. Thus the RTP session
 bandwidth configured in RTCP has to be sufficiently high to reach the
 reporting goals the application has following the rules for the
 scaled minimal RTCP interval.
6.2.2. RT/AVPF and RTP/SAVPF
 When using RTP/AVPF or RTP/SAVPF we get a quite powerful additional
 tool, the setting of the T_rr_interval which has several effects on
 the RTCP reporting. First of all as Tmin is set to 0 after the
 initial transmission, the regular reporting interval is instead
 determined by the regular bandwidth based calculation and the
 T_rr_interval. This has the effect that we are no longer restricted
 by the minimal interval or even the scaling rule for the minimal
 rule. Instead the RTCP bandwidth and the T_rr_interval are the
 governing factors.
 Now it also becomes important to separate between the application's
 need for regular reports and RTCP feedback packet types. In both
 regular RTCP mode, as in Early RTCP Mode, the usage of the
 T_rr_interval prevents regular RTCP packets, i.e. packets without any
 Feedback packets, to be sent more often than T_rr_interval. This
 value is applied to prevent any regular RTCP packet to be sent less
 than T_rr_interval times a uniformly distributed random value from
 the interval [0.5,1.5] after the previous regular packet packet. The
 random value recalculated after each regular RTCP packet
 transmission.
 So applications that have a use for feedback packets for some media
 streams, for example video streams, but don't want frequent regular
 reporting for audio, could configure the T_rr_interval to a value so
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 that the regular reporting for both audio and video is at a level
 that is considered acceptable for the audio. They could then use
 feedback packets, which will include RTCP SR/RR packets, unless
 reduced-size RTCP feedback packets [RFC5506] are used, and can
 include other report information in addition to the feedback packet
 that needs to be sent. That way the available RTCP bandwidth can be
 focused for the use which provides the most utility for the
 application.
 Using T_rr_interval still requires one to determine suitable values
 for the RTCP bandwidth value, in fact it might make it even more
 important, as this is more likely to affect the RTCP behaviour and
 performance than when using RTP/AVP, as there are fewer limitations
 affecting the RTCP transmission.
 When using T_rr_interval, i.e. having it be non zero, there are
 configurations that have to be avoided. If the resulting Td value is
 smaller but close to T_rr_interval then the interval in which the
 actual regular RTCP packet transmission falls into becomes very
 large, from 0.5 times T_rr_interval up to 2.73 times the
 T_rr_interval. Therefore for configuration where one intends to have
 Td smaller than T_rr_interval, then Td is RECOMMENDED to be targeted
 at values less than 1/4th of T_rr_interval which results in that the
 range becomes [0.5*T_rr_interval, 1.81*T_rr_interval].
 With RTP/AVPF, using a T_rr_interval of 0 or with another low value
 significantly lower than Td still has utility, and different
 behaviour compared to RTP/AVP. This avoids the Tmin limitations of
 RTP/AVP, thus allowing more frequent regular RTCP reporting. In fact
 this will result that the RTCP traffic becomes as high as the
 configured values.
 (tbd: a future version of this memo will include examples of how to
 choose RTCP parameters for common scenarios)
 There exists no method within the specification for using different
 regular RTCP reporting intervals depending on the media type or
 individual media stream.
. Security Considerations
 In the secure RTP protocol (SRTP) [RFC3711], the cryptographic
 context of a compound SRTCP packet is the SSRC of the sender of the
 first RTCP (sub-)packet. This could matter in some cases, especially
 for keying mechanisms such as Mikey [RFC3830] which allow use of per-
 SSRC keying.
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 Other than that, the standard security considerations of RTP apply;
 sending multiple media streams from a single endpoint does not appear
 to have different security consequences than sending the same number
 of streams.
. Open Issues
 At this stage this document contains a number of open issues. The
 below list tries to summarize the issues:
 1. Do we need to provide a recommendation for unicast session
 joiners with many sources to not use 0 initial minimal interval
 from bit-rate burst perspective?
 2. RTCP parameters for common scenarios in Section 6.2?
 3. Is scheduling algorithm working well with dynamic changes?
 4. Are the scheduling algorithm changes impacting previous
 implementations in such a way that the report aggregation has to
 be agreed on, and thus needs to be considered as an optimization?
 5. An open question is if any improvements or clarifications ought
 to be allowed regarding FB message scheduling in multi-SSRC
 endpoints.
. IANA Considerations
 No IANA actions needed.
. References
10.1. Normative References
 [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
 Requirement Levels", BCP 14, RFC 2119, March 1997.
 [RFC3550] Schulzrinne, H., Casner, S., Frederick, R., and V.
 Jacobson, "RTP: A Transport Protocol for Real-Time
 Applications", STD 64, RFC 3550, July 2003.
 [RFC3711] Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K.
 Norrman, "The Secure Real-time Transport Protocol (SRTP)",
 RFC 3711, March 2004.
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 [RFC4585] Ott, J., Wenger, S., Sato, N., Burmeister, C., and J. Rey,
 "Extended RTP Profile for Real-time Transport Control
 Protocol (RTCP)-Based Feedback (RTP/AVPF)", RFC 4585, July
 2006.
 [RFC5124] Ott, J. and E. Carrara, "Extended Secure RTP Profile for
 Real-time Transport Control Protocol (RTCP)-Based Feedback
 (RTP/SAVPF)", RFC 5124, February 2008.
 [RFC5506] Johansson, I. and M. Westerlund, "Support for Reduced-Size
 Real-Time Transport Control Protocol (RTCP): Opportunities
 and Consequences", RFC 5506, April 2009.
10.2. Informative References
 [I-D.ietf-avtcore-multi-media-rtp-session]
 Westerlund, M., Perkins, C., and J. Lennox, "Sending
 Multiple Types of Media in a Single RTP Session", draft-
 ietf-avtcore-multi-media-rtp-session-05 (work in
 progress), February 2014.
 [I-D.ietf-avtcore-rtp-multi-stream-optimisation]
 Lennox, J., Westerlund, M., Wu, W., and C. Perkins,
 "Sending Multiple Media Streams in a Single RTP Session:
 Grouping RTCP Reception Statistics and Other Feedback",
 draft-ietf-avtcore-rtp-multi-stream-optimisation-02 (work
 in progress), February 2014.
 [I-D.ietf-avtcore-rtp-topologies-update]
 Westerlund, M. and S. Wenger, "RTP Topologies", draft-
 ietf-avtcore-rtp-topologies-update-02 (work in progress),
 May 2014.
 [I-D.ietf-clue-framework]
 Duckworth, M., Pepperell, A., and S. Wenger, "Framework
 for Telepresence Multi-Streams", draft-ietf-clue-
 framework-15 (work in progress), May 2014.
 [I-D.ietf-mmusic-sdp-bundle-negotiation]
 Holmberg, C., Alvestrand, H., and C. Jennings,
 "Negotiating Media Multiplexing Using the Session
 Description Protocol (SDP)", draft-ietf-mmusic-sdp-bundle-
 negotiation-07 (work in progress), April 2014.
 [RFC3551] Schulzrinne, H. and S. Casner, "RTP Profile for Audio and
 Video Conferences with Minimal Control", STD 65, RFC 3551,
 July 2003.
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Internet-Draft Multiple Media Streams in an RTP Session May 2014
 [RFC3611] Friedman, T., Caceres, R., and A. Clark, "RTP Control
 Protocol Extended Reports (RTCP XR)", RFC 3611, November
 2003.
 [RFC3830] Arkko, J., Carrara, E., Lindholm, F., Naslund, M., and K.
 Norrman, "MIKEY: Multimedia Internet KEYing", RFC 3830,
 August 2004.
 [RFC4588] Rey, J., Leon, D., Miyazaki, A., Varsa, V., and R.
 Hakenberg, "RTP Retransmission Payload Format", RFC 4588,
 July 2006.
 [RFC6190] Wenger, S., Wang, Y., Schierl, T., and A. Eleftheriadis,
 "RTP Payload Format for Scalable Video Coding", RFC 6190,
 May 2011.
Appendix A. Changes From Earlier Versions
 Note to the RFC-Editor: please remove this section prior to
 publication as an RFC.
A.1. Changes From WG Draft -02
 o Changed usage of Media Stream
 o Added Updates RFC 4585
 o Added rules for how to deal with RTCP when aggregating multiple
 SSRCs report in same compound packet:
 * avg_rtcp_size calcualtion
 * Scheduling rules to maintain timing
 o Started a section clarifying and discsussing RTP/AVPF Feedback
 Packets and their scheduling.
A.2. Changes From WG Draft -01
 o None, a keep-alive version
A.3. Changes From WG Draft -00
 o Split the Reporting Group Extension from this draft into draft-
 ietf-avtcore-rtp-multi-stream-optimization-00.
 o Added RTCP tuning considerations from draft-ietf-avtcore-multi-
 media-rtp-session-02.
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A.4. Changes From Individual Draft -02
 o Resubmitted as working group draft.
 o Updated references.
A.5. Changes From Individual Draft -01
 o Merged with draft-wu-avtcore-multisrc-endpoint-adver.
 o Changed how Reporting Groups are indicated in RTCP, to make it
 clear which source(s) is the group's reporting sources.
 o Clarified the rules for when sources can be placed in the same
 reporting group.
 o Clarified that mixers and translators need to pass reporting group
 SDES information if they are forwarding RR and SR traffic from
 members of a reporting group.
A.6. Changes From Individual Draft -00
 o Added the Reporting Group semantic to explicitly indicate which
 sources come from a single endpoint, rather than leaving it
 implicit.
 o Specified that Reporting Group semantics (as they now are) apply
 to AVPF and XR, as well as to RR/SR report blocks.
 o Added a description of the cascaded source-projecting mixer, along
 with a calculation of its RTCP overhead if reporting groups are
 not in use.
 o Gave some guidance on how the flexibility of RTCP randomization
 allows some freedom in RTCP multiplexing.
 o Clarified the language of several of the recommendations.
 o Added an open issue discussing how avg_rtcp_size ought to be
 calculated for multiplexed RTCP.
 o Added an open issue discussing how RTCP bandwidths are to be
 chosen for sessions where source bandwidths greatly differ.
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Authors' Addresses
 Jonathan Lennox
 Vidyo, Inc.
 433 Hackensack Avenue
 Seventh Floor
 Hackensack, NJ 07601
 US
 Email: jonathan@vidyo.com
 Magnus Westerlund
 Ericsson
 Farogatan 6
 SE-164 80 Kista
 Sweden
 Phone: +46 10 714 82 87
 Email: magnus.westerlund@ericsson.com
 Qin Wu
 Huawei
 101 Software Avenue, Yuhua District
 Nanjing, Jiangsu 210012
 China
 Email: sunseawq@huawei.com
 Colin Perkins
 University of Glasgow
 School of Computing Science
 Glasgow G12 8QQ
 United Kingdom
 Email: csp@csperkins.org
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