From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc6190.txt | 5603 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 5603 insertions(+) create mode 100644 doc/rfc/rfc6190.txt (limited to 'doc/rfc/rfc6190.txt') diff --git a/doc/rfc/rfc6190.txt b/doc/rfc/rfc6190.txt new file mode 100644 index 0000000..152a8d0 --- /dev/null +++ b/doc/rfc/rfc6190.txt @@ -0,0 +1,5603 @@ + + + + + + +Internet Engineering Task Force (IETF) S. Wenger +Request for Comments: 6190 Independent +Category: Standards Track Y.-K. Wang +ISSN: 2070-1721 Huawei Technologies + T. Schierl + Fraunhofer HHI + A. Eleftheriadis + Vidyo + May 2011 + + + RTP Payload Format for Scalable Video Coding + +Abstract + + This memo describes an RTP payload format for Scalable Video Coding + (SVC) as defined in Annex G of ITU-T Recommendation H.264, which is + technically identical to Amendment 3 of ISO/IEC International + Standard 14496-10. The RTP payload format allows for packetization + of one or more Network Abstraction Layer (NAL) units in each RTP + packet payload, as well as fragmentation of a NAL unit in multiple + RTP packets. Furthermore, it supports transmission of an SVC stream + over a single as well as multiple RTP sessions. The payload format + defines a new media subtype name "H264-SVC", but is still backward + compatible to RFC 6184 since the base layer, when encapsulated in its + own RTP stream, must use the H.264 media subtype name ("H264") and + the packetization method specified in RFC 6184. The payload format + has wide applicability in videoconferencing, Internet video + streaming, and high-bitrate entertainment-quality video, among + others. + +Status of This Memo + + This is an Internet Standards Track document. + + This document is a product of the Internet Engineering Task Force + (IETF). It represents the consensus of the IETF community. It has + received public review and has been approved for publication by the + Internet Engineering Steering Group (IESG). Further information on + Internet Standards is available in Section 2 of RFC 5741. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + http://www.rfc-editor.org/info/rfc6190. + + + + + + + +Wenger, et al. Standards Track [Page 1] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +Copyright Notice + + Copyright (c) 2011 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 + include Simplified BSD License text as described in Section 4.e of + the Trust Legal Provisions and are provided without warranty as + described in the Simplified BSD License. + + This document may contain material from IETF Documents or IETF + Contributions published or made publicly available before November + 10, 2008. The person(s) controlling the copyright in some of this + material may not have granted the IETF Trust the right to allow + modifications of such material outside the IETF Standards Process. + Without obtaining an adequate license from the person(s) controlling + the copyright in such materials, this document may not be modified + outside the IETF Standards Process, and derivative works of it may + not be created outside the IETF Standards Process, except to format + it for publication as an RFC or to translate it into languages other + than English. + + + + + + + + + + + + + + + + + + + + + + + + + +Wenger, et al. Standards Track [Page 2] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +Table of Contents + + 1. Introduction ....................................................5 + 1.1. The SVC Codec ..............................................6 + 1.1.1. Overview ............................................6 + 1.1.2. Parameter Sets ......................................8 + 1.1.3. NAL Unit Header .....................................9 + 1.2. Overview of the Payload Format ............................12 + 1.2.1. Design Principles ..................................12 + 1.2.2. Transmission Modes and Packetization Modes .........13 + 1.2.3. New Payload Structures .............................15 + 2. Conventions ....................................................16 + 3. Definitions and Abbreviations ..................................16 + 3.1. Definitions ...............................................16 + 3.1.1. Definitions from the SVC Specification .............16 + 3.1.2. Definitions Specific to This Memo ..................18 + 3.2. Abbreviations .............................................22 + 4. RTP Payload Format .............................................23 + 4.1. RTP Header Usage ..........................................23 + 4.2. NAL Unit Extension and Header Usage .......................23 + 4.2.1. NAL Unit Extension .................................23 + 4.2.2. NAL Unit Header Usage ..............................24 + 4.3. Payload Structures ........................................25 + 4.4. Transmission Modes ........................................28 + 4.5. Packetization Modes .......................................28 + 4.5.1. Packetization Modes for Single-Session + Transmission .......................................28 + 4.5.2. Packetization Modes for Multi-Session + Transmission .......................................29 + 4.6. Single NAL Unit Packets ...................................32 + 4.7. Aggregation Packets .......................................33 + 4.7.1. Non-Interleaved Multi-Time Aggregation + Packets (NI-MTAPs) .................................33 + 4.8. Fragmentation Units (FUs) .................................35 + 4.9. Payload Content Scalability Information (PACSI) NAL Unit ..35 + 4.10. Empty NAL unit ...........................................43 + 4.11. Decoding Order Number (DON) ..............................43 + 4.11.1. Cross-Session DON (CS-DON) for + Multi-Session Transmission ........................43 + 5. Packetization Rules ............................................45 + 5.1. Packetization Rules for Single-Session Transmission .......45 + 5.2. Packetization Rules for Multi-Session Transmission ........46 + 5.2.1. NI-T/NI-TC Packetization Rules .....................47 + 5.2.2. NI-C/NI-TC Packetization Rules .....................49 + 5.2.3. I-C Packetization Rules ............................50 + 5.2.4. Packetization Rules for Non-VCL NAL Units ..........50 + 5.2.5. Packetization Rules for Prefix NAL Units ...........51 + + + + +Wenger, et al. Standards Track [Page 3] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + 6. De-Packetization Process .......................................51 + 6.1. De-Packetization Process for Single-Session Transmission ..51 + 6.2. De-Packetization Process for Multi-Session Transmission ...51 + 6.2.1. Decoding Order Recovery for the NI-T and + NI-TC Modes ........................................52 + 6.2.1.1. Informative Algorithm for NI-T + Decoding Order Recovery within + an Access Unit ............................55 + 6.2.2. Decoding Order Recovery for the NI-C, + NI-TC, and I-C Modes ...............................57 + 7. Payload Format Parameters ......................................59 + 7.1. Media Type Registration ...................................60 + 7.2. SDP Parameters ............................................75 + 7.2.1. Mapping of Payload Type Parameters to SDP ..........75 + 7.2.2. Usage with the SDP Offer/Answer Model ..............76 + 7.2.3. Dependency Signaling in Multi-Session + Transmission .......................................84 + 7.2.4. Usage in Declarative Session Descriptions ..........85 + 7.3. Examples ..................................................86 + 7.3.1. Example for Offering a Single SVC Session ..........86 + 7.3.2. Example for Offering a Single SVC Session Using + scalable-layer-id ..................................87 + 7.3.3. Example for Offering Multiple Sessions in MST ......87 + 7.3.4. Example for Offering Multiple Sessions in + MST Including Operation with Answerer Using + scalable-layer-id ..................................89 + 7.3.5. Example for Negotiating an SVC Stream with + a Constrained Base Layer in SST ....................90 + 7.4. Parameter Set Considerations ..............................91 + 8. Security Considerations ........................................91 + 9. Congestion Control .............................................92 + 10. IANA Considerations ...........................................93 + 11. Informative Appendix: Application Examples ....................93 + 11.1. Introduction .............................................93 + 11.2. Layered Multicast ........................................93 + 11.3. Streaming ................................................94 + 11.4. Videoconferencing (Unicast to MANE, Unicast to + Endpoints) ...............................................95 + 11.5. Mobile TV (Multicast to MANE, Unicast to Endpoint) .......96 + 12. Acknowledgements ..............................................97 + 13. References ....................................................97 + 13.1. Normative References .....................................97 + 13.2. Informative References ...................................98 + + + + + + + + +Wenger, et al. Standards Track [Page 4] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +1. Introduction + + This memo specifies an RTP [RFC3550] payload format for the Scalable + Video Coding (SVC) extension of the H.264/AVC video coding standard. + SVC is specified in Amendment 3 to ISO/IEC 14496 Part 10 + [ISO/IEC14496-10] and equivalently in Annex G of ITU-T Rec. H.264 + [H.264]. In this memo, unless explicitly stated otherwise, + "H.264/AVC" refers to the specification of [H.264] excluding Annex G. + + SVC covers the entire application range of H.264/AVC, from low- + bitrate mobile applications, to High-Definition Television (HDTV) + broadcasting, and even Digital Cinema that requires nearly lossless + coding and hundreds of megabits per second. The scalability features + that SVC adds to H.264/AVC enable several system-level + functionalities related to the ability of a system to adapt the + signal to different system conditions with no or minimal processing. + The adaptation relates both to the capabilities of potentially + heterogeneous receivers (differing in screen resolution, processing + speed, etc.), and to differing or time-varying network conditions. + The adaptation can be performed at the source, the destination, or in + intermediate media-aware network elements (MANEs). The payload + format specified in this memo exposes these system-level + functionalities so that system designers can take direct advantage of + these features. + + Informative note: Since SVC streams contain, by design, a sub- + stream that is compliant with H.264/AVC, it is trivial for a MANE + to filter the stream so that all SVC-specific information is + removed. This memo, in fact, defines a media type parameter + (sprop-avc-ready, Section 7.2) that indicates whether or not the + stream can be converted to one compliant with [RFC6184] by + eliminating RTP packets, and rewriting RTP Control Protocol (RTCP) + to match the changes to the RTP packet stream as specified in + Section 7 of [RFC3550]. + + This memo defines two basic modes for transmission of SVC data, + single-session transmission (SST) and multi-session transmission + (MST). In SST, a single RTP session is used for the transmission of + all scalability layers comprising an SVC bitstream; in MST, the + scalability layers are transported on different RTP sessions. In + SST, packetization is a straightforward extension of [RFC6184]. For + MST, four different modes are defined in this memo. They differ on + whether or not they allow interleaving, i.e., transmitting Network + Abstraction Layer (NAL) units in an order different than the decoding + order, and by the technique used to effect inter-session NAL unit + decoding order recovery. Decoding order recovery is performed using + either inter-session timestamp alignment [RFC3550] or cross-session + decoding order numbers (CS-DONs). One of the MST modes supports both + + + +Wenger, et al. Standards Track [Page 5] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + decoding order recovery techniques, so that receivers can select + their preferred technique. More details can be found in Section + 1.2.2. + + This memo further defines three new NAL unit types. The first type + is the payload content scalability information (PACSI) NAL unit, + which is used to provide an informative summary of the scalability + information of the data contained in an RTP packet, as well as + ancillary data (e.g., CS-DON values). The second and third new NAL + unit types are the empty NAL unit and the non-interleaved multi-time + aggregation packet (NI-MTAP) NAL unit. The empty NAL unit is used to + ensure inter-session timestamp alignment required for decoding order + recovery in MST. The NI-MTAP is used as a new payload structure + allowing the grouping of NAL units of different time instances in + decoding order. More details about the new packet structures can be + found in Section 1.2.3. + + This memo also defines the signaling support for SVC transport over + RTP, including a new media subtype name (H264-SVC). + + A non-normative overview of the SVC codec and the payload is given in + the remainder of this section. + +1.1. The SVC Codec + +1.1.1. Overview + + SVC defines a coded video representation in which a given bitstream + offers representations of the source material at different levels of + fidelity (hence the term "scalable"). Scalable video coding + bitstreams, or scalable bitstreams, are constructed in a pyramidal + fashion: the coding process creates bitstream components that improve + the fidelity of hierarchically lower components. + + The fidelity dimensions offered by SVC are spatial (picture size), + quality (or Signal-to-Noise Ratio (SNR)), and temporal (pictures per + second). Bitstream components associated with a given level of + spatial, quality, and temporal fidelity are identified using + corresponding parameters in the bitstream: dependency_id, quality_id, + and temporal_id (see also Section 1.1.3). The fidelity identifiers + have integer values, where higher values designate components that + are higher in the hierarchy. It is noted that SVC offers significant + flexibility in terms of how an encoder may choose to structure the + dependencies between the various components. Decoding of a + particular component requires the availability of all the components + it depends upon, either directly, or indirectly. An operation point + + + + + +Wenger, et al. Standards Track [Page 6] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + of an SVC bitstream consists of the bitstream components required to + be able to decode a particular dependency_id, quality_id, and + temporal_id combination. + + The term "layer" is used in various contexts in this memo. For + example, in the terms "Video Coding Layer" and "Network Abstraction + Layer" it refers to conceptual organization levels. When referring + to bitstream syntax elements such as block layer or macroblock layer, + it refers to hierarchical bitstream structure levels. When used in + the context of bitstream scalability, e.g., "AVC base layer", it + refers to a level of representation fidelity of the source signal + with a specific set of NAL units included. The correct + interpretation is supported by providing the appropriate context. + + SVC maintains the bitstream organization introduced in H.264/AVC. + Specifically, all bitstream components are encapsulated in Network + Abstraction Layer (NAL) units, which are organized as Access Units + (AUs). An AU is associated with a single sampling instance in time. + A subset of the NAL unit types correspond to the Video Coding Layer + (VCL), and contain the coded picture data associated with the source + content. Non-VCL NAL units carry ancillary data that may be + necessary for decoding (e.g., parameter sets as explained below) or + that facilitate certain system operations but are not needed by the + decoding process itself. Coded picture data at the various fidelity + dimensions are organized in slices. Within one AU, a coded picture + of an operation point consists of all the coded slices required for + decoding up to the particular combination of dependency_id and + quality_id values at the time instance corresponding to the AU. + + It is noted that the concept of temporal scalability is already + present in H.264/AVC, as profiles defined in Annex A of [H.264] + already support it. Specifically, in H.264/AVC, the concept of sub- + sequences has been introduced to allow optional use of temporal + layers through Supplemental Enhancement Information (SEI) messages. + SVC extends this approach by exposing the temporal scalability + information using the temporal_id parameter, alongside (and unified + with) the dependency_id and quality_id values that are used for + spatial and quality scalability, respectively. For coded picture + data defined in Annex G of [H.264], this is accomplished by using a + new type of NAL unit, namely, coded slice in scalable extension NAL + unit (type 20), where the fidelity parameters are part of its header. + For coded picture data that follow H.264/AVC, and to ensure + compatibility with existing H.264/AVC decoders, another new type of + NAL unit, namely, prefix NAL unit (type 14), has been defined to + carry this header information. SVC additionally specifies a third + new type of NAL unit, namely, subset sequence parameter set NAL unit + (type 15), to contain sequence parameter set information for quality + and spatial enhancement layers. All these three newly specified NAL + + + +Wenger, et al. Standards Track [Page 7] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + unit types (14, 15, and 20) are among those reserved in H.264/AVC and + are to be ignored by decoders conforming to one or more of the + profiles specified in Annex A of [H.264]. + + Within an AU, the VCL NAL units associated with a given dependency_id + and quality_id are referred to as a "layer representation". The + layer representation corresponding to the lowest values of + dependency_id and quality_id (i.e., zero for both) is compliant by + design to H.264/AVC. The set of VCL and associated non-VCL NAL units + across all AUs in a bitstream associated with a particular + combination of values of dependency_id and quality_id, and regardless + of the value of temporal_id, is conceptually a scalable layer. For + backward compatibility with H.264/AVC, it is important to + differentiate, however, whether or not SVC-specific NAL units are + present in a given bitstream. This is particularly important for the + lowest fidelity values in terms of dependency_id and quality_id (zero + for both), as the corresponding VCL data are compliant with + H.264/AVC, and may or may not be accompanied by associated prefix NAL + units. This memo therefore uses the term "AVC base layer" to + designate the layer that does not contain SVC-specific NAL units, and + "SVC base layer" to designate the same layer but with the addition of + the associated SVC prefix NAL units. Note that the SVC specification + uses the term "base layer" for what in this memo will be referred to + as "AVC base layer". Similarly, it is also important to be able to + differentiate, within a layer, the temporal fidelity components it + contains. This memo uses the term "T0" to indicate, within a + particular layer, the subset that contains the NAL units associated + with temporal_id equal to 0. + + SNR scalability in SVC is offered in two different ways. In what is + called coarse-grain scalability (CGS), scalability is provided by + including or excluding a complete layer when decoding a particular + bitstream. In contrast, in medium-grain scalability (MGS), + scalability is provided by selectively omitting the decoding of + specific NAL units belonging to MGS layers. The selection of the NAL + units to omit can be based on fixed-length fields present in the NAL + unit header (see also Sections 1.1.3 and 4.2). + +1.1.2. Parameter Sets + + SVC maintains the parameter sets concept in H.264/AVC and introduces + a new type of sequence parameter set, referred to as the subset + sequence parameter set [H.264]. Subset sequence parameter sets have + NAL unit type equal to 15, which is different from the NAL unit type + value (7) of sequence parameter sets. VCL NAL units of NAL unit type + 1 to 5 must only (indirectly) refer to sequence parameter sets, while + VCL NAL units of NAL unit type 20 must only (indirectly) refer to + subset sequence parameter sets. The references are indirect because + + + +Wenger, et al. Standards Track [Page 8] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + VCL NAL units refer to picture parameter sets (in their slice + header), which in turn refer to regular or subset sequence parameter + sets. Subset sequence parameter sets use a separate identifier value + space than sequence parameter sets. + + In SVC, coded picture data from different layers may use the same or + different sequence and picture parameter sets. Let the variable DQId + be equal to dependency_id * 16 + quality_id. At any time instant + during the decoding process there is one active sequence parameter + set for the layer representation with the highest value of DQId and + one or more active layer SVC sequence parameter set(s) for layer + representations with lower values of DQId. The active sequence + parameter set or an active layer SVC sequence parameter set remains + unchanged throughout a coded video sequence in the scalable layer in + which the active sequence parameter set or active layer SVC sequence + parameter set is referred to. This means that the referred sequence + parameter set or subset sequence parameter set can only change at + instantaneous decoding refresh (IDR) access units for any layer. At + any time instant during the decoding process there may be one active + picture parameter set (for the layer representation with the highest + value of DQId) and one or more active layer picture parameter set(s) + (for layer representations with lower values of DQId). The active + picture parameter set or an active layer picture parameter set + remains unchanged throughout a layer representation in which the + active picture parameter set or active layer picture parameter set is + referred to, but may change from one AU to the next. + +1.1.3. NAL Unit Header + + SVC extends the one-byte H.264/AVC NAL unit header by three + additional octets for NAL units of types 14 and 20. The header + indicates the type of the NAL unit, the (potential) presence of bit + errors or syntax violations in the NAL unit payload, information + regarding the relative importance of the NAL unit for the decoding + process, the layer identification information, and other fields as + discussed below. + + The syntax and semantics of the NAL unit header are specified in + [H.264], but the essential properties of the NAL unit header are + summarized below for convenience. + + The first byte of the NAL unit header has the following format (the + bit fields are the same as defined for the one-byte H.264/AVC NAL + unit header, while the semantics of some fields have changed + slightly, in a backward-compatible way): + + + + + + +Wenger, et al. Standards Track [Page 9] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + +---------------+ + |0|1|2|3|4|5|6|7| + +-+-+-+-+-+-+-+-+ + |F|NRI| Type | + +---------------+ + + The semantics of the components of the NAL unit type octet, as + specified in [H.264], are described briefly below. In addition to + the name and size of each field, the corresponding syntax element + name in [H.264] is also provided. + + F: 1 bit + forbidden_zero_bit. H.264/AVC declares a value of 1 as a + syntax violation. + + NRI: 2 bits + nal_ref_idc. A value of "00" (in binary form) indicates that + the content of the NAL unit is not used to reconstruct + reference pictures for future prediction. Such NAL units can + be discarded without risking the integrity of the reference + pictures in the same layer. A value greater than "00" + indicates that the decoding of the NAL unit is required to + maintain the integrity of reference pictures in the same layer + or that the NAL unit contains parameter sets. + + Type: 5 bits + nal_unit_type. This component specifies the NAL unit type as + defined in Table 7-1 of [H.264], and later within this memo. + For a reference of all currently defined NAL unit types and + their semantics, please refer to Section 7.4.1 in [H.264]. + + In H.264/AVC, NAL unit types 14, 15, and 20 are reserved for + future extensions. SVC uses these three NAL unit types as + follows: NAL unit type 14 is used for prefix NAL unit, NAL unit + type 15 is used for subset sequence parameter set, and NAL unit + type 20 is used for coded slice in scalable extension (see + Section 7.4.1 in [H.264]). NAL unit types 14 and 20 indicate + the presence of three additional octets in the NAL unit header, + as shown below. + + +---------------+---------------+---------------+ + |0|1|2|3|4|5|6|7|0|1|2|3|4|5|6|7|0|1|2|3|4|5|6|7| + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |R|I| PRID |N| DID | QID | TID |U|D|O| RR| + +---------------+---------------+---------------+ + + + + + + +Wenger, et al. Standards Track [Page 10] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + R: 1 bit + reserved_one_bit. Reserved bit for future extension. R must + be equal to 1. The value of R must be ignored by decoders. + + I: 1 bit + idr_flag. This component specifies whether the layer + representation is an instantaneous decoding refresh (IDR) layer + representation (when equal to 1) or not (when equal to 0). + + PRID: 6 bits + priority_id. This flag specifies a priority identifier for the + NAL unit. A lower value of PRID indicates a higher priority. + + N: 1 bit + no_inter_layer_pred_flag. This flag specifies, when present in + a coded slice NAL unit, whether inter-layer prediction may be + used for decoding the coded slice (when equal to 1) or not + (when equal to 0). + + DID: 3 bits + dependency_id. This component indicates the inter-layer coding + dependency level of a layer representation. At any access + unit, a layer representation with a given dependency_id may be + used for inter-layer prediction for coding of a layer + representation with a higher dependency_id, while a layer + representation with a given dependency_id shall not be used for + inter-layer prediction for coding of a layer representation + with a lower dependency_id. + + QID: 4 bits + quality_id. This component indicates the quality level of an + MGS layer representation. At any access unit and for identical + dependency_id values, a layer representation with quality_id + equal to ql uses a layer representation with quality_id equal + to ql-1 for inter-layer prediction. + + TID: 3 bits + temporal_id. This component indicates the temporal level of a + layer representation. The temporal_id is associated with the + frame rate, with lower values of _temporal_id corresponding to + lower frame rates. A layer representation at a given + temporal_id typically depends on layer representations with + lower temporal_id values, but it never depends on layer + representations with higher temporal_id values. + + + + + + + +Wenger, et al. Standards Track [Page 11] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + U: 1 bit + use_ref_base_pic_flag. A value of 1 indicates that only + reference base pictures are used during the inter prediction + process. A value of 0 indicates that the reference base + pictures are not used during the inter prediction process. + + D: 1 bit + discardable_flag. A value of 1 indicates that the current NAL + unit is not used for decoding NAL units with values of + dependency_id higher than the one of the current NAL unit, in + the current and all subsequent access units. Such NAL units + can be discarded without risking the integrity of layers with + higher dependency_id values. discardable_flag equal to 0 + indicates that the decoding of the NAL unit is required to + maintain the integrity of layers with higher dependency_id. + + O: 1 bit + output_flag: Affects the decoded picture output process as + defined in Annex C of [H.264]. + + RR: 2 bits + reserved_three_2bits. Reserved bits for future extension. RR + MUST be equal to "11" (in binary form). The value of RR must + be ignored by decoders. + + This memo extends the semantics of F, NRI, I, PRID, DID, QID, TID, U, + and D per Annex G of [H.264] as described in Section 4.2. + +1.2. Overview of the Payload Format + + Similar to [RFC6184], this payload format can only be used to carry + the raw NAL unit stream over RTP and not the bytestream format + specified in Annex B of [H.264]. + + The design principles, transmission modes, and packetization modes as + well as new payload structures are summarized in this section. It is + assumed that the reader is familiar with the terminology and concepts + defined in [RFC6184]. + +1.2.1. Design Principles + + The following design principles have been observed for this payload + format: + + o Backward compatibility with [RFC6184] wherever possible. + + + + + + +Wenger, et al. Standards Track [Page 12] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o The SVC base layer or any H.264/AVC compatible subset of the SVC + base layer, when transmitted in its own RTP stream, must be + encapsulated using [RFC6184]. This ensures that such an RTP + stream can be understood by [RFC6184] receivers. + + o Media-aware network elements (MANEs) as defined in [RFC6184] are + signaling-aware, rely on signaling information, and have state. + + o MANEs can aggregate multiple RTP streams, possibly from multiple + RTP sessions. + + o MANEs can perform media-aware stream thinning (selective + elimination of packets or portions thereof). By using the payload + header information identifying layers within an RTP session, MANEs + are able to remove packets or portions thereof from the incoming + RTP packet stream. This implies rewriting the RTP headers of the + outgoing packet stream, and rewriting of RTCP packets as specified + in Section 7 of [RFC3550]. + +1.2.2. Transmission Modes and Packetization Modes + + This memo allows the packetization of SVC data for both single- + session transmission (SST) and multi-session transmission (MST). In + the case of SST all SVC data are carried in a single RTP session. In + the case of MST two or more RTP sessions are used to carry the SVC + data, in accordance with the MST-specific packetization modes defined + in this memo, which are based on the packetization modes defined in + [RFC6184]. In MST, each RTP session is associated with one RTP + stream, which may carry one or more layers. + + The base layer is, by design, compatible to H.264/AVC. During + transmission, the associated prefix NAL units, which are introduced + by SVC and, when present, are ignored by H.264/AVC decoders, may be + encapsulated within the same RTP packet stream as the H.264/AVC VCL + NAL units or in a different RTP packet stream (when MST is used). + For convenience, the term "AVC base layer" is used to refer to the + base layer without prefix NAL units, while the term "SVC base layer" + is used to refer to the base layer with prefix NAL units. + + Furthermore, the base layer may have multiple temporal components + (i.e., supporting different frame rates). As a result, the lowest + temporal component ("T0") of the AVC or SVC base layer is used as the + starting point of the SVC bitstream hierarchy. + + This memo allows encapsulating in a given RTP stream any of the + following three alternatives of layer combinations: + + + + + +Wenger, et al. Standards Track [Page 13] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + 1. the T0 AVC base layer or the T0 SVC base layer only; + 2. one or more enhancement layers only; or + 3. the T0 SVC base layer, and one or more enhancement layers. + + SST should be used in point-to-point unicast applications and, in + general, whenever the potential benefit of using multiple RTP + sessions does not justify the added complexity. When SST is used, + the layer combination cases 1 and 3 above can be used. When an + H.264/AVC compatible subset of the SVC base layer is transmitted + using SST, the packetization of [RFC6184] must be used, thus ensuring + compatibility with [RFC6184] receivers. When, however, one or more + SVC quality or spatial enhancement layers are transmitted using SST, + the packetization defined in this memo must be used. In SST, any of + the three [RFC6184] packetization modes, namely, single NAL unit + mode, non-interleaved mode, and interleaved mode, can be used. + + MST should be used in a multicast session when different receivers + may request different layers of the scalable bitstream. An operation + point for an SVC bitstream, as defined in this memo, corresponds to a + set of layers that together conform to one of the profiles defined in + Annex A or G of [H.264] and, when decoded, offer a representation of + the original video at a certain fidelity. The number of streams used + in MST should be at least equal to the number of operation points + that may be requested by the receivers. Depending on the + application, this may result in each layer being carried in its own + RTP session, or in having multiple layers encapsulated within one RTP + session. + + Informative note: Layered multicast is a term commonly used to + describe the application where multicast is used to transmit + layered or scalable data that has been encapsulated into more than + one RTP session. This application allows different receivers in + the multicast session to receive different operation points of the + scalable bitstream. Layered multicast, among other application + examples, is discussed in more detail in Section 11.2. + + When MST is used, any of the three layer combinations above can be + used for each of the sessions. When an H.264/AVC compatible subset + of the SVC base layer is transmitted in its own session in MST, the + packetization of [RFC6184] must be used, such that [RFC6184] + receivers can be part of the MST and receive only this session. For + MST, this memo defines four different MST-specific packetization + modes, namely, non-interleaved timestamp (NI-T) based mode, non- + interleaved CS-DON (NI-C) based mode, non-interleaved combined + timestamp and CS-DON mode (NI-TC), and interleaved CS-DON (I-C) based + mode (detailed in Section 4.5.2). The modes differ depending on + whether the SVC data are allowed to be interleaved, i.e., to be + transmitted in an order different than the intended decoding order, + + + +Wenger, et al. Standards Track [Page 14] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + and they also differ in the mechanisms provided in order to recover + the correct decoding order of the NAL units across the multiple RTP + sessions. These four MST modes reuse the packetization modes + introduced in [RFC6184] for the packetization of NAL units in each of + their individual RTP sessions. + + As the names of the MST packetization modes imply, the NI-T, NI-C, + and NI-TC modes do not allow interleaved transmission, while the I-C + mode allows interleaved transmission. With any of the three non- + interleaved MST packetization modes, legacy [RFC6184] receivers with + implementation of the non-interleaved mode specified in [RFC6184] can + join a multi-session transmission of SVC, to receive the base RTP + session encapsulated according to [RFC6184]. + +1.2.3. New Payload Structures + + [RFC6184] specifies three basic payload structures, namely, single + NAL unit packet, aggregation packet, and fragmentation unit. + Depending on the basic payload structure, an RTP packet may contain a + NAL unit not aggregating other NAL units, one or more NAL units + aggregated in another NAL unit, or a fragment of a NAL unit not + aggregating other NAL units. Each NAL unit of a type specified in + [H.264] (i.e., 1 to 23, inclusive) may be carried in its entirety in + a single NAL unit packet, may be aggregated in an aggregation packet, + or may be fragmented and carried in a number of fragmentation unit + packets. To enable aggregation or fragmentation of NAL units while + still ensuring that the RTP packet payload is only composed of NAL + units, [RFC6184] introduced six new NAL unit types (24-29) to be used + as payload structures, selected from the NAL unit types left + unspecified in [H.264]. + + This memo reuses all the payload structures used in [RFC6184]. + Furthermore, three new types of NAL units are defined: payload + content scalability information (PACSI) NAL unit, empty NAL unit, and + non-interleaved multi-time aggregation packet (NI-MTAP) (specified in + Sections 4.9, 4.10, and 4.7.1, respectively). + + PACSI NAL units may be used for the following purposes: + + o To enable MANEs to decide whether to forward, process, or discard + aggregation packets, by checking in PACSI NAL units the + scalability information and other characteristics of the + aggregated NAL units, rather than looking into the aggregated NAL + units themselves, which are defined by the video coding + specification. + + + + + + +Wenger, et al. Standards Track [Page 15] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o To enable correct decoding order recovery in MST using the NI-C or + NI-TC mode, with the help of the CS-DON information included in + PACSI NAL units. + + o To improve resilience to packet losses, e.g., by utilizing the + following data or information included in PACSI NAL units: + repeated Supplemental Enhancement Information (SEI) messages, + information regarding the start and end of layer representations, + and the indices to layer representations of the lowest temporal + subset. + + Empty NAL units may be used to enable correct decoding order recovery + in MST using the NI-T or NI-TC mode. NI-MTAP NAL units may be used + to aggregate NAL units from multiple access units but without + interleaving. + +2. Conventions + + 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 BCP 14, RFC 2119 + [RFC2119]. + + This specification uses the notion of setting and clearing a bit when + bit fields are handled. Setting a bit is the same as assigning that + bit the value of 1 (On). Clearing a bit is the same as assigning + that bit the value of 0 (Off). + +3. Definitions and Abbreviations + +3.1. Definitions + + This document uses the terms and definitions of [H.264]. Section + 3.1.1 lists relevant definitions copied from [H.264] for convenience. + + When there is discrepancy, the definitions in [H.264] take + precedence. Section 3.1.2 gives definitions specific to this memo. + Some of the definitions in Section 3.1.2 are also present in + [RFC6184] and copied here with slight adaptations as needed. + +3.1.1. Definitions from the SVC Specification + + access unit: A set of NAL units always containing exactly one primary + coded picture. In addition to the primary coded picture, an access + unit may also contain one or more redundant coded pictures, one + auxiliary coded picture, or other NAL units not containing slices or + slice data partitions of a coded picture. The decoding of an access + unit always results in a decoded picture. + + + +Wenger, et al. Standards Track [Page 16] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + base layer: A bitstream subset that contains all the NAL units with + the nal_unit_type syntax element equal to 1 or 5 of the bitstream and + does not contain any NAL unit with the nal_unit_type syntax element + equal to 14, 15, or 20 and conforms to one or more of the profiles + specified in Annex A of [H.264]. + + base quality layer representation: The layer representation of the + target dependency representation of an access unit that is associated + with the quality_id syntax element equal to 0. + + coded video sequence: A sequence of access units that consists, in + decoding order, of an IDR access unit followed by zero or more non- + IDR access units including all subsequent access units up to but not + including any subsequent IDR access unit. + + dependency representation: A subset of Video Coding Layer (VCL) NAL + units within an access unit that are associated with the same value + of the dependency_id syntax element, which is provided as part of the + NAL unit header or by an associated prefix NAL unit. A dependency + representation consists of one or more layer representations. + + IDR access unit: An access unit in which the primary coded picture is + an IDR picture. + + IDR picture: Instantaneous decoding refresh picture. A coded picture + in which all slices of the target dependency representation within + the access unit are I or EI slices that causes the decoding process + to mark all reference pictures as "unused for reference" immediately + after decoding the IDR picture. After the decoding of an IDR picture + all following coded pictures in decoding order can be decoded without + inter prediction from any picture decoded prior to the IDR picture. + The first picture of each coded video sequence is an IDR picture. + + layer representation: A subset of VCL NAL units within an access unit + that are associated with the same values of the dependency_id and + quality_id syntax elements, which are provided as part of the VCL NAL + unit header or by an associated prefix NAL unit. One or more layer + representations represent a dependency representation. + + prefix NAL unit: A NAL unit with nal_unit_type equal to 14 that + immediately precedes in decoding order a NAL unit with nal_unit_type + equal to 1, 5, or 12. The NAL unit that immediately succeeds in + decoding order the prefix NAL unit is referred to as the associated + NAL unit. The prefix NAL unit contains data associated with the + associated NAL unit, which are considered to be part of the + associated NAL unit. + + + + + +Wenger, et al. Standards Track [Page 17] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + reference base picture: A reference picture that is obtained by + decoding a base quality layer representation with the nal_ref_idc + syntax element not equal to 0 and the store_ref_base_pic_flag syntax + element equal to 1 of an access unit and all layer representations of + the access unit that are referred to by inter-layer prediction of the + base quality layer representation. A reference base picture is not + an output of the decoding process, but the samples of a reference + base picture may be used for inter prediction in the decoding process + of subsequent pictures in decoding order. Reference base picture is + a collective term for a reference base field or a reference base + frame. + + scalable bitstream: A bitstream with the property that one or more + bitstream subsets that are not identical to the scalable bitstream + form another bitstream that conforms to the SVC specification + [H.264]. + + target dependency representation: The dependency representation of an + access unit that is associated with the largest value of the + dependency_id syntax element for all dependency representations of + the access unit. + + target layer representation: The layer representation of the target + dependency representation of an access unit that is associated with + the largest value of the quality_id syntax element for all layer + representations of the target dependency representation of the access + unit. + +3.1.2. Definitions Specific to This Memo + + anchor layer representation: An anchor layer representation is such a + layer representation that, if decoding of the operation point + corresponding to the layer starts from the access unit containing + this layer representation, all the following layer representations of + the layer, in output order, can be correctly decoded. The output + order is defined in [H.264] as the order in which decoded pictures + are output from the decoded picture buffer of the decoder. As H.264 + does not specify the picture display process, this more general term + is used instead of display order. An anchor layer representation is + a random access point to the layer the anchor layer representation + belongs. However, some layer representations, succeeding an anchor + layer representation in decoding order but preceding the anchor layer + representation in output order, may refer to earlier layer + representations for inter prediction, and hence the decoding may be + incorrect if random access is performed at the anchor layer + representation. + + + + + +Wenger, et al. Standards Track [Page 18] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + AVC base layer: The subset of the SVC base layer in which all prefix + NAL units (type 14) are removed. Note that this is equivalent to the + term "base layer" as defined in Annex G of [H.264]. + + base RTP session: When multi-session transmission is used, the RTP + session that carries the RTP stream containing the T0 AVC base layer + or the T0 SVC base layer, and zero or more enhancement layers. This + RTP session does not depend on any other RTP session as indicated by + mechanisms defined in Section 7.2.3. The base RTP session may carry + NAL units of NAL unit type equal to 14 and 15. + + decoding order number (DON): A field in the payload structure or a + derived variable indicating NAL unit decoding order. Values of DON + are in the range of 0 to 65535, inclusive. After reaching the + maximum value, the value of DON wraps around to 0. Note that this + definition also exists in [RFC6184] in exactly the same form. + + Empty NAL unit: A NAL unit with NAL unit type equal to 31 and sub- + type equal to 1. An empty NAL unit consists of only the two-byte NAL + unit header with an empty payload. + + enhancement RTP session: When multi-session transmission is used, an + RTP session that is not the base RTP session. An enhancement RTP + session typically contains an RTP stream that depends on at least one + other RTP session as indicated by mechanisms defined in Section + 7.2.3. A lower RTP session to an enhancement RTP session is an RTP + session on which the enhancement RTP session depends. The lowest RTP + session for a receiver is the RTP session that does not depend on any + other RTP session received by the receiver. The highest RTP session + for a receiver is the RTP session on which no other RTP session + received by the receiver depends. + + cross-session decoding order number (CS-DON): A derived variable + indicating NAL unit decoding order number over all NAL units within + all the session-multiplexed RTP sessions that carry the same SVC + bitstream. + + default level: The level indicated by the profile-level-id parameter. + In Session Description Protocol (SDP) Offer/Answer, the level is + downgradable, i.e., the answer may either use the default level or a + lower level. Note that this definition also exists in [RFC6184] in a + slightly different form. + + default sub-profile: The subset of coding tools, which may be all + coding tools of one profile or the common subset of coding tools of + more than one profile, indicated by the profile-level-id parameter. + In SDP Offer/Answer, the default sub-profile must be used in a + + + + +Wenger, et al. Standards Track [Page 19] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + symmetric manner, i.e., the answer must either use the same sub- + profile as the offer or reject the offer. Note that this definition + also exists in [RFC6184] in a slightly different form. + + enhancement layer: A layer in which at least one of the values of + dependency_id or quality_id is higher than 0, or a layer in which + none of the NAL units is associated with the value of temporal_id + equal to 0. An operation point constructed using the maximum + temporal_id, dependency_id, and quality_id values associated with an + enhancement layer may or may not conform to one or more of the + profiles specified in Annex A of [H.264]. + + H.264/AVC compatible: The property of a bitstream subset of + conforming to one or more of the profiles specified in Annex A of + [H.264]. + + intra layer representation: A layer representation that contains + only slices that use intra prediction, and hence do not refer to any + earlier layer representation in decoding order in the same layer. + Note that in SVC intra prediction includes intra-layer intra + prediction as well as inter-layer intra prediction. + + layer: A bitstream subset in which all NAL units of type 1, 5, 12, + 14, or 20 have the same values of dependency_id and quality_id, + either directly through their NAL unit header (for NAL units of type + 14 or 20) or through association to a prefix (type 14) NAL unit (for + NAL unit type 1, 5, or 12). A layer may contain NAL units associated + with more than one values of temporal_id. + + media-aware network element (MANE): A network element, such as a + middlebox or application layer gateway that is capable of parsing + certain aspects of the RTP payload headers or the RTP payload and + reacting to their contents. Note that this definition also exists in + [RFC6184] in exactly the same form. + + Informative note: The concept of a MANE goes beyond normal routers + or gateways in that a MANE has to be aware of the signaling (e.g., + to learn about the payload type mappings of the media streams), + and in that it has to be trusted when working with Secure Real- + time Transport Protocol (SRTP). The advantage of using MANEs is + that they allow packets to be dropped according to the needs of + the media coding. For example, if a MANE has to drop packets due + to congestion on a certain link, it can identify and remove those + packets whose elimination produces the least adverse effect on the + user experience. After dropping packets, MANEs must rewrite RTCP + packets to match the changes to the RTP packet stream as specified + in Section 7 of [RFC3550]. + + + + +Wenger, et al. Standards Track [Page 20] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + multi-session transmission: The transmission mode in which the SVC + stream is transmitted over multiple RTP sessions. Dependency between + RTP sessions MUST be signaled according to Section 7.2.3 of this + memo. + + NAL unit decoding order: A NAL unit order that conforms to the + constraints on NAL unit order given in Section G.7.4.1.2 in [H.264]. + Note that this definition also exists in [RFC6184] in a slightly + different form. + + NALU-time: The value that the RTP timestamp would have if the NAL + unit would be transported in its own RTP packet. Note that this + definition also exists in [RFC6184] in exactly the same form. + + operation point: An operation point is identified by a set of values + of temporal_id, dependency_id, and quality_id. A bitstream + corresponding to an operation point can be constructed by removing + all NAL units associated with a higher value of dependency_id, and + all NAL units associated with the same value of dependency_id but + higher values of quality_id or temporal_id. An operation point + bitstream conforms to at least one of the profiles defined in Annex A + or G of [H.264], and offers a representation of the original video + signal at a certain fidelity. + + Informative note: Additional NAL units may be removed (with lower + dependency_id or same dependency_id but lower quality_id) if they + are not required for decoding the bitstream at the particular + operation point. The resulting bitstream, however, may no longer + conform to any of the profiles defined in Annex A or G of [H.264]. + + operation point representation: The set of all NAL units of an + operation point within the same access unit. + + RTP packet stream: A sequence of RTP packets with increasing sequence + numbers (except for wrap-around), identical payload type and + identical SSRC (Synchronization Source), carried in one RTP session. + Within the scope of this memo, one RTP packet stream is utilized to + transport one or more layers. + + single-session transmission: The transmission mode in which the SVC + bitstream is transmitted over a single RTP session. + + SVC base layer: The layer that includes all NAL units associated with + dependency_id and quality_id values both equal to 0, including prefix + NAL units (NAL unit type 14). + + + + + + +Wenger, et al. Standards Track [Page 21] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + SVC enhancement layer: A layer in which at least one of the values of + dependency_id or quality_id is higher than 0. An operation point + constructed using the maximum dependency_id and quality_id values and + any temporal_id value associated with an SVC enhancement layer does + not conform to any of the profiles specified in Annex A of [H.264]. + + SVC NAL unit: A NAL unit of NAL unit type 14, 15, or 20 as specified + in Annex G of [H.264]. + + SVC NAL unit header: A four-byte header resulting from the addition + of a three-byte SVC-specific header extension added in NAL unit types + 14 and 20. + + SVC RTP session: Either the base RTP session or an enhancement RTP + session. + + T0 AVC base layer: A subset of the AVC base layer constructed by + removing all VCL NAL units associated with temporal_id values higher + than 0 and non-VCL NAL units and SEI messages associated only with + the VCL NAL units being removed. + + T0 SVC base layer: A subset of the SVC base layer constructed by + removing all VCL NAL units associated with temporal_id values higher + than 0 as well as prefix NAL units, non-VCL NAL units, and SEI + messages associated only with the VCL NAL units being removed. + + transmission order: The order of packets in ascending RTP sequence + number order (in modulo arithmetic). Within an aggregation packet, + the NAL unit transmission order is the same as the order of + appearance of NAL units in the packet. Note that this definition + also exists in [RFC6184] in exactly the same form. + +3.2. Abbreviations + + In addition to the abbreviations defined in [RFC6184], the following + abbreviations are used in this memo. + + CGS: Coarse-Grain Scalability + CS-DON: Cross-Session Decoding Order Number + MGS: Medium-Grain Scalability + MST: Multi-Session Transmission + PACSI: Payload Content Scalability Information + SST: Single-Session Transmission + SNR: Signal-to-Noise Ratio + SVC: Scalable Video Coding + + + + + + +Wenger, et al. Standards Track [Page 22] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +4. RTP Payload Format + +4.1. RTP Header Usage + + In addition to Section 5.1 of [RFC6184], the following rules apply. + + o Setting of the M bit: + + The M bit of an RTP packet for which the packet payload is an NI-MTAP + MUST be equal to 1 if the last NAL unit, in decoding order, of the + access unit associated with the RTP timestamp is contained in the + packet. + + o Setting of the RTP timestamp: + + For an RTP packet for which the packet payload is an empty NAL unit, + the RTP timestamp must be set according to Section 4.10. + + For an RTP packet for which the packet payload is a PACSI NAL unit, + the RTP timestamp MUST be equal to the NALU-time of the next non- + PACSI NAL unit in transmission order. Recall that the NALU-time of a + NAL unit in an MTAP is defined in [RFC6184] as the value that the RTP + timestamp would have if that NAL unit would be transported in its own + RTP packet. + + o Setting of the SSRC: + + For both SST and MST, the SSRC values MUST be set according to + [RFC3550]. + +4.2. NAL Unit Extension and Header Usage + +4.2.1. NAL Unit Extension + + This memo specifies a NAL unit extension mechanism to allow for + introduction of new types of NAL units, beyond the three NAL unit + types left undefined in [RFC6184] (i.e., 0, 30, and 31). The + extension mechanism utilizes the NAL unit type value 31 and is + specified as follows. When the NAL unit type value is equal to 31, + the one-byte NAL unit header consisting of the F, NRI, and Type + fields as specified in Section 1.1.3 is extended by one additional + octet, which consists of a 5-bit field named Subtype and three 1-bit + fields named J, K, and L, respectively. The additional octet is + shown in the following figure. + + + + + + + +Wenger, et al. Standards Track [Page 23] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + +---------------+ + |0|1|2|3|4|5|6|7| + +-+-+-+-+-+-+-+-+ + | Subtype |J|K|L| + +---------------+ + + The Subtype value determines the (extended) NAL unit type of this NAL + unit. The interpretation of the fields J, K, and L depends on the + Subtype. The semantics of the fields are as follows. + + When Subtype is equal to 1, the NAL unit is an empty NAL unit as + specified in Section 4.10. When Subtype is equal to 2, the NAL unit + is an NI-MTAP NAL unit as specified in Section 4.7.1. All other + values of Subtype (0, 3-31) are reserved for future extensions, and + receivers MUST ignore the entire NAL unit when Subtype is equal to + any of these reserved values. + +4.2.2. NAL Unit Header Usage + + The structure and semantics of the NAL unit header according to the + H.264 specification [H.264] were introduced in Section 1.1.3. This + section specifies the extended semantics of the NAL unit header + fields F, NRI, I, PRID, DID, QID, TID, U, and D, according to this + memo. When the Type field is equal to 31, the semantics of the + fields in the extension NAL unit header were specified in Section + 4.2.1. + + The semantics of F specified in Section 5.3 of [RFC6184] also apply + in this memo. That is, a value of 0 for F indicates that the NAL + unit type octet and payload should not contain bit errors or other + syntax violations, whereas a value of 1 for F indicates that the NAL + unit type octet and payload may contain bit errors or other syntax + violations. MANEs SHOULD set the F bit to indicate bit errors in the + NAL unit. + + For NRI, for a bitstream conforming to one of the profiles defined in + Annex A of [H.264] and transported using [RFC6184], the semantics + specified in Section 5.3 of [RFC6184] apply, i.e., NRI also indicates + the relative importance of NAL units. For a bitstream conforming to + one of the profiles defined in Annex G of [H.264] and transported + using this memo, in addition to the semantics specified in Annex G of + [H.264], NRI also indicates the relative importance of NAL units + within a layer. + + For I, in addition to the semantics specified in Annex G of [H.264], + according to this memo, MANEs MAY use this information to protect NAL + units with I equal to 1 better than NAL units with I equal to 0. + MANEs MAY also utilize information of NAL units with I equal to 1 to + + + +Wenger, et al. Standards Track [Page 24] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + decide when to forward more packets for an RTP packet stream. For + example, when it is detected that spatial layer switching has + happened such that the operation point has changed to a higher value + of DID, MANEs MAY start to forward NAL units with the higher value of + DID only after forwarding a NAL unit with I equal to 1 with the + higher value of DID. + + Note that, in the context of this section, "protecting a NAL unit" + means any RTP or network transport mechanism that could improve the + probability of successful delivery of the packet conveying the NAL + unit, including applying a Quality of Service (QoS) enabled network, + Forward Error Correction (FEC), retransmissions, and advanced + scheduling behavior, whenever possible. + + For PRID, the semantics specified in Annex G of [H.264] apply. Note + that MANEs implementing unequal error protection MAY use this + information to protect NAL units with smaller PRID values better than + those with larger PRID values, for example, by including only the + more important NAL units in a FEC protection mechanism. The + importance for the decoding process decreases as the PRID value + increases. + + For DID, QID, or TID, in addition to the semantics specified in Annex + G of [H.264], according to this memo, values of DID, QID, or TID + indicate the relative importance in their respective dimension. A + lower value of DID, QID, or TID indicates a higher importance if the + other two components are identical. MANEs MAY use this information + to protect more important NAL units better than less important NAL + units. + + For U, in addition to the semantics specified in Annex G of [H.264], + according to this memo, MANEs MAY use this information to protect NAL + units with U equal to 1 better than NAL units with U equal to 0. + + For D, in addition to the semantics specified in Annex G of [H.264], + according to this memo, MANEs MAY use this information to determine + whether a given NAL unit is required for successfully decoding a + certain Operation Point of the SVC bitstream, hence to decide whether + to forward the NAL unit. + +4.3. Payload Structures + + The NAL unit structure is central to H.264/AVC, [RFC6184], as well as + SVC and this memo. In H.264/AVC and SVC, all coded bits for + representing a video signal are encapsulated in NAL units. In + [RFC6184], each RTP packet payload is structured as a NAL unit, which + contains one or a part of one NAL unit specified in H.264/AVC, or + aggregates one or more NAL units specified in H.264/AVC. + + + +Wenger, et al. Standards Track [Page 25] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + [RFC6184] specifies three basic payload structures (in Section 5.2 of + [RFC6184]): single NAL unit packet, aggregation packet, fragmentation + unit, and six new types (24 to 29) of NAL units. The value of the + Type field of the RTP packet payload header (i.e., the first byte of + the payload) may be equal to any value from 1 to 23 for a single NAL + unit packet, any value from 24 to 27 for an aggregation packet, and + 28 or 29 for a fragmentation unit. + + In addition to the NAL unit types defined originally for H.264/AVC, + SVC defines three new NAL unit types specifically for SVC: coded + slice in scalable extension NAL units (type 20), prefix NAL units + (type 14), and subset sequence parameter set NAL units (type 15), as + described in Section 1.1. + + This memo further introduces three new types of NAL units, PACSI NAL + unit (NAL unit type 30) as specified in Section 4.9, empty NAL unit + (type 31, subtype 1) as specified in Section 4.10, and NI-MTAP NAL + unit (type 31, subtype 2) as specified in Section 4.7.1. + + The RTP packet payload structure in [RFC6184] is maintained with + slight extensions in this memo, as follows. Each RTP packet payload + is still structured as a NAL unit, which contains one or a part of + one NAL unit specified in H.264/AVC and SVC, or contains one PACSI + NAL unit or one empty NAL unit, or aggregates zero or more NAL units + specified in H.264/AVC and SVC, zero or one PACSI NAL unit, and zero + or more empty NAL units. + + In this memo, one of the three basic payload structures, + fragmentation unit, remains the same as in [RFC6184], and the other + two, single NAL unit packet and aggregation packet, are extended as + follows. The value of the Type field of the payload header may be + equal to any value from 1 to 23, inclusive, and 30 to 31, inclusive, + for a single NAL unit packet, and any value from 24 to 27, inclusive, + and 31, for an aggregation packet. When the Type field of the + payload header is equal to 31 and the Subtype field of the payload + header is equal to 2, the packet is an aggregation packet (containing + an NI-MTAP NAL unit). When the Type field of the payload header is + equal to 31 and the Subtype field of the payload header is equal to + 1, the packet is a single NAL unit packet (containing an empty NAL + unit). + + Note that, in this memo, the length of the payload header varies + depending on the value of the Type field in the first byte of the RTP + packet payload. If the value is equal to 14, 20, or 30, the first + four bytes of the packet payload form the payload header; otherwise, + if the value is equal to 31, the first two bytes of the payload form + the payload header; otherwise, the payload header is the first byte + of the packet payload. + + + +Wenger, et al. Standards Track [Page 26] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Table 1 lists the NAL unit types introduced in SVC and this memo and + where they are described in this memo. Table 2 summarizes the basic + payload structure types for all NAL unit types when they are directly + used as RTP packet payloads according to this memo. Table 3 + summarizes the NAL unit types allowed to be aggregated (i.e., used as + aggregation units in aggregation packets) or fragmented (i.e., + carried in fragmentation units) according to this memo. + + Table 1. NAL unit types introduced in SVC and this memo + + Type Subtype NAL Unit Name Section Numbers + ----------------------------------------------------------- + 14 - Prefix NAL unit 1.1 + 15 - Subset sequence parameter set 1.1 + 20 - Coded slice in scalable extension 1.1 + 30 - PACSI NAL unit 4.9 + 31 0 reserved 4.2.1 + 31 1 Empty NAL unit 4.10 + 31 2 NI-MTAP 4.7.1 + 31 3-31 reserved 4.2.1 + + Table 2. Basic payload structure types for all NAL unit + types when they are directly used as RTP packet payloads + + Type Subtype Basic Payload Structure + ------------------------------------------ + 0 - reserved + 1-23 - Single NAL Unit Packet + 24-27 - Aggregation Packet + 28-29 - Fragmentation Unit + 30 - Single NAL Unit Packet + 31 0 reserved + 31 1 Single NAL Unit Packet + 31 2 Aggregation Packet + 31 3-31 reserved + + + + + + + + + + + + + + + + +Wenger, et al. Standards Track [Page 27] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Table 3. Summary of the NAL unit types allowed to be + aggregated or fragmented (yes = allowed, no = disallowed, + - = not applicable/not specified) + + Type Subtype STAP-A STAP-B MTAP16 MTAP24 FU-A FU-B NI-MTAP + ------------------------------------------------------------- + 0 - - - - - - - - + 1-23 - yes yes yes yes yes yes yes + 24-29 - no no no no no no no + 30 - yes yes yes yes no no yes + 31 0 - - - - - - - + 31 1 yes no no no no no yes + 31 2 no no no no no no no + 31 3-31 - - - - - - - + +4.4. Transmission Modes + + This memo enables transmission of an SVC bitstream over one or more + RTP sessions. If only one RTP session is used for transmission of + the SVC bitstream, the transmission mode is referred to as single- + session transmission (SST); otherwise (more than one RTP session is + used for transmission of the SVC bitstream), the transmission mode is + referred to as multi-session transmission (MST). + + SST SHOULD be used for point-to-point unicast scenarios, while MST + SHOULD be used for point-to-multipoint multicast scenarios where + different receivers requires different operation points of the same + SVC bitstream, to improve bandwidth utilizing efficiency. + + If the OPTIONAL mst-mode media type parameter (see Section 7.1) is + not present, SST MUST be used; otherwise (mst-mode is present), MST + MUST be used. + +4.5. Packetization Modes + +4.5.1. Packetization Modes for Single-Session Transmission + + When SST is in use, Section 5.4 of [RFC6184] applies with the + following extensions. + + The packetization modes specified in Section 5.4 of [RFC6184], + namely, single NAL unit mode, non-interleaved mode, and interleaved + mode, are also referred to as session packetization modes. Table 4 + summarizes the allowed session packetization modes for SST. + + + + + + + +Wenger, et al. Standards Track [Page 28] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Table 4. Summary of allowed session packetization modes + (denoted as "Session Mode" for simplicity) for SST (yes = + allowed, no = disallowed) + + Session Mode Allowed + ------------------------------------- + Single NAL Unit Mode yes + Non-Interleaved Mode yes + Interleaved Mode yes + + For NAL unit types in the range of 0 to 29, inclusive, the NAL unit + types allowed to be directly used as packet payloads for each session + packetization mode are the same as specified in Section 5.4 of + [RFC6184]. For other NAL unit types, which are newly introduced in + this memo, the NAL unit types allowed to be directly used as packet + payloads for each session packetization mode are summarized in Table + 5. + + Table 5. New NAL unit types allowed to be directly used + as packet payloads for each session packetization mode + (yes = allowed, no = disallowed, - = not applicable/not specified) + + Type Subtype Single NAL Non-Interleaved Interleaved + Unit Mode Mode Mode + ------------------------------------------------------------- + 30 - yes no no + 31 0 - - - + 31 1 yes yes no + 31 2 no yes no + 31 3-31 - - - + +4.5.2. Packetization Modes for Multi-Session Transmission + + For MST, this memo specifies four MST packetization modes: + + o Non-interleaved timestamp based mode (NI-T); + + o Non-interleaved cross-session decoding order number (CS-DON) based + mode (NI-C); + + o Non-interleaved combined timestamp and CS-DON mode (NI-TC); and + + o Interleaved CS-DON (I-C) mode. + + These four modes differ in two ways. First, they differ in terms of + whether NAL units are required to be transmitted within each RTP + session in decoding order (i.e., non-interleaved), or they are + allowed to be transmitted in a different order (i.e., interleaved). + + + +Wenger, et al. Standards Track [Page 29] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Second, they differ in the mechanisms they provide in order to + recover the correct decoding order of the NAL units across all RTP + sessions involved. + + The NI-T, NI-C, and NI-TC modes do not allow interleaving, and are + thus targeted for systems that require relatively low end-to-end + latency, e.g., conversational systems. The I-C mode allows + interleaving and is thus targeted for systems that do not require + very low end-to-end latency. The benefits of interleaving are the + same as that of the interleaved mode specified in [RFC6184]. + + The NI-T mode uses timestamps to recover the decoding order of NAL + units, whereas the NI-C and I-C modes both use the CS-DON mechanism + (explained later) to do so. The NI-TC mode provides both timestamps + and the CS-DON method; receivers in this case may choose to use + either method for performing decoding order recovery. The MST + packetization mode in use MUST be signaled by the value of the + OPTIONAL mst-mode media type parameter. The used MST packetization + mode governs which session packetization modes are allowed in the + associated RTP sessions, which in turn govern which NAL unit types + are allowed to be directly used as RTP packet payloads. + + Table 6 summarizes the allowed session packetization modes for NI-T, + NI-C, and NI-TC. Table 7 summarizes the allowed session + packetization modes for I-C. + + Table 6. Summary of allowed session packetization modes + (denoted as "Session Mode" for simplicity) for NI-T, NI-C, and + NI-TC (yes = allowed, no = disallowed) + + Session Mode Base Session Enhancement Session + ----------------------------------------------------------- + Single NAL Unit Mode yes no + Non-Interleaved Mode yes yes + Interleaved Mode no no + + Table 7. Summary of allowed session packetization modes + (denoted as "Session Mode" for simplicity) for I-C + (yes = allowed, no = disallowed) + + Session Mode Base Session Enhancement Session + ----------------------------------------------------------- + Single NAL Unit Mode no no + Non-Interleaved Mode no no + Interleaved Mode yes yes + + + + + + +Wenger, et al. Standards Track [Page 30] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + For NAL unit types in the range of 0 to 29, inclusive, the NAL unit + types allowed to be directly used as packet payloads for each session + packetization mode are the same as specified in Section 5.4 of + [RFC6184]. For other NAL unit types, which are newly introduced in + this memo, the NAL unit types allowed to be directly used as packet + payloads for each allowed session packetization mode for NI-T, NI-C, + NI-TC, and I-C are summarized in Tables 8, 9, 10, and 11, + respectively. + + Table 8. New NAL unit types allowed to be directly used + as packet payloads for each allowed session packetization + mode when NI-T is in use (yes = allowed, no = disallowed, + - = not applicable/not specified) + + Type Subtype Single NAL Non-Interleaved + Unit Mode Mode + --------------------------------------------------- + 30 - yes no + 31 0 - - + 31 1 yes yes + 31 2 no yes + 31 3-31 - - + + Table 9. New NAL unit types allowed to be directly used + as packet payloads for each allowed session packetization + mode when NI-C is in use (yes = allowed, no = disallowed, + - = not applicable/not specified) + + Type Subtype Single NAL Non-Interleaved + Unit Mode Mode + --------------------------------------------------- + 30 - yes yes + 31 0 - - + 31 1 no no + 31 2 no yes + 31 3-31 - - + + + + + + + + + + + + + + + +Wenger, et al. Standards Track [Page 31] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Table 10. New NAL unit types allowed to be directly used + as packet payloads for each allowed session packetization + mode when NI-TC is in use (yes = allowed, no = disallowed, + - = not applicable/not specified) + + Type Subtype Single NAL Non-Interleaved + Unit Mode Mode + --------------------------------------------------- + 30 - yes yes + 31 0 - - + 31 1 yes yes + 31 2 no yes + 31 3-31 - - + + Table 11. New NAL unit types allowed to be directly used + as packet payloads for the allowed session packetization + mode when I-C is in use (yes = allowed, no = disallowed, + - = not applicable/not specified) + + Type Subtype Interleaved Mode + ------------------------------------ + 30 - no + 31 0 - + 31 1 no + 31 2 no + 31 3-31 - + + When MST is in use and the MST packetization mode in use is NI-C, + empty NAL units (type 31, subtype 1) MUST NOT be used, i.e., no RTP + packet is allowed to contain one or more empty NAL units. + + When MST is in use and the MST packetization mode in use is I-C, both + empty NAL units (type 31, subtype 1) and NI-MTAP NAL units (type 31, + subtype 2) MUST NOT be used, i.e., no RTP packet is allowed to + contain one or more empty NAL units or an NI-MTAP NAL unit. + +4.6. Single NAL Unit Packets + + Section 5.6 of [RFC6184] applies with the following extensions. + + The payload of a single NAL unit packet MAY be a PACSI NAL unit (Type + 30) or an empty NAL unit (Type 31 and Subtype 1), in addition to a + NAL unit with NAL unit type equal to any value from 1 to 23, + inclusive. + + + + + + + +Wenger, et al. Standards Track [Page 32] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + If the Type field of the first byte of the payload is not equal to + 31, the payload header is the first byte of the payload. Otherwise, + (the Type field of the first byte of the payload is equal to 31), the + payload header is the first two bytes of the payload. + +4.7. Aggregation Packets + + In addition to Section 5.7 of [RFC6184], the following applies in + this memo. + +4.7.1. Non-Interleaved Multi-Time Aggregation Packets (NI-MTAPs) + + One new NAL unit type introduced in this memo is the non-interleaved + multi-time aggregation packet (NI-MTAP). An NI-MTAP consists of one + or more non-interleaved multi-time aggregation units. + + The NAL units contained in NI-MTAPs MUST be aggregated in decoding + order. + + A non-interleaved multi-time aggregation unit for the NI-MTAP + consists of 16 bits of unsigned size information of the following NAL + unit (in network byte order), and 16 bits (in network byte order) of + timestamp offset (TS offset) for the NAL unit. The structure is + presented in Figure 1. The starting or ending position of an + aggregation unit within a packet may or may not be on a 32-bit word + boundary. The NAL units in the NI-MTAP are ordered in NAL unit + decoding order. + + The Type field of the NI-MTAP MUST be set equal to "31". + + The F bit MUST be set to 0 if all the F bits of the aggregated NAL + units are zero; otherwise, it MUST be set to 1. + + The value of NRI MUST be the maximum value of NRI across all NAL + units carried in the NI-MTAP packet. + + The field Subtype MUST be equal to 2. + + If the field J is equal to 1, the optional DON field MUST be present + for each of the non-interleaved multi-time aggregation units. For + SST, the J field MUST be equal to 0. For MST, in the NI-T mode the J + field MUST be equal to 0, whereas in the NI-C or NI-TC mode the J + field MUST be equal to 1. When the NI-C or NI-TC mode is in use, the + DON field, when present, MUST represent the CS-DON value for the + particular NAL unit as defined in Section 6.2.2. + + The fields K and L MUST be both equal to 0. + + + + +Wenger, et al. Standards Track [Page 33] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + : NAL unit size | TS offset | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | DON (optional) | | + |-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ NAL unit | + | | + | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | : + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 1. Non-interleaved multi-time aggregation unit for NI-MTAP + + Let TS be the RTP timestamp of the packet carrying the NAL unit. + Recall that the NALU-time of a NAL unit in an MTAP is defined in + [RFC6184] as the value that the RTP timestamp would have if that NAL + unit would be transported in its own RTP packet. The timestamp + offset field MUST be set to a value equal to the value of the + following formula: + + if NALU-time >= TS, TS offset = NALU-time - TS + else, TS offset = NALU-time + (2^32 - TS) + + For the "earliest" multi-time aggregation unit in an NI-MTAP, the + timestamp offset MUST be zero. Hence, the RTP timestamp of the NI- + MTAP itself is identical to the earliest NALU-time. + + Informative note: The "earliest" multi-time aggregation unit is + the one that would have the smallest extended RTP timestamp among + all the aggregation units of an NI-MTAP if the aggregation units + were encapsulated in single NAL unit packets. An extended + timestamp is a timestamp that has more than 32 bits and is capable + of counting the wraparound of the timestamp field, thus enabling + one to determine the smallest value if the timestamp wraps. Such + an "earliest" aggregation unit may or may not be the first one in + the order in which the aggregation units are encapsulated in an + NI-MTAP. The "earliest" NAL unit need not be the same as the + first NAL unit in the NAL unit decoding order either. + + Figure 2 presents an example of an RTP packet that contains an NI- + MTAP that contains two non-interleaved multi-time aggregation units, + labeled as 1 and 2 in the figure. + + + + + + + + +Wenger, et al. Standards Track [Page 34] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | RTP Header | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |F|NRI| Type | Subtype |J|K|L| | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | + | | + | Non-interleaved multi-time aggregation unit #1 | + : : + | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | Non-interleaved multi-time | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | + | aggregation unit #2 | + : : + | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | :...OPTIONAL RTP padding | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 2. An RTP packet including an NI-MTAP containing two + non-interleaved multi-time aggregation units + +4.8. Fragmentation Units (FUs) + + Section 5.8 of [RFC6184] applies. + + Informative note: In case a NAL unit with the four-byte SVC NAL + unit header is fragmented, the three-byte SVC-specific header + extension is considered as part of the NAL unit payload. That is, + the three-byte SVC-specific header extension is only available in + the first fragment of the fragmented NAL unit. + +4.9. Payload Content Scalability Information (PACSI) NAL Unit + + Another new type of NAL unit specified in this memo is the payload + content scalability information (PACSI) NAL unit. The Type field of + PACSI NAL units MUST be equal to 30 (a NAL unit type value left + unspecified in [H.264] and [RFC6184]). A PACSI NAL unit MAY be + carried in a single NAL unit packet or an aggregation packet, and + MUST NOT be fragmented. + + PACSI NAL units may be used for the following purposes: + + o To enable MANEs to decide whether to forward, process, or discard + aggregation packets, by checking in PACSI NAL units the + scalability information and other characteristics of the + + + + + +Wenger, et al. Standards Track [Page 35] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + aggregated NAL units, rather than looking into the aggregated NAL + units themselves, which are defined by the video coding + specification; + + o To enable correct decoding order recovery in MST using the NI-C or + NI-TC mode, with the help of the CS-DON information included in + PACSI NAL units; and + + o To improve resilience to packet losses, e.g., by utilizing the + following data or information included in PACSI NAL units: + repeated Supplemental Enhancement Information (SEI) messages, + information regarding the start and end of layer representations, + and the indices to layer representations of the lowest temporal + subset. + + PACSI NAL units MAY be ignored in the NI-T mode without affecting the + decoding order recovery process. + + When a PACSI NAL unit is present in an aggregation packet, the + following applies. + + o The PACSI NAL unit MUST be the first aggregated NAL unit in the + aggregation packet. + + o There MUST be at least one additional aggregated NAL unit in the + aggregation packet. + + o The RTP header fields and the payload header fields of the + aggregation packet are set as if the PACSI NAL unit was not + included in the aggregation packet. + + o If the aggregation packet is an MTAP16, MTAP24, or NI-MTAP with + the J field equal to 1, the decoding order number (DON) for the + PACSI NAL unit MUST be set to indicate that the PACSI NAL unit has + an identical DON to the first NAL unit in decoding order among the + remaining NAL units in the aggregation packet. + + When a PACSI NAL unit is included in a single NAL unit packet, it is + associated with the next non-PACSI NAL unit in transmission order, + and the RTP header fields of the packet are set as if the next non- + PACSI NAL unit in transmission order was included in a single NAL + unit packet. + + The PACSI NAL unit structure is as follows. The first four octets + are exactly the same as the four-byte SVC NAL unit header discussed + in Section 1.1.3. They are followed by one octet containing several + flags, then five optional octets, and finally zero or more SEI NAL + units. Each SEI NAL unit is preceded by a 16-bit unsigned size field + + + +Wenger, et al. Standards Track [Page 36] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + (in network byte order) that indicates the size of the following NAL + unit in bytes (excluding these two octets, but including the NAL unit + header octet of the SEI NAL unit). Figure 3 illustrates the PACSI + NAL unit structure and an example of a PACSI NAL unit containing two + SEI NAL units. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |F|NRI| Type |R|I| PRID |N| DID | QID | TID |U|D|O| RR| + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |X|Y|T|A|P|C|S|E| TL0PICIDX (o) | IDRPICID (o) | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | DONC (o) | NAL unit size 1 | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + | SEI NAL unit 1 | + | | + | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | NAL unit size 2 | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | + | | + | SEI NAL unit 2 | + | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 3. PACSI NAL unit structure. Fields suffixed by + "(o)" are OPTIONAL. + + The bits A, P, and C are specified only if the bit X is equal to 1. + The bits S and E are specified, and the fields TL0PICIDX and IDRPICID + are present, only if the bit Y is equal to 1. The field DONC is + present only if the bit T is equal to 1. The field T MUST be equal + to 0 if the PACSI NAL unit is contained in an STAP-B, MTAP16, MTAP24, + or NI-MTAP with the J field equal to 1. + + The values of the fields in PACSI NAL unit MUST be set as follows. + + o The F bit MUST be set to 1 if the F bit in at least one of the + remaining NAL units in the aggregation packet is equal to 1 (when + the PACSI NAL unit is included in an aggregation packet) or if the + next non-PACSI NAL unit in transmission order has the F bit equal + to 1 (when the PACSI NAL unit is included in a single NAL unit + packet). Otherwise, the F bit MUST be set to 0. + + + + + + +Wenger, et al. Standards Track [Page 37] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o The NRI field MUST be set to the highest value of NRI field among + all the remaining NAL units in the aggregation packet (when the + PACSI NAL unit is included in an aggregation packet) or the value + of the NRI field of the next non-PACSI NAL unit in transmission + order (when the PACSI NAL unit is included in a single NAL unit + packet). + + o The Type field MUST be set to 30. + + o The R bit MUST be set to 1. Receivers MUST ignore the value of R. + + o The I bit MUST be set to 1 if the I bit of at least one of the + remaining NAL units in the aggregation packet is equal to 1 (when + the PACSI NAL unit is included in an aggregation packet) or if the + I bit of the next non-PACSI NAL unit in transmission order is + equal to 1 (when the PACSI NAL unit is included in a single NAL + unit packet). Otherwise, the I bit MUST be set to 0. + + o The PRID field MUST be set to the lowest value of the PRID values + of the remaining NAL units in the aggregation packet (when the + PACSI NAL unit is included in an aggregation packet) or the PRID + value of the next non-PACSI NAL unit in transmission order (when + the PACSI NAL unit is included in a single NAL unit packet). + + o The N bit MUST be set to 1 if the N bit of all the remaining NAL + units in the aggregation packet is equal to 1 (when the PACSI NAL + unit is included in an aggregation packet) or if the N bit of the + next non-PACSI NAL unit in transmission order is equal to 1 (when + the PACSI NAL unit is included in a single NAL unit packet). + Otherwise, the N bit MUST be set to 0. + + o The DID field MUST be set to the lowest value of the DID values of + the remaining NAL units in the aggregation packet (when the PACSI + NAL unit is included in an aggregation packet) or the DID value of + the next non-PACSI NAL unit in transmission order (when the PACSI + NAL unit is included in a single NAL unit packet). + + o The QID field MUST be set to the lowest value of the QID values of + the remaining NAL units with the lowest value of DID in the + aggregation packet (when the PACSI NAL unit is included in an + aggregation packet) or the QID value of the next non-PACSI NAL + unit in transmission order (when the PACSI NAL unit is included in + a single NAL unit packet). + + o The TID field MUST be set to the lowest value of the TID values of + the remaining NAL units with the lowest value of DID in the + aggregation packet (when the PACSI NAL unit is included in an + + + + +Wenger, et al. Standards Track [Page 38] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + aggregation packet) or the TID value of the next non-PACSI NAL + unit in transmission order (when the PACSI NAL unit is included in + a single NAL unit packet). + + o The U bit MUST be set to 1 if the U bit of at least one of the + remaining NAL units in the aggregation packet is equal to 1 (when + the PACSI NAL unit is included in an aggregation packet) or if the + U bit of the next non-PACSI NAL unit in transmission order is + equal to 1 (when the PACSI NAL unit is included in a single NAL + unit packet). Otherwise, the U bit MUST be set to 0. + + o The D bit MUST be set to 1 if the D value of all the remaining NAL + units in the aggregation packet is equal to 1 (when the PACSI NAL + unit is included in an aggregation packet) or if the D bit of the + next non-PACSI NAL unit in transmission order is equal to 1 (when + the PACSI NAL unit is included in a single NAL unit packet). + Otherwise, the D bit MUST be set to 0. + + o The O bit MUST be set to 1 if the O bit of at least one of the + remaining NAL units in the aggregation packet is equal to 1 (when + the PACSI NAL unit is included in an aggregation packet) or if the + O bit of the next non-PACSI NAL unit in transmission order is + equal to 1 (when the PACSI NAL unit is included in a single NAL + unit packet). Otherwise, the O bit MUST be set to 0. + + o The RR field MUST be set to "11" (in binary form). Receivers MUST + ignore the value of RR. + + o If the X bit is equal to 1, the bits A, P, and C are specified as + below. Otherwise, the bits A, P, and C are unspecified, and + receivers MUST ignore the values of these bits. The X bit SHOULD + be identical for all the PACSI NAL units in all the RTP sessions + carrying the same SVC bitstream. + + o If the Y bit is equal to 1, the OPTIONAL fields TL0PICIDX and + IDRPICID MUST be present and specified as below, and the bits S + and E are also specified as below. Otherwise, the fields + TL0PICIDX and IDRPICID MUST NOT be present, while the S and E bits + are unspecified and receivers MUST ignore the values of these + bits. The Y bit MUST be identical for all the PACSI NAL units in + all the RTP sessions carrying the same SVC bitstream. The Y bit + MUST be equal to 0 when the parameter packetization-mode is equal + to 2. + + o If the T bit is equal to 1, the OPTIONAL field DONC MUST be + present and specified as below. Otherwise, the field DONC MUST + NOT be present. The field T MUST be equal to 0 if the PACSI NAL + unit is contained in an STAP-B, MTAP16, MTAP24, or NI-MTAP. + + + +Wenger, et al. Standards Track [Page 39] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o The A bit MUST be set to 1 if at least one of the remaining NAL + units in the aggregation packet belongs to an anchor layer + representation (when the PACSI NAL unit is included in an + aggregation packet) or if the next non-PACSI NAL unit in + transmission order belongs to an anchor layer representation (when + the PACSI NAL unit is included in a single NAL unit packet). + Otherwise, the A bit MUST be set to 0. + + Informative note: The A bit indicates whether CGS or spatial layer + switching at a non-IDR layer representation (a layer + representation with nal_unit_type not equal to 5 and idr_flag not + equal to 1) can be performed. With some picture coding structures + a non-IDR intra layer representation can be used for random + access. Compared to using only IDR layer representations, higher + coding efficiency can be achieved. The H.264/AVC or SVC solution + to indicate the random accessibility of a non-IDR intra layer + representation is using a recovery point SEI message. The A bit + offers direct access to this information, without having to parse + the recovery point SEI message, which may be buried deeply in an + SEI NAL unit. Furthermore, the SEI message may or may not be + present in the bitstream. + + o The P bit MUST be set to 1 if all the remaining NAL units in the + aggregation packet have redundant_pic_cnt greater than 0 (when the + PACSI NAL unit is included in an aggregation packet) or the next + non-PACSI NAL unit in transmission order has redundant_pic_cnt + greater than 0 (when the PACSI NAL unit is included in a single + NAL unit packet). Otherwise, the P bit MUST be set to 0. + + Informative note: The P bit indicates whether a packet can be + discarded because it contains only redundant slice NAL units. + Without this bit, the corresponding information can be obtained + from the syntax element redundant_pic_cnt, which is contained in + the variable-length coded slice header. + + o The C bit MUST be set to 1 if at least one of the remaining NAL + units in the aggregation packet belongs to an intra layer + representation (when the PACSI NAL unit is included in an + aggregation packet) or if the next non-PACSI NAL unit in + transmission order belongs to an intra layer representation (when + the PACSI NAL unit is included in a single NAL unit packet). + Otherwise, the C bit MUST be set to 0. + + Informative note: The C bit indicates whether a packet contains + intra slices, which may be the only packets to be forwarded, e.g., + when the network conditions are particularly adverse. + + + + + +Wenger, et al. Standards Track [Page 40] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o The S bit MUST be set to 1, if the first NAL unit following the + PACSI NAL unit in an aggregation packet is the first VCL NAL unit, + in decoding order, of a layer representation (when the PACSI NAL + unit is included in an aggregation packet) or if the next non- + PACSI NAL unit in transmission order is the first VCL NAL unit, in + decoding order, of a layer representation(when the PACSI NAL unit + is included in a single NAL unit packet). Otherwise, the S bit + MUST be set to 0. + + o The E bit MUST be set to 1, if the last NAL unit following the + PACSI NAL unit in an aggregation packet is the last VCL NAL unit, + in decoding order, of a layer representation (when the PACSI NAL + unit is included in an aggregation packet) or if the next non- + PACSI NAL unit in transmission order is the last VCL NAL unit, in + decoding order, of a layer representation (when the PACSI NAL unit + is included in a single NAL unit packet). Otherwise, the E bit + MUST be set to 0. + + Informative note: In an aggregation packet it is always possible + to detect the beginning or end of a layer representation by + detecting changes in the values of dependency_id, quality_id, and + temporal_id in NAL unit headers, except from the first and last + NAL units of a packet. The S or E bits are used to provide this + information, for both single NAL unit and aggregation packets, so + that previous or following packets do not have to be examined. + This enables MANEs to detect slice loss and take proper action + such as requesting a retransmission as soon as possible, as well + as to allow efficient playout buffer handling similarly to the M + bit present in the RTP header. The M bit in the RTP header still + indicates the end of an access unit, not the end of a layer + representation. + + o When present, the TL0PICIDX field MUST be set to equal to + tl0_dep_rep_idx as specified in Annex G of [H.264] for the layer + representation containing the first NAL unit following the PACSI + NAL unit in the aggregation packet (when the PACSI NAL unit is + included in an aggregation packet) or containing the next non- + PACSI NAL unit in transmission order (when the PACSI NAL unit is + included in a single NAL unit packet). + + o When present, the IDRPICID field MUST be set to equal to + effective_idr_pic_id as specified in Annex G of [H.264] for the + layer representation containing the first NAL unit following the + PACSI NAL unit in the aggregation packet (when the PACSI NAL unit + is included in an aggregation packet) or containing the next non- + PACSI NAL unit in transmission order (when the PACSI NAL unit is + included in a single NAL unit packet). + + + + +Wenger, et al. Standards Track [Page 41] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Informative note: The TL0PICIDX and IDRPICID fields enable the + detection of the loss of layer representations in the most + important temporal layer (with temporal_id equal to 0) by + receivers as well as MANEs. SVC provides a solution that uses SEI + messages, which are harder to parse and may or may not be present + in the bitstream. When the PACSI NAL unit is part of an NI-MTAP + packet, it is possible to infer the correct values of + tl0_dep_rep_idx and idr_pic_id for all layer representations + contained in the NI-MTAP by following the rules that specify how + these parameters are set as given in Annex G of [H.264] and by + detecting the different layer representations contained in the NI- + MTAP packet by detecting changes in the values of dependency_id_, + quality_id, and temporal_id in the NAL unit headers as well as + using the S and E flags. The only exception is if NAL units of an + IDR picture are present in the NI-MTAP in a position other than + the first NAL unit following the PACSI NAL unit, in which case the + value of idr_pic_id cannot be inferred. In this case the NAL unit + has to be partially parsed to obtain the idr_pic_id. Note that, + due to the large size of IDR pictures, their inclusion in an NI- + MTAP, and especially in a position other than the first NAL unit + following the PACSI NAL unit, may be neither practical nor useful. + + o When present, the field DONC indicates the cross-session decoding + order number (CS-DON) for the first of the remaining NAL units in + the aggregation packet (when the PACSI NAL unit is included in an + aggregation packet) or the CS-DON of the next non-PACSI NAL unit + in transmission order (when the PACSI NAL unit is included in a + single NAL unit packet). CS-DON is further discussed in Section + 4.11. + + The PACSI NAL unit MAY include a subset of the SEI NAL units + associated with the access unit to which the first non-PACSI NAL unit + in the aggregation packet belongs, and MUST NOT contain SEI NAL units + associated with any other access unit. + + Informative note: In H.264/AVC and SVC, within each access unit, + SEI NAL units must appear before any VCL NAL unit in decoding + order. Therefore, without using PACSI NAL units, SEI messages are + typically only conveyed in the first of the packets carrying an + access unit. Senders may repeat SEI NAL units in PACSI NAL units, + so that they are repeated in more than one packet and thus + increase robustness against packet losses. Receivers may use the + repeated SEI messages in place of missing SEI messages. + + For a PACSI NAL unit included in an aggregation packet, an SEI + message SHOULD NOT be included in the PACSI NAL unit and also + included in one of the remaining NAL units contained in the same + aggregation packet. + + + +Wenger, et al. Standards Track [Page 42] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +4.10. Empty NAL unit + + An empty NAL unit MAY be included in a single NAL unit packet, an + STAP-A or an NI-MTAP packet. Empty NAL units MUST have an RTP + timestamp (when transported in a single NAL unit packet) or NALU- + time (when transported in an aggregation packet) that is associated + with an access unit for which there exists at least one NAL unit of + type 1, 5, or 20. When MST is used, the type 1, 5, or 20 NAL unit + may be in a different RTP session. Empty NAL units may be used in + the decoding order recovery process of the NI-T mode as described in + Section 5.2.1. + + The packet structure is shown in the following figure. + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |F|NRI| Type | Subtype |J|K|L| + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 4. Empty NAL unit structure. + + The fields MUST be set as follows: + + F MUST be equal to 0 + NRI MUST be equal to 3 + Type MUST be equal to 31 + Subtype MUST be equal to 1 + J MUST be equal to 0 + K MUST be equal to 0 + L MUST be equal to 0 + +4.11. Decoding Order Number (DON) + + The DON concept is introduced in [RFC6184] and is used to recover the + decoding order when interleaving is used within a single session. + Section 5.5 of [RFC6184] applies when using SST. + + When using MST, it is necessary to recover the decoding order across + the various RTP sessions regardless if interleaving is used or not. + In addition to the timestamp mechanism described later, the CS-DON + mechanism is an extension of the DON facility that can be used for + this purpose, and is defined in the following section. + +4.11.1. Cross-Session DON (CS-DON) for Multi-Session Transmission + + The cross-session decoding order number (CS-DON) is a number that + indicates the decoding order of NAL units across all RTP sessions + involved in MST. It is similar to the DON concept in [RFC6184], but + contrary to [RFC6184] where the DON was used only for interleaved + + + +Wenger, et al. Standards Track [Page 43] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + packetization, in this memo it is used not only in the interleaved + MST mode (I-C) but also in two of the non-interleaved MST modes (NI-C + and NI-TC). + + When the NI-C or NI-TC MST modes are in use, the packetization of + each session MUST be as specified in Section 5.2.2. In PACSI NAL + units the CS-DON value is explicitly coded in the field DONC. For + non-PACSI NAL units the CS-DON value is derived as follows. Let SN + indicate the RTP sequence number of a packet. + + o For each non-PACSI NAL unit carried in a session using the single + NAL unit session packetization mode, the CS-DON value of the NAL + unit is equal to (DONC_prev_PACSI + SN_diff - 1) % 65536, wherein + "%" is the modulo operation, DONC_prev_PACSI is the DONC value of + the previous PACSI NAL unit with the same NALU-time as the current + NAL unit, and SN_diff is calculated as follows: + + if SN1 > SN2, SN_diff = SN1 - SN2 + else SN_diff = SN2 + 65536 - SN1 + + where SN1 and SN2 are the SNs of the current NAL unit and the + previous PACSI NAL unit with the same NALU-time, respectively. + + o For non-PACSI NAL units carried in a session using the non- + interleaved session packetization mode, the CS-DON value of each + non-PACSI NAL unit is derived as follows. + + For a non-PACSI NAL unit in a single NAL unit packet, the + following applies. + + If the previous PACSI NAL unit is contained in a single NAL + unit packet, the CS-DON value of the NAL unit is calculated + as above; + + otherwise (the previous PACSI NAL unit is contained in an + STAP-A packet), the CS-DON value of the NAL unit is + calculated as above, with DONC_prev_PACSI being replaced by + the CS-DON value of the previous non-PACSI NAL unit in + decoding order (i.e., the CS-DON value of the last NAL unit + of the STAP-A packet). + + For a non-PACSI NAL unit in an STAP-A packet, the following + applies. + + If the non-PACSI NAL unit is the first non-PACSI NAL unit in + the STAP-A packet, the CS-DON value of the NAL unit is equal + to DONC of the PACSI NAL unit in the STAP-A packet; + + + + +Wenger, et al. Standards Track [Page 44] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + otherwise (the non-PACSI NAL unit is not the first non- + PACSI NAL unit in the STAP-A packet), the CS-DON value of + the NAL unit is equal to: (the CS-DON value of the previous + non-PACSI NAL unit in decoding order + 1) % 65536, wherein + "%" is the modulo operation. + + For a non-PACSI NAL unit in a number of FU-A packets, the CS- + DON value of the NAL unit is calculated the same way as when + the single NAL unit session packetization mode is in use, with + SN1 being the SN value of the first FU-A packet. + + For a non-PACSI NAL unit in an NI-MTAP packet, the CS-DON value + is equal to the value of the DON field of the non-interleaved + multi-time aggregation unit. + + When the I-C MST packetization mode is in use, the DON values derived + according to [RFC6184] for all the NAL units in each of the RTP + sessions MUST indicate CS-DON values. + +5. Packetization Rules + + Section 6 of [RFC6184] applies in this memo, with the following + additions. + +5.1. Packetization Rules for Single-Session Transmission + + All receivers MUST support the single NAL unit packetization mode to + provide backward compatibility to endpoints supporting only the + single NAL unit mode of [RFC6184]. However, the use of single NAL + unit packetization mode (packetization-mode equal to 0) SHOULD be + avoided whenever possible, because encapsulating NAL units of small + sizes in their own packets (e.g., small NAL units containing + parameter sets, prefix NAL units, or SEI messages) is less efficient + due to the packet header overhead. + + All receivers MUST support the non-interleaved mode. + + Informative note: The non-interleaved mode of [RFC6184] does allow + an application to encapsulate a single NAL unit in a single RTP + packet. Historically, the single NAL unit mode has been included + in [RFC6184] only for compatibility with ITU-T Rec. H.241 Annex A + [H.241]. There is no point in carrying this historic ballast + towards a new application space such as the one provided with SVC. + The implementation complexity increase for supporting the + additional mechanisms of the non-interleaved mode (namely, STAP-A + and FU-A) is minor, whereas the benefits are significant. As a + result, the support of STAP-A and FU-A is required. Additionally, + + + + +Wenger, et al. Standards Track [Page 45] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + support for two of the three NAL unit types defined in this memo, + namely, empty NAL units and NI-MTAP is needed, as specified in + Section 4.5.1. + + A NAL unit of small size SHOULD be encapsulated in an aggregation + packet together with one or more other NAL units. For example, non- + VCL NAL units such as access unit delimiters, parameter sets, or SEI + NAL units are typically small. + + A prefix NAL unit and the NAL unit with which it is associated, and + which follows the prefix NAL unit in decoding order, SHOULD be + included in the same aggregation packet whenever an aggregation + packet is used for the associated NAL unit, unless this would violate + session MTU constraints or if fragmentation units are used for the + associated NAL unit. + + Informative note: Although the prefix NAL unit is ignored by an + H.264/AVC decoder, it is necessary in the SVC decoding process. + + Given the small size of the prefix NAL unit, it is best if it is + transported in the same RTP packet as its associated NAL unit. + + When only an H.264/AVC compatible subset of the SVC base layer is + transmitted in an RTP session, the subset MUST be encapsulated + according to [RFC6184]. This way, an [RFC6184] receiver will be able + to receive the H.264/AVC compatible bitstream subset. + + When a set of layers including one or more SVC enhancement layers is + transmitted in an RTP session, the set SHOULD be carried in one RTP + stream that SHOULD be encapsulated according to this memo. + +5.2. Packetization Rules for Multi-Session Transmission + + When MST is used, the packetization rules specified in Section 5.1 + still apply. In addition, the following packetization rules MUST be + followed, to ensure that decoding order of NAL units carried in the + sessions can be correctly recovered for each of the MST packetization + modes using the de-packetization process specified in Section 6.2. + + The NI-T and NI-TC modes both use timestamps to recover the decoding + order. In order to be able to do so, it is necessary for the RTP + packet stream to contain data for all sampling instances of a given + RTP session in all enhancement RTP sessions that depend on the given + RTP session. The NI-C and I-C modes do not have this limitation, and + use the CS-DON values as a means to explicitly indicate decoding + order, either directly coded in PACSI NAL units, or inferred from + + + + + +Wenger, et al. Standards Track [Page 46] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + them using the packetization rules. It is noted that the NI-TC mode + offers both alternatives and it is up to the receiver to select which + one to use. + +5.2.1. NI-T/NI-TC Packetization Rules + + When using the NI-T mode and a PACSI NAL unit is present, the T bit + MUST be equal to 0, i.e., the DONC field MUST NOT be present. + + When using the NI-T mode, the optional parameters sprop-mst-remux- + buf-size, sprop-remux-buf-req, remux-buf-cap, sprop-remux-init-buf- + time, sprop-mst-max-don-diff MUST NOT be present. + + When the NI-T or NI-TC MST mode is in use, the following applies. + + If one or more NAL units of an access unit of sampling time instance + t is present in RTP session A, then one or more NAL units of the same + access unit MUST be present in any enhancement RTP session that + depends on RTP session A. + + Informative note: The mapping between RTP and NTP format + timestamps is conveyed in RTCP SR packets. In addition, the + mechanisms for faster media timestamp synchronization discussed in + [RFC6051] may be used to speed up the acquisition of the RTP-to- + wall-clock mapping. + + Informative note: The rule above may require the insertion of NAL + units, typically when temporal scalability is used, i.e., an + enhancement RTP session does not contain any NAL units for an + access unit with a particular NTP timestamp (media timestamp), + which, however, is present in a lower enhancement RTP session or + the base RTP session. There are two ways to insert additional NAL + units in order to satisfy this rule: + + - One option for adding additional NAL units is to use empty NAL + units (defined in Section 4.10), which can be used by the + process described in Section 6.2.1 for the access unit + reordering process. + + - Additional NAL units may also be added by the encoder itself, + for example, by transmitting coded data that simply instruct the + decoder to repeat the previous picture. This option, however, + may be difficult to use with pre-encoded content. + + If a packet must be inserted in order to satisfy the above rule, + e.g., in case of a MANE generating multiple RTP streams out of a + single RTP stream, the inserted packet must have an RTP timestamp + that maps to the same wall-clock time (in NTP format) as the one of + + + +Wenger, et al. Standards Track [Page 47] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + the RTP timestamp of any packet of the access unit present in any + lower enhancement RTP session or the base RTP session. This is easy + to accomplish if the NAL unit or the packet can be inserted at the + time of the RTP stream generation, since the media timestamp (NTP + timestamp) must be the same for the inserted packet and the packet of + the corresponding access unit. If there is no knowledge of the media + time at RTP stream generation or if the RTP streams are not generated + at the same instance, this can be also applied later in the + transmission process. In this case the NTP timestamp of the inserted + packet can be calculated as follows. + + Assume that a packet A2 of an access unit with RTP timestamp TS_A2 is + present in base RTP session A, and that no packet of that access unit + is present in enhancement RTP session B, as shown in Figure 5. Thus, + a packet B2 must be inserted into session B following the rule above. + The most recent RTCP sender report in session A carries NTP timestamp + NTP_A and the RTP timestamp TS_A. The sender report in session B + with a lower NTP timestamp than NTP_A is NTP_B, and carries the RTP + timestamp TS_B. + + RTP session B:..B0........B1........(B2)...................... + + RTCP session B:.....SR(NTP_B,TS_B)............................. + + RTP session A:..A0........A1........A2........................ + + RTCP session A:..................SR(NTP_A,TS_A)................ + + -----------------|--x------|-----x---|------------------------> + NTP time + --------------------+<---------->+<->+------------------------> + t1 t2 RTP TS(B) time + + Figure 5. Example calculation of RTP timestamp for packet + insertion in an enhancement layer RTP session + + The vertical bars ("|")in the NTP time line in the figure above + indicate that access unit data is present in at least one of the + sessions. The "x" marks indicate the times of the sender reports. + The RTP timestamp time line for session B, shown right below the NTP + time line, indicates two time segments, t1 and t2. t1 is the time + difference between the sender reports between the two sessions, + expressed in RTP timestamp clock ticks, and t2 is the time difference + from the session A sender report to the A2 packet, again expressed in + RTP timestamp clock ticks. The sum of these differences is added to + + + + + + +Wenger, et al. Standards Track [Page 48] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + the RTP timestamp of the session report from session B in order to + derive the correct RTP timestamp for the inserted packet B2. In + other words: + + TS_B2 = TS_B + t1 + t2 + + Let toRTP() be a function that calculates the RTP time difference (in + clock ticks of the used clock) given an NTP timestamp difference, and + effRTPdiff() be a function that calculates the effective difference + between two timestamps, including wraparounds: + + effRTPdiff( ts1, ts2 ): + + if( ts1 <= ts2 ) then + effRTPdiff := ts1-ts2 + else + effRTPDiff := (4294967296 + ts2) - ts1 + We have: + + t1 = toRTP(NTP_A - NTP_B) and t2 = effRTPdiff(TS_A2, TS_A) + + Hence in order to generate the RTP timestamp TS_B2 for the inserted + packet B2, the RTP timestamp for packet B2 TS_B2 can be calculated as + follows. + + TS_B2 = TS_B + toRTP(NTP_A - NTP_B) + effRTPdiff(TS_A2, TS_A) + +5.2.2. NI-C/NI-TC Packetization Rules + + When the NI-C or NI-TC MST mode is in use, the following applies for + each of the RTP sessions. + + o For each single NAL unit packet containing a non-PACSI NAL unit, + the previous packet, if present, MUST have the same RTP timestamp + as the single NAL unit packet, and the following applies. + + o If the NALU-time of the non-PACSI NAL unit is not equal to the + NALU-time of the previous non-PACSI NAL unit in decoding order, + the previous packet MUST contain a PACSI NAL unit containing + the DONC field. + + o In an STAP-A packet the first NAL unit in the STAP-A packet MUST + be a PACSI NAL unit containing the DONC field. + + o For an FU-A packet the previous packet MUST have the same RTP + timestamp as the FU-A packet, and the following applies. + + + + + +Wenger, et al. Standards Track [Page 49] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o If the FU-A packet is the start of the fragmented NAL unit, the + following applies. + + o If the NALU-time of the fragmented NAL unit is not equal to + the NALU-time of the previous non-PACSI NAL unit in decoding + order, the previous packet MUST contain a PACSI NAL unit + containing the DONC field; + + o Otherwise, (the NALU-time of the fragmented NAL unit is + equal to the NALU-time of the previous non-PACSI NAL unit in + decoding order), the previous packet MAY contain a PACSI NAL + unit containing the DONC field. + + o Otherwise, if the FU-A packet is the end of the fragmented NAL + unit, the following applies. + + o If the next non-PACSI NAL unit in decoding order has NALU- + time equal to the NALU-time of the fragmented NAL unit, and + is carried in a number of FU-A packets or a single NAL unit + packet, the next packet MUST be a single NAL unit packet + containing a PACSI NAL unit containing the DONC field. + + o Otherwise (the FU-A packet is neither the start nor the end + of the fragmented NAL unit), the previous packet MUST be a + FU-A packet. + + o For each single NAL unit packet containing a PACSI NAL unit, if + present, the PACSI NAL unit MUST contain the DONC field. + + o When the optional media type parameter sprop-mst-csdon-always- + present is equal to 1, the session packetization mode in use MUST + be the non-interleaved mode, and only STAP-A and NI-MTAP packets + can be used. + +5.2.3. I-C Packetization Rules + + When the I-C MST packetization mode is in use, the following applies. + + o When a PACSI NAL unit is present, the T bit MUST be equal to 0, + i.e., the DONC field is not present, and the Y bit MUST be equal + to 0, i.e., the TL0PICIDX and IDRPICID are not present. + +5.2.4. Packetization Rules for Non-VCL NAL Units + + NAL units that do not directly encode video slices are known in H.264 + as non-VCL NAL units. Non-VCL units that are only used by, or only + relevant to, enhancement RTP sessions SHOULD be sent in the lowest + session to which they are relevant. + + + +Wenger, et al. Standards Track [Page 50] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Some senders, however, such as those sending pre-encoded data, may be + unable to easily determine which non-VCL units are relevant to which + session. Thus, non-VCL NAL units MAY, instead, be sent in a session + on which the session using these non-VCL NAL units depends (e.g., the + base RTP session). + + If a non-VCL unit is relevant to more than one RTP session, neither + of which depends on the other(s), the NAL unit MAY be sent in another + session on which all these sessions depend. + +5.2.5. Packetization Rules for Prefix NAL Units + + Section 5.1 of this memo applies, with the following addition. If + the base layer is sent in a base RTP session using [RFC6184], prefix + NAL units MAY be sent in the lowest enhancement RTP session rather + than in the base RTP session. + +6. De-Packetization Process + +6.1. De-Packetization Process for Single-Session Transmission + + For single-session transmission, where a single RTP session is used, + the de-packetization process specified in Section 7 of [RFC6184] + applies. + +6.2. De-Packetization Process for Multi-Session Transmission + + For multi-session transmission, where more than one RTP session is + used to receive data from the same SVC bitstream, the de- + packetization process is specified as follows. + + As for a single RTP session, the general concept behind the de- + packetization process is to reorder NAL units from transmission order + to the NAL unit decoding order. + + The sessions to be received MUST be identified by mechanisms + specified in Section 7.2.3. An enhancement RTP session typically + contains an RTP stream that depends on at least one other RTP + session, as indicated by mechanisms defined in Section 7.2.3. A + lower RTP session to an enhancement RTP session is an RTP session on + which the enhancement RTP session depends. The lowest RTP session + for a receiver is the base RTP session, which does not depend on any + other RTP session received by the receiver. The highest RTP session + for a receiver is the RTP session on which no other RTP session + received by the receiver depends. + + + + + + +Wenger, et al. Standards Track [Page 51] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + For each of the RTP sessions, the RTP reception process as specified + in RFC 3550 is applied. Then the received packets are passed into + the payload de-packetization process as defined in this memo. + + The decoding order of the NAL units carried in all the associated RTP + sessions is then recovered by applying one of the following + subsections, depending on which of the MST packetization modes is in + use. + +6.2.1. Decoding Order Recovery for the NI-T and NI-TC Modes + + The following process MUST be applied when the NI-T packetization + mode is in use. The following process MAY be applied when the NI-TC + packetization mode is in use. + + The process is based on RTP session dependency signaling, RTP + sequence numbers, and timestamps. + + The decoding order of NAL units within an RTP packet stream in RTP + session is given by the ordering of sequence numbers SN of the RTP + packets that contain the NAL units, and the order of appearance of + NAL units within a packet. + + Timing information according to the media timestamp TS, i.e., the NTP + timestamp as derived from the RTP timestamp of an RTP packet, is + associated with all NAL units contained in the same RTP packet + received in an RTP session. + + For NI-MTAP packets the NALU-time is derived for each contained NAL + unit by using the "TS offset" value in the NI-MTAP packet as defined + in Section 4.10, and is used instead of the RTP packet timestamp to + derive the media timestamp, e.g., using the NTP wall clock as + provided via RTCP sender reports. NAL units contained in + fragmentation packets are handled as defragmented, entire NAL units + with their own media timestamps. All NAL units associated with the + same value of media timestamp TS are part of the same access unit + AU(TS). Any empty NAL units SHOULD be kept as, effectively, access + unit indicators in the reordering process. Empty NAL units and PACSI + NAL units SHOULD be removed before passing access unit data to the + decoder. + + Informative note: These empty NAL units are used to associate NAL + units present in other RTP sessions with RTP sessions not + containing any data for an access unit of a particular time + instance. They act as access unit indicators in sessions that + would otherwise contain no data for the particular access unit. + The presence of these NAL units is ensured by the packetization + rules in Section 5.2.1. + + + +Wenger, et al. Standards Track [Page 52] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + It is assumed that the receiver has established an operation point + (DID, QID, and TID values), and has identified the highest + enhancement RTP session for this operation point. The decoding order + of NAL units from multiple RTP streams in multiple RTP sessions MUST + be recovered into a single sequence of NAL units, grouped into access + units, by performing any process equivalent to the following steps. + The general process is described in Section 4.2 of [RFC6051]. For + convenience the instructions of [RFC6051] are repeated and applied to + NAL units rather than to full RTP packets. Additionally, SVC- + specific extensions to the procedure in Section 4.2. of [RFC6051] + are presented in the following list: + + o The process should be started with the NAL units received in + the highest RTP session with the first media timestamp TS (in + NTP format) available in the session's (de-jittering) buffer. + It is assumed that packets in the de-jittering buffer are + already stored in RTP sequence number order. + + o Collect all NAL units associated with the same value of media + timestamp TS, starting from the highest RTP session, from all + the (de-jittering) buffers of the received RTP sessions. The + collected NAL units will be those associated with the access + unit AU(TS). + + o Place the collected NAL units in the order of session + dependency as derived by the dependency indication as specified + in Section 7.2.3, starting from the lowest RTP session. + + o Place the session ordered NAL units in decoding order within + the particular access unit by satisfying the NAL unit ordering + rules for SVC access units, as described in the informative + algorithm provided in Section 6.2.1.1. + + o Remove NI-MTAP and any PACSI NAL units from the access unit + AU(TS). + + o The access units can then be transferred to the decoder. + Access units AU(TS) are transferred to the decoder in the order + of appearance (given by the order of RTP sequence numbers) of + media timestamp values TS in the highest RTP session associated + with access unit AU(TS). + + Informative note: Due to packet loss it is possible that not + all sessions may have NAL units present for the media + timestamp value TS present in the highest RTP session. In + such a case, an algorithm may: a) proceed to the next + complete access unit with NAL units present in all the + received RTP sessions; or b) consider a new highest RTP + + + +Wenger, et al. Standards Track [Page 53] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + session, the highest RTP session for which the access unit + is complete, and apply the process above. The algorithm may + return to the original highest RTP session when a complete + and error-free access unit that contains NAL units in all + the sessions is received. + + The following gives an informative example. + + The example shown in Figure 6 refers to three RTP sessions A, B, and + C containing an SVC bitstream transmitted as 3 sources. In the + example, the dependency signaling (described in Section 7.2.3) + indicates that session A is the base RTP session, B is the first + enhancement RTP session and depends on A, and C is the second + enhancement RTP session and depends on A and B. A hierarchical + picture coding prediction structure is used, in which session A has + the lowest frame rate and sessions B and C have the same but higher + frame rate. + + The figure shows NAL units contained in RTP packets that are stored + in the de-jittering buffer at the receiver for session de- + packetization. The NAL units are already reordered according to + their RTP sequence number order and, if within an aggregation packet, + according to the order of their appearance within the aggregation + packet. The figure indicates for the received NAL units the decoding + order within the sessions, as well as the associated media (NTP) + timestamps ("TS[..]"). NAL units of the same access unit within a + session are grouped by "(.,.)" and share the same media timestamp TS, + which is shown at the bottom of the figure. Note that the timestamps + are not in increasing order since, in this example, the decoding + order is different from the output/display order. + + The process first proceeds to the NAL units associated with the first + media timestamp TS[1] present in the highest session C and + removes/ignores all preceding (in decoding order) NAL units to NAL + units with TS[1] in each of the de-jittering buffers of RTP sessions + A, B, and C. Then, starting from session C, the first media + timestamp available in decoding order (TS[1]) is selected and NAL + units starting from RTP session A, and sessions B and C are placed in + order of the RTP session dependency as required by Section 7.2.3 of + this memo (in the example for TS[1]: first session B and then session + C) into the access unit AU(TS[1]) associated with media timestamp + TS[1]. Then the next media timestamp TS[3] in order of appearance in + the highest RTP session C is processed and the process described + above is repeated. Note that there may be access units with no NAL + units present, e.g., in the lowest RTP session A (see, e.g., TS[1]). + With TS[8], the first access unit with NAL units present in all the + RTP sessions appears in the buffers. + + + + +Wenger, et al. Standards Track [Page 54] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + C: ------------(1,2)-(3,4)--(5)---(6)---(7,8)(9,10)-(11)--(12)---- + | | | | | | | | | | + B: -(1,2)-(3,4)-(5)---(6)--(7,8)-(9,10)-(11)-(12)--(13,14)(15,15)- + | | | | | | + A: -------(1)---------------(2)---(3)---------------(4)----(5)---- + ---------------------------------------------------decoding order--> + + TS: [4] [2] [1] [3] [8] [6] [5] [7] [12] [10] + + Key: + A, B, C - RTP sessions + Integer values in "()" - NAL unit decoding order within RTP session + "( )" - groups the NAL units of an access unit + in an RTP session + "|" - indicates corresponding NAL units of the + same access unit AU(TS[..]) in the RTP + sessions + Integer values in "[]" - media timestamp TS, sampling time + as derived, e.g., from NTP timestamp + associated with the access unit AU(TS[..]), + consisting of NAL units in the sessions + above each TS value. + + Figure 6. Example of decoding order recovery in multi-source + transmission. + +6.2.1.1. Informative Algorithm for NI-T Decoding Order Recovery within + an Access Unit + + Within an access unit, the [H.264] specification (Sections 7.4.1.2.3 + and G.7.4.1.2.3) constrains the valid decoding order of NAL units. + + These constraints make it possible to reconstruct a valid decoding + order for the NAL units of an access unit based only on the order of + NAL units in each session, the NAL unit headers, and Supplemental + Enhancement Information message headers. + + This section specifies an informative algorithm to reconstruct a + valid decoding order for NAL units within an access unit. Other NAL + unit orderings may also be valid; however, any compliant NAL unit + ordering will describe the same video stream and ancillary data as + the one produced by this algorithm. + + An actual implementation, of course, needs only to behave "as if" + this reordering is done. In particular, NAL units that are discarded + by an implementation's decoding process do not need to be reordered. + + + + + +Wenger, et al. Standards Track [Page 55] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + In this algorithm, NAL units within an access unit are first ordered + by NAL unit type, in the order specified in Table 12 below, except + from NAL unit type 14, which is handled specially as described in the + table. NAL units of the same type are then ordered as specified for + the type, if necessary. + + For the purposes of this algorithm, "session order" is the order of + NAL units implied by their transmission order within an RTP session. + For the non-interleaved and single NAL unit modes, this is the RTP + sequence number order coupled with the order of NAL units within an + aggregation unit. + + Table 12. Ordering of NAL unit types within an Access Unit + + Type Description / Comments + ----------------------------------------------------------- + 9 Access unit delimiter + + 7 Sequence parameter set + + 13 Sequence parameter set extension + + 15 Subset sequence parameter set + + 8 Picture parameter set + + 16-18 Reserved + + 6 Supplemental enhancement information (SEI) + If an SEI message with a first payload of 0 (Buffering + Period) is present, it must be the first SEI message. + + If SEI messages with a Scalable Nesting (30) payload and + a nested payload of 0 (Buffering Period) are present, + these then follow the first SEI message. Such an SEI + message with the all_layer_representations_in_au_flag + equal to 1 is placed first, followed by any others, + sorted in increasing order of DQId. + + All other SEI messages follow in any order. + + 14 Prefix NAL unit in scalable extension + 1 Coded slice of a non-IDR picture + 5 Coded slice of an IDR picture + + + + + + + +Wenger, et al. Standards Track [Page 56] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + NAL units of type 1 or 5 will be sent within only a + single session for any given access unit. They are + placed in session order. (Note: Any given access unit + will contain only NAL units of type 1 or type 5, not + both.) + + If NAL units of type 14 are present, every NAL unit of + type 1 or 5 is prefixed by a NAL unit of type 14. (Note: + Within an access unit, every NAL unit of type 14 is + identical, so correlation of type 14 NAL units with the + other NAL units is not necessary.) + + 12 Filler data + + The only restriction of filler data NAL units within an + access unit is that they shall not precede the first VCL + NAL unit with the same access unit. + + 19 Coded slice of an auxiliary coded picture without + partitioning + + These NAL units will be sent within only a single + session for any given access unit, and are placed in + session order. + + 20 Coded slice in scalable extension + 21-23 Reserved + + Type 20 NAL units are placed in increasing order of DQId. + Within each DQId value, they are placed in session order. + + (Note: SVC slices with a given DQId value will be sent + within only a single session for any given access unit.) + + Type 21-23 NAL units are placed immediately following + the non-reserved-type VCL NAL unit they follow in + session order. + + 10 End of sequence + + 11 End of stream + +6.2.2. Decoding Order Recovery for the NI-C, NI-TC, and I-C Modes + + The following process MUST be used when either the NI-C or I-C MST + packetization mode is in use. The following process MAY be applied + when the NI-TC MST packetization mode is in use. + + + + +Wenger, et al. Standards Track [Page 57] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + The RTP packets output from the RTP-level reception processing for + each session are placed into a re-multiplexing buffer. + + It is RECOMMENDED to set the size of the re-multiplexing buffer (in + bytes) equal to or greater than the value of the sprop-remux-buf-req + media type parameter of the highest RTP session the receiver + receives. + + The CS-DON value is calculated and stored for each NAL unit. + + Informative note: The CS-DON value of a NAL unit may rely on + information carried in another packet than the packet containing + the NAL unit. This happens, e.g., when the CS-DON values need to + be derived for non-PACSI NAL units contained in single NAL unit + packets, as the single NAL unit packets themselves do not contain + CS-DON information. In this case, when no packet containing + required CS-DON information is received for a NAL unit, this NAL + unit has to be discarded by the receiver as it cannot be fed to + the decoder in the correct order. When the optional media type + parameter sprop-mst-csdon-always-present is equal to 1, no such + dependency exists, i.e., the CS-DON value of any particular NAL + unit can be derived solely according to information in the packet + containing the NAL unit, and therefore, the receiver does not need + to discard any received NAL units. + + The receiver operation is described below with the help of the + following functions and constants: + + o Function AbsDON is specified in Section 8.1 of [RFC6184]. + + o Function don_diff is specified in Section 5.5 of [RFC6184]. + + o Constant N is the value of the OPTIONAL sprop-mst-remux-buf-size + media type parameter of the highest RTP session incremented by 1. + + Initial buffering lasts until one of the following conditions is + fulfilled: + + o There are N or more VCL NAL units in the re-multiplexing buffer. + + o If sprop-mst-max-don-diff of the highest RTP session is present, + don_diff(m,n) is greater than the value of sprop-mst-max-don-diff + of the highest RTP session, where n corresponds to the NAL unit + having the greatest value of AbsDON among the received NAL units + and m corresponds to the NAL unit having the smallest value of + AbsDON among the received NAL units. + + + + + +Wenger, et al. Standards Track [Page 58] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o Initial buffering has lasted for the duration equal to or greater + than the value of the OPTIONAL sprop-remux-init-buf-time media + type parameter of the highest RTP session. + + The NAL units to be removed from the re-multiplexing buffer are + determined as follows: + + o If the re-multiplexing buffer contains at least N VCL NAL units, + NAL units are removed from the re-multiplexing buffer and passed + to the decoder in the order specified below until the buffer + contains N-1 VCL NAL units. + + o If sprop-mst-max-don-diff of the highest RTP session is present, + all NAL units m for which don_diff(m,n) is greater than sprop- + max-don-diff of the highest RTP session are removed from the re- + multiplexing buffer and passed to the decoder in the order + specified below. Herein, n corresponds to the NAL unit having the + greatest value of AbsDON among the NAL units in the re- + multiplexing buffer. + + The order in which NAL units are passed to the decoder is specified + as follows: + + o Let PDON be a variable that is initialized to 0 at the beginning + of the RTP sessions. + + o For each NAL unit associated with a value of CS-DON, a CS-DON + distance is calculated as follows. If the value of CS-DON of the + NAL unit is larger than the value of PDON, the CS-DON distance is + equal to CS-DON - PDON. Otherwise, the CS-DON distance is equal + to 65535 - PDON + CS-DON + 1. + + o NAL units are delivered to the decoder in increasing order of CS- + DON distance. If several NAL units share the same value of CS- + DON distance, they can be passed to the decoder in any order. + + o When a desired number of NAL units have been passed to the + decoder, the value of PDON is set to the value of CS-DON for the + last NAL unit passed to the decoder. + +7. Payload Format Parameters + + This section specifies the parameters that MAY be used to select + optional features of the payload format and certain features of the + bitstream. The parameters are specified here as part of the media + type registration for the SVC codec. A mapping of the parameters + into the Session Description Protocol (SDP) [RFC4566] is also + + + + +Wenger, et al. Standards Track [Page 59] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + provided for applications that use SDP. Equivalent parameters could + be defined elsewhere for use with control protocols that do not use + SDP. + + Some parameters provide a receiver with the properties of the stream + that will be sent. The names of all these parameters start with + "sprop" for stream properties. Some of these "sprop" parameters are + limited by other payload or codec configuration parameters. For + example, the sprop-parameter-sets parameter is constrained by the + profile-level-id parameter. The media sender selects all "sprop" + parameters rather than the receiver. This uncommon characteristic of + the "sprop" parameters may be incompatible with some signaling + protocol concepts, in which case the use of these parameters SHOULD + be avoided. + +7.1. Media Type Registration + + The media subtype for the SVC codec has been allocated from the IETF + tree. + + The receiver MUST ignore any unspecified parameter. + + Informative note: Requiring that the receiver ignore unspecified + parameters allows for backward compatibility of future extensions. + For example, if a future specification that is backward compatible + to this specification specifies some new parameters, then a + receiver according to this specification is capable of receiving + data per the new payload but ignoring those parameters newly + specified in the new payload specification. This provision is + also present in [RFC6184]. + + Media Type name: video + + Media subtype name: H264-SVC + + Required parameters: none + + OPTIONAL parameters: + + In the following definitions of parameters, "the stream" or "the + NAL unit stream" refers to all NAL units conveyed in the current + RTP session in SST, and all NAL units conveyed in the current RTP + session and all NAL units conveyed in other RTP sessions that the + current RTP session depends on in MST. + + + + + + + +Wenger, et al. Standards Track [Page 60] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + profile-level-id: + A base16 [RFC4648] (hexadecimal) representation of the + following three bytes in the sequence parameter set or subset + sequence parameter set NAL unit specified in [H.264]: 1) + profile_idc; 2) a byte herein referred to as profile-iop, + composed of the values of constraint_set0_flag, + constraint_set1_flag, constraint_set2_flag, + constraint_set3_flag, constraint_set4_flag, + constraint_set5_flag, and reserved_zero_2bits, in bit- + significance order, starting from the most-significant bit, and + 3) level_idc. Note that reserved_zero_2bits is required to be + equal to 0 in [H.264], but other values for it may be specified + in the future by ITU-T or ISO/IEC. + + The profile-level-id parameter indicates the default sub- + profile, i.e., the subset of coding tools that may have been + used to generate the stream or that the receiver supports, and + the default level of the stream or the one that the receiver + supports. + + The default sub-profile is indicated collectively by the + profile_idc byte and some fields in the profile-iop byte. + Depending on the values of the fields in the profile-iop byte, + the default sub-profile may be the same set of coding tools + supported by one profile, or a common subset of coding tools of + multiple profiles, as specified in Subsection G.7.4.2.1.1 of + [H.264]. The default level is indicated by the level_idc byte, + and, when profile_idc is equal to 66, 77, or 88 (the Baseline, + Main, or Extended profile) and level_idc is equal to 11, + additionally by bit 4 (constraint_set3_flag) of the profile-iop + byte. When profile_idc is equal to 66, 77, or 88 (the + Baseline, Main, or Extended profile) and level_idc is equal to + 11, and bit 4 (constraint_set3_flag) of the profile-iop byte is + equal to 1, the default level is Level 1b. + + Table 13 lists all profiles defined in Annexes A and G of + [H.264] and, for each of the profiles, the possible + combinations of profile_idc and profile-iop that represent the + same sub-profile. + + Table 13. Combinations of profile_idc and profile-iop + representing the same sub-profile corresponding to the full set + of coding tools supported by one profile. In the following, x + may be either 0 or 1, while the profile names are indicated as + follows. CB: Constrained Baseline profile, B: Baseline + profile, M: Main profile, E: Extended profile, H: High profile, + H10: High 10 profile, H42: High 4:2:2 profile, H44: High 4:4:4 + Predictive profile, H10I: High 10 Intra profile, H42I: High + + + +Wenger, et al. Standards Track [Page 61] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + 4:2:2 Intra profile, H44I: High 4:4:4 Intra profile, C44I: + CAVLC 4:4:4 Intra profile, SB: Scalable Baseline profile, SH: + Scalable High profile, and SHI: Scalable High Intra profile. + + Profile profile_idc profile-iop + (hexadecimal) (binary) + + CB 42 (B) x1xx0000 + same as: 4D (M) 1xxx0000 + same as: 58 (E) 11xx0000 + B 42 (B) x0xx0000 + same as: 58 (E) 10xx0000 + M 4D (M) 0x0x0000 + E 58 00xx0000 + H 64 00000000 + H10 6E 00000000 + H42 7A 00000000 + H44 F4 00000000 + H10I 6E 00010000 + H42I 7A 00010000 + H44I F4 00010000 + C44I 2C 00010000 + SB 53 x0000000 + SH 56 0x000000 + SHI 56 0x010000 + + For example, in the table above, profile_idc equal to 58 + (Extended) with profile-iop equal to 11xx0000 indicates the + same sub-profile corresponding to profile_idc equal to 42 + (Baseline) with profile-iop equal to x1xx0000. Note that other + combinations of profile_idc and profile-iop (not listed in + Table 13) may represent a sub-profile equivalent to the common + subset of coding tools for more than one profile. Note also + that a decoder conforming to a certain profile may be able to + decode bitstreams conforming to other profiles. + + If profile-level-id is used to indicate stream properties, it + indicates that, to decode the stream, the minimum subset of + coding tools a decoder has to support is the default sub- + profile, and the lowest level the decoder has to support is the + default level. + + If the profile-level-id parameter is used for capability + exchange or session setup, it indicates the subset of coding + tools, which is equal to the default sub-profile, that the + codec supports for both receiving and sending. If max-recv- + level is not present, the default level from profile-level-id + indicates the highest level the codec wishes to support. If + + + +Wenger, et al. Standards Track [Page 62] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + max-recv-level is present, it indicates the highest level the + codec supports for receiving. For either receiving or sending, + all levels that are lower than the highest level supported MUST + also be supported. + + Informative note: Capability exchange and session setup + procedures should provide means to list the capabilities for + each supported sub-profile separately. For example, the + one-of-N codec selection procedure of the SDP Offer/Answer + model can be used (Section 10.2 of [RFC3264]). The one-of-N + codec selection procedure may also be used to provide + different combinations of profile_idc and profile-iop that + represent the same sub-profile. When there are many + different combinations of profile_idc and profile-iop that + represent the same sub-profile, using the one-of-N codec + selection procedure may result in a fairly large SDP + message. Therefore, a receiver should understand the + different equivalent combinations of profile_idc and + profile-iop that represent the same sub-profile, and be + ready to accept an offer using any of the equivalent + combinations. + + If no profile-level-id is present, the Baseline Profile without + additional constraints at Level 1 MUST be implied. + + max-recv-level: + This parameter MAY be used to indicate the highest level a + receiver supports when the highest level is higher than the + default level (the level indicated by profile-level-id). The + value of max-recv-level is a base16 (hexadecimal) + representation of the two bytes after the syntax element + profile_idc in the sequence parameter set NAL unit specified in + [H.264]: profile-iop (as defined above) and level_idc. If (the + level_idc byte of max-recv-level is equal to 11 and bit 4 of + the profile-iop byte of max-recv-level is equal to 1) or (the + level_idc byte of max-recv-level is equal to 9 and bit 4 of the + profile-iop byte of max-recv-level is equal to 0), the highest + level the receiver supports is Level 1b. Otherwise, the + highest level the receiver supports is equal to the level_idc + byte of max-recv-level divided by 10. + + max-recv-level MUST NOT be present if the highest level the + receiver supports is not higher than the default level. + + max-recv-base-level: + This parameter MAY be used to indicate the highest level a + receiver supports for the base layer when negotiating an SVC + stream. The value of max-recv-base-level is a base16 + + + +Wenger, et al. Standards Track [Page 63] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + (hexadecimal) representation of the two bytes after the syntax + element profile_idc in the sequence parameter set NAL unit + specified in [H.264]: profile-iop (as defined above) and + level_idc. If (the level_idc byte of max-recv-level is equal + to 11 and bit 4 of the profile-iop byte of max-recv-level is + equal to 1) or (the level_idc byte of max-recv-level is equal + to 9 and bit 4 of the profile-iop byte of max-recv-level is + equal to 0), the highest level the receiver supports for the + base layer is Level 1b. Otherwise, the highest level the + receiver supports for the base layer is equal to the level_idc + byte of max-recv-level divided by 10. + + max-mbps, max-fs, max-cpb, max-dpb, and max-br: + The common properties of these parameters are specified in + [RFC6184]. + + max-mbps: This parameter is as specified in [RFC6184]. + + max-fs: This parameter is as specified in [RFC6184]. + + max-cpb: The value of max-cpb is an integer indicating the maximum + coded picture buffer size in units of 1000 bits for the VCL HRD + parameters and in units of 1200 bits for the NAL HRD + parameters. Note that this parameter does not use units of + cpbBrVclFactor and cpbBrNALFactor (see Table A-1 of [H.264]). + The max-cpb parameter signals that the receiver has more memory + than the minimum amount of coded picture buffer memory required + by the signaled highest level conveyed in the value of the + profile-level-id parameter or the max-recv-level parameter. + When max-cpb is signaled, the receiver MUST be able to decode + NAL unit streams that conform to the signaled highest level, + with the exception that the MaxCPB value in Table A-1 of + [H.264] for the signaled highest level is replaced with the + value of max-cpb (after taking cpbBrVclFactor and + cpbBrNALFactor into consideration when needed). The value of + max-cpb (after taking cpbBrVclFactor and cpbBrNALFactor into + consideration when needed) MUST be greater than or equal to the + value of MaxCPB given in Table A-1 of [H.264] for the highest + level. Senders MAY use this knowledge to construct coded video + streams with greater variation of bitrate than can be achieved + with the MaxCPB value in Table A-1 of [H.264]. + + + + + + + + + + +Wenger, et al. Standards Track [Page 64] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Informative note: The coded picture buffer is used in the + Hypothetical Reference Decoder (HRD, Annex C) of [H.264]. + The use of the HRD is recommended in SVC encoders to verify + that the produced bitstream conforms to the standard and to + control the output bitrate. Thus, the coded picture buffer + is conceptually independent of any other potential buffers + in the receiver, including de-interleaving, re-multiplexing, + and de-jitter buffers. The coded picture buffer need not be + implemented in decoders as specified in Annex C of [H.264]; + standard-compliant decoders can have any buffering + arrangements provided that they can decode standard- + compliant bitstreams. Thus, in practice, the input buffer + for video decoder can be integrated with the de- + interleaving, re-multiplexing, and de-jitter buffers of the + receiver. + + max-dpb: This parameter is as specified in [RFC6184]. + + max-br: The value of max-br is an integer indicating the maximum + video bitrate in units of 1000 bits per second for the VCL HRD + parameters and in units of 1200 bits per second for the NAL HRD + parameters. Note that this parameter does not use units of + cpbBrVclFactor and cpbBrNALFactor (see Table A-1 of [H.264]). + + The max-br parameter signals that the video decoder of the + receiver is capable of decoding video at a higher bitrate than + is required by the signaled highest level conveyed in the value + of the profile-level-id parameter or the max-recv-level + parameter. + + When max-br is signaled, the video codec of the receiver MUST + be able to decode NAL unit streams that conform to the signaled + highest level, with the following exceptions in the limits + specified by the highest level: + + o The value of max-br (after taking cpbBrVclFactor and + cpbBrNALFactor into consideration when needed) replaces the + MaxBR value in Table A-1 of [H.264] for the highest level. + + o When the max-cpb parameter is not present, the result of the + following formula replaces the value of MaxCPB in Table A-1 + of [H.264]: (MaxCPB of the signaled level) * max-br / (MaxBR + of the signaled highest level). + + For example, if a receiver signals capability for Main profile + Level 1.2 with max-br equal to 1550, this indicates a maximum + video bitrate of 1550 kbits/sec for VCL HRD parameters, a + + + + +Wenger, et al. Standards Track [Page 65] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + maximum video bitrate of 1860 kbits/sec for NAL HRD parameters, + and a CPB size of 4036458 bits (1550000 / 384000 * 1000 * + 1000). + + The value of max-br (after taking cpbBrVclFactor and + cpbBrNALFactor into consideration when needed) MUST be greater + than or equal to the value MaxBR given in Table A-1 of [H.264] + for the signaled highest level. + + Senders MAY use this knowledge to send higher-bitrate video as + allowed in the level definition of SVC, to achieve improved + video quality. + + Informative note: This parameter was added primarily to + complement a similar codepoint in the ITU-T Recommendation + H.245, so as to facilitate signaling gateway designs. No + assumption can be made from the value of this parameter that + the network is capable of handling such bitrates at any + given time. In particular, no conclusion can be drawn that + the signaled bitrate is possible under congestion control + constraints. + + redundant-pic-cap: + This parameter is as specified in [RFC6184]. + + sprop-parameter-sets: + This parameter MAY be used to convey any sequence parameter + set, subset sequence parameter set, and picture parameter set + NAL units (herein referred to as the initial parameter set NAL + units) that can be placed in the NAL unit stream to precede any + other NAL units in decoding order and that are associated with + the default level of profile-level-id. The parameter MUST NOT + be used to indicate codec capability in any capability exchange + procedure. The value of the parameter is a comma (',') + separated list of base64 [RFC4648] representations of the + parameter set NAL units as specified in Sections 7.3.2.1, + 7.3.2.2, and G.7.3.2.1 of [H.264]. Note that the number of + bytes in a parameter set NAL unit is typically less than 10, + but a picture parameter set NAL unit can contain several + hundreds of bytes. + + Informative note: When several payload types are offered in + the SDP Offer/Answer model, each with its own sprop- + parameter-sets parameter, then the receiver cannot assume + that those parameter sets do not use conflicting storage + locations (i.e., identical values of parameter set + + + + + +Wenger, et al. Standards Track [Page 66] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + identifiers). Therefore, a receiver should buffer all + sprop-parameter-sets and make them available to the decoder + instance that decodes a certain payload type. + + sprop-level-parameter-sets: + This parameter MAY be used to convey any sequence, subset + sequence, and picture parameter set NAL units (herein referred + to as the initial parameter set NAL units) that can be placed + in the NAL unit stream to precede any other NAL units in + decoding order and that are associated with one or more levels + different than the default level of profile-level-id. The + parameter MUST NOT be used to indicate codec capability in any + capability exchange procedure. + + The sprop-level-parameter-sets parameter contains parameter + sets for one or more levels that are different than the default + level. All parameter sets targeted for use when one level of + the default sub-profile is accepted by a receiver are clustered + and prefixed with a three-byte field that has the same syntax + as profile-level-id. This enables the receiver to install the + parameter sets for the accepted level and discard the rest. + The three-byte field is named PLId, and all parameter sets + associated with one level are named PSL, which has the same + syntax as sprop-parameter-sets. Parameter sets for each level + are represented in the form of PLId:PSL, i.e., PLId followed by + a colon (':') and the base64 [RFC4648] representation of the + initial parameter set NAL units for the level. Each pair of + PLId:PSL is also separated by a colon. Note that a PSL can + contain multiple parameter sets for that level, separated with + commas (','). + + The subset of coding tools indicated by each PLId field MUST be + equal to the default sub-profile, and the level indicated by + each PLId field MUST be different than the default level. + + Informative note: This parameter allows for efficient level + downgrade or upgrade in SDP Offer/Answer and out-of-band + transport of parameter sets, simultaneously. + + in-band-parameter-sets: + This parameter MAY be used to indicate a receiver capability. + The value MAY be equal to either 0 or 1. The value 1 indicates + that the receiver discards out-of-band parameter sets in sprop- + parameter-sets and sprop-level-parameter-sets, therefore the + sender MUST transmit all parameter sets in-band. The value 0 + indicates that the receiver utilizes out-of-band parameter sets + included in sprop-parameter-sets and/or sprop-level-parameter- + sets. However, in this case, the sender MAY still choose to + + + +Wenger, et al. Standards Track [Page 67] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + send parameter sets in-band. When the parameter is not + present, this receiver capability is not specified, and + therefore the sender MAY send out-of-band parameter sets only, + or it MAY send in-band-parameter-sets only, or it MAY send + both. + + packetization-mode: + This parameter is as specified in [RFC6184]. When the mst-mode + parameter is present, the value of this parameter is + additionally constrained as follows. If mst-mode is equal to + "NI-T", "NI-C", or "NI-TC", packetization-mode MUST NOT be + equal to 2. Otherwise, (mst-mode is equal to "I-C"), + packetization-mode MUST be equal to 2. + + sprop-interleaving-depth: + This parameter is as specified in [RFC6184]. + + sprop-deint-buf-req: + This parameter is as specified in [RFC6184]. + + deint-buf-cap: + This parameter is as specified in [RFC6184]. + + sprop-init-buf-time: + This parameter is as specified in [RFC6184]. + + sprop-max-don-diff: + This parameter is as specified in [RFC6184]. + + max-rcmd-nalu-size: + This parameter is as specified in [RFC6184]. + + mst-mode: + This parameter MAY be used to signal the properties of a NAL + unit stream or the capabilities of a receiver implementation. + If this parameter is present, multi-session transmission MUST + be used. Otherwise (this parameter is not present), single- + session transmission MUST be used. When this parameter is + present, the following applies. When the value of mst-mode is + equal to "NI-T", the NI-T mode MUST be used. When the value of + mst-mode is equal to "NI-C", the NI-C mode MUST be used. When + the value of mst-mode is equal to "NI-TC", the NI-TC mode MUST + be used. When the value of mst-mode is equal to "I-C", the I-C + mode MUST be used. The value of mst-mode MUST have one of the + following tokens: "NI-T", "NI-C", "NI-TC", or "I-C". + + All RTP sessions in an MST MUST have the same value of mst- + mode. + + + +Wenger, et al. Standards Track [Page 68] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + sprop-mst-csdon-always-present: + This parameter MUST NOT be present when mst-mode is not present + or the value of mst-mode is equal to "NI-T" or "I-C". This + parameter signals the properties of the NAL unit stream. When + sprop-mst-csdon-always-present is present and the value is + equal to 1, packetization-mode MUST be equal to 1, and all the + RTP packets carrying the NAL unit stream MUST be STAP-A packets + containing a PACSI NAL unit that further contains the DONC + field or NI-MTAP packets with the J field equal to 1. When + sprop-mst-csdon-always-present is present and the value is + equal to 1, the CS-DON value of any particular NAL unit can be + derived solely according to information in the packet + containing the NAL unit. + + When sprop-mst-csdon-always-present is present in the current + RTP session, it MUST be present also in all the RTP sessions + the current RTP session depends on and the value of sprop-mst- + csdon-always-present is identical for the current RTP session + and all the RTP sessions on which the current RTP session + depends. + + sprop-mst-remux-buf-size: + This parameter MUST NOT be present when mst-mode is not present + or the value of mst-mode is equal to "NI-T". This parameter + MUST be present when mst-mode is present and the value of mst- + mode is equal to "NI-C", "NI-TC", or "I-C". + + This parameter signals the properties of the NAL unit stream. + It MUST be set to a value one less than the minimum re- + multiplexing buffer size (in NAL units), so that it is + guaranteed that receivers can reconstruct NAL unit decoding + order as specified in Subsection 6.2.2. + + The value of sprop-mst-remux-buf-size MUST be an integer in the + range of 0 to 32767, inclusive. + + sprop-remux-buf-req: + This parameter MUST NOT be present when mst-mode is not present + or the value of mst-mode is equal to "NI-T". It MUST be + present when mst-mode is present and the value of mst-mode is + equal to "NI-C", "NI-TC", or "I-C". + + sprop-remux-buf-req signals the required size of the re- + multiplexing buffer for the NAL unit stream. It is guaranteed + that receivers can recover the decoding order of the received + NAL units from the current RTP session and the RTP sessions the + + + + + +Wenger, et al. Standards Track [Page 69] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + current RTP session depends on as specified in Section 6.2.2, + when the re-multiplexing buffer size is of at least the value + of sprop-remux-buf-req in units of bytes. + + The value of sprop-remux-buf-req MUST be an integer in the + range of 0 to 4294967295, inclusive. + + remux-buf-cap: + This parameter MUST NOT be present when mst-mode is not present + or the value of mst-mode is equal to "NI-T". This parameter + MAY be used to signal the capabilities of a receiver + implementation and indicates the amount of re-multiplexing + buffer space in units of bytes that the receiver has available + for recovering the NAL unit decoding order as specified in + Section 6.2.2. A receiver is able to handle any NAL unit + stream for which the value of the sprop-remux-buf-req parameter + is smaller than or equal to this parameter. + + If the parameter is not present, then a value of 0 MUST be used + for remux-buf-cap. The value of remux-buf-cap MUST be an + integer in the range of 0 to 4294967295, inclusive. + + sprop-remux-init-buf-time: + This parameter MAY be used to signal the properties of the NAL + unit stream. The parameter MUST NOT be present if mst-mode is + not present or the value of mst-mode is equal to "NI-T". + + The parameter signals the initial buffering time that a + receiver MUST wait before starting to recover the NAL unit + decoding order as specified in Section 6.2.2 of this memo. + + The parameter is coded as a non-negative base10 integer + representation in clock ticks of a 90-kHz clock. If the + parameter is not present, then no initial buffering time value + is defined. Otherwise, the value of sprop-remux-init-buf-time + MUST be an integer in the range of 0 to 4294967295, inclusive. + + sprop-mst-max-don-diff: + This parameter MAY be used to signal the properties of the NAL + unit stream. It MUST NOT be used to signal transmitter or + receiver or codec capabilities. The parameter MUST NOT be + present if mst-mode is not present or the value of mst-mode is + equal to "NI-T". sprop-mst-max-don-diff is an integer in the + range of 0 to 32767, inclusive. If sprop-mst-max-don-diff is + not present, the value of the parameter is unspecified. sprop- + mst-max-don-diff is calculated same as sprop-max-don-diff as + specified in [RFC6184], with decoding order number being + replaced by cross-session decoding order number. + + + +Wenger, et al. Standards Track [Page 70] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + sprop-scalability-info: + This parameter MAY be used to convey the NAL unit containing + the scalability information SEI message as specified in Annex G + of [H.264]. This parameter MAY be used to signal the contained + layers of an SVC bitstream. The parameter MUST NOT be used to + indicate codec capability in any capability exchange procedure. + The value of the parameter is the base64 [RFC4648] + representation of the NAL unit containing the scalability + information SEI message. If present, the NAL unit MUST contain + only one SEI message that is a scalability information SEI + message. + + This parameter MAY be used in an offering or declarative SDP + message to indicate what layers (operation points) can be + provided. A receiver MAY indicate its choice of one layer + using the optional media type parameter scalable-layer-id. + + scalable-layer-id: + This parameter MAY be used to signal a receiver's choice of the + offers or declared operation points or layers using sprop- + scalability-info or sprop-operation-point-info. The value of + scalable-layer-id is a base16 representation of the layer_id[ i + ] syntax element in the scalability information SEI message as + specified in Annex G of [H.264] or layer-ID contained in sprop- + operation-point-info. + + sprop-operation-point-info: + This parameter MAY be used to describe the operation points of + an RTP session. The value of this parameter consists of a + comma-separated list of operation-point-description vectors. + The values given by the operation-point-description vectors are + the same as, or are derived from, the values that would be + given for a scalable layer in the scalability information SEI + message as specified in Annex G of [H.264], where the term + scalable layer in the scalability information SEI message + refers to all NAL units associated with the same values of + temporal_id, dependency_id, and quality_id. In this memo, such + a set of NAL units is called an operation point. + + Each operation-point-description vector has ten elements, + provided as a comma-separated list of values as defined below. + The first value of the operation-point-description vector is + preceded by a '<', and the last value of the operation-point- + description vector is followed by a '>'. If the sprop- + operation-point-info is followed by exactly one operation- + point-description vector, this describes the highest operation + point contained in the RTP session. If there are two or more + + + + +Wenger, et al. Standards Track [Page 71] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + operation-point-description vectors, the first describes the + lowest and the last describes the highest operation point + contained in the RTP session. + + The values given by the operation-point-description vector are + as follows, in the order listed: + + - layer-ID: This value specifies the layer identifier of the + operation point, which is identical to the layer_id that + would be indicated (for the same values of dependency_id, + quality_id, and temporal_id) in the scalability information + SEI message. This field MAY be empty, indicating that the + value is unspecified. When there are multiple operation- + point-description vectors with layer-ID, the values of + layer-ID do not need to be consecutive. + + - temporal-ID: This value specifies the temporal_id of the + operation point. This field MUST NOT be empty. + + - dependency-ID: This values specifies the dependency_id of + the operation point. This field MUST NOT be empty. + + - quality-ID: This values specifies the quality_id of the + operation point. This field MUST NOT be empty. + + - profile-level-ID: This value specifies the profile-level-idc + of the operation point in the base16 format. The default + sub-profile or default level indicated by the parameter + profile-level-ID in the sprop-operation-point-info vector + SHALL be equal to or lower than the default sub-profile or + default level indicated by profile-level-id, which may be + either present or the default value is taken. This field + MAY be empty, indicating that the value is unspecified. + + - avg-framerate: This value specifies the average frame rate + of the operation point. This value is given as an integer + in frames per 256 seconds. The field MAY be empty, + indicating that the value is unspecified. + + - width: This value specifies the width dimension in pixels of + decoded frames for the operation point. This parameter is + not directly given in the scalability information SEI + message. This field MAY be empty, indicating that the value + is unspecified. + + + + + + + +Wenger, et al. Standards Track [Page 72] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + - height: This value gives the height dimension in pixels of + decoded frames for the operation point. This parameter is + not directly given in the scalability information SEI. This + field MAY be empty, indicating that the value is + unspecified. + + - avg-bitrate: This value specifies the average bitrate of the + operation point. This parameter is given as an integer in + kbits per second over the entire stream. Note that this + parameter is provided in the scalability information SEI + message in bits per second and calculated over a variable + time window. This field MAY be empty, indicating that the + value is unspecified. + + - max-bitrate: This value specifies the maximum bitrate of the + operation point. This parameter is given as an integer in + kbits per second and describes the maximum bitrate per each + one-second window. Note that this parameter is provided in + the scalability information SEI message in bits per second + and is calculated over a variable time window. This field + MAY be empty, indicating that the value is unspecified. + + Similarly to sprop-scalability-info, this parameter MAY be + used in an offering or declarative SDP message to indicate + what layers (operation points) can be provided. A receiver + MAY indicate its choice of the highest layer it wants to + send and/or receive using the optional media type parameter + scalable-layer-id. + + sprop-no-NAL-reordering-required: + This parameter MAY be used to signal the properties of the NAL + unit stream. This parameter MUST NOT be present when mst-mode + is not present or the value of mst-mode is not equal to "NI-T". + The presence of this parameter indicates that no reordering of + non-VCL or VCL NAL units is required for the decoding order + recovery process. + + sprop-avc-ready: + This parameter MAY be used to indicate the properties of the + NAL unit stream. The presence of this parameter indicates that + the RTP session, if used in SST, or used in MST combined with + other RTP sessions also with this parameter present, can be + processed by a [RFC6184] receiver. This parameter MAY be used + with RTP sessions with media subtype H264-SVC. + + Encoding considerations: + This media type is framed and binary; see Section 4.8 of RFC + 4288 [RFC4288]. + + + +Wenger, et al. Standards Track [Page 73] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Security considerations: + See Section 8 of RFC 6190. + + Published specification: + Please refer to RFC 6190 and its Section 13. + + Additional information: + none + + File extensions: none + + Macintosh file type code: none + + Object identifier or OID: none + + Person & email address to contact for further information: + + Ye-Kui Wang, yekui.wang@huawei.com + + Intended usage: COMMON + + Restrictions on usage: + This media type depends on RTP framing, and hence is only + defined for transfer via RTP [RFC3550]. Transport within other + framing protocols is not defined at this time. + + Interoperability considerations: + The media subtype name contains "SVC" to avoid potential + conflict with RFC 3984 and its potential future replacement RTP + payload format for H.264 non-SVC profiles. + + Applications that use this media type: + Real-time video applications like video streaming, video + telephony, and video conferencing. + + Author: + + Ye-Kui Wang, yekui.wang@huawei.com + + Change controller: + IETF Audio/Video Transport working group delegated from the + IESG. + + + + + + + + + +Wenger, et al. Standards Track [Page 74] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +7.2. SDP Parameters + +7.2.1. Mapping of Payload Type Parameters to SDP + + The media type video/H264-SVC string is mapped to fields in the + Session Description Protocol (SDP) as follows: + + o The media name in the "m=" line of SDP MUST be video. + + o The encoding name in the "a=rtpmap" line of SDP MUST be H264-SVC + (the media subtype). + + o The clock rate in the "a=rtpmap" line MUST be 90000. + + o The OPTIONAL parameters profile-level-id, max-recv-level, max- + recv-base-level, max-mbps, max-fs, max-cpb, max-dpb, max-br, + redundant-pic-cap, in-band-parameter-sets, packetization-mode, + sprop-interleaving-depth, deint-buf-cap, sprop-deint-buf-req, + sprop-init-buf-time, sprop-max-don-diff, max-rcmd-nalu-size, mst- + mode, sprop-mst-csdon-always-present, sprop-mst-remux-buf-size, + sprop-remux-buf-req, remux-buf-cap, sprop-remux-init-buf-time, + sprop-mst-max-don-diff, and scalable-layer-id, when present, MUST + be included in the "a=fmtp" line of SDP. These parameters are + expressed as a media type string, in the form of a semicolon- + separated list of parameter=value pairs. + + o The OPTIONAL parameters sprop-parameter-sets, sprop-level- + parameter-sets, sprop-scalability-info, sprop-operation-point- + info, sprop-no-NAL-reordering-required, and sprop-avc-ready, when + present, MUST be included in the "a=fmtp" line of SDP or conveyed + using the "fmtp" source attribute as specified in Section 6.3 of + [RFC5576]. For a particular media format (i.e., RTP payload + type), a sprop-parameter-sets or sprop-level-parameter-sets MUST + NOT be both included in the "a=fmtp" line of SDP and conveyed + using the "fmtp" source attribute. When included in the "a=fmtp" + line of SDP, these parameters are expressed as a media type + string, in the form of a semicolon-separated list of + parameter=value pairs. When conveyed using the "fmtp" source + attribute, these parameters are only associated with the given + source and payload type as parts of the "fmtp" source attribute. + + Informative note: Conveyance of sprop-parameter-sets and + sprop-level-parameter-sets using the "fmtp" source attribute + allows for out-of-band transport of parameter sets in + topologies like Topo-Video-switch-MCU [RFC5117]. + + + + + + +Wenger, et al. Standards Track [Page 75] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +7.2.2. Usage with the SDP Offer/Answer Model + + When an SVC stream (with media subtype H264-SVC) is offered over RTP + using SDP in an Offer/Answer model [RFC3264] for negotiation for + unicast usage, the following limitations and rules apply: + + o The parameters identifying a media format configuration for SVC + are profile-level-id, packetization-mode, and mst-mode. These + media configuration parameters (except for the level part of + profile-level-id) MUST be used symmetrically when the answerer + does not include scalable-layer-id in the answer; i.e., the + answerer MUST either maintain all configuration parameters or + remove the media format (payload type) completely, if one or more + of the parameter values are not supported. Note that the level + part of profile-level-id includes level_idc, and, for indication + of level 1b when profile_idc is equal to 66, 77, or 88, bit 4 + (constraint_set3_flag) of profile-iop. The level part of profile- + level-id is changeable. + + Informative note: The requirement for symmetric use does not + apply for the level part of profile-level-id, and does not + apply for the other stream properties and capability + parameters. + + Informative note: In [H.264], all the levels except for Level + 1b are equal to the value of level_idc divided by 10. Level 1b + is a level higher than Level 1.0 but lower than Level 1.1, and + is signaled in an ad hoc manner. For the Baseline, Main, and + Extended profiles (with profile_idc equal to 66, 77, and 88, + respectively), Level 1b is indicated by level_idc equal to 11 + (i.e., the same as level 1.1) and constraint_set3_flag equal to + 1. For other profiles, Level 1b is indicated by level_idc + equal to 9 (but note that Level 1b for these profiles is still + higher than Level 1, which has level_idc equal to 10, and lower + than Level 1.1). In SDP Offer/Answer, an answer may indicate a + level equal to or lower than the level indicated in the offer. + Due to the ad hoc indication of Level 1b, offerers and + answerers must check the value of bit 4 (constraint_set3_flag) + of the middle octet of the parameter profile-level-id, when + profile_idc is equal to 66, 77, or 88 and level_idc is equal to + 11. + + To simplify handling and matching of these configurations, the + same RTP payload type number used in the offer should also be used + in the answer, as specified in [RFC3264]. The same RTP payload + type number used in the offer MUST also be used in the answer when + the answer includes scalable-layer-id. When the answer does not + include scalable-layer-id, the answer MUST NOT contain a payload + + + +Wenger, et al. Standards Track [Page 76] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + type number used in the offer unless the configuration is exactly + the same as in the offer or the configuration in the answer only + differs from that in the offer with a level lower than the default + level offered. + + Informative note: When an offerer receives an answer that does + not include scalable-layer-id it has to compare payload types + not declared in the offer based on the media type (i.e., + video/H264-SVC) and the above media configuration parameters + with any payload types it has already declared. This will + enable it to determine whether the configuration in question is + new or if it is equivalent to configuration already offered, + since a different payload type number may be used in the + answer. + + Since an SVC stream may contain multiple operation points, a + facility is provided so that an answerer can select a different + operation point than the entire SVC stream. Specifically, + different operation points MAY be described using the sprop- + scalability-info or sprop-operation-point-info parameters. The + first one carries the entire scalability information SEI message + defined in Annex G of [H.264], whereas the second one may be + derived, e.g., as a subset of this SEI message that only contains + key information about an operation point. Operation points, in + both cases, are associated with a layer identifier. + + If such information (sprop-operation-point-info or sprop- + scalability-info) is provided in an offer, an answerer MAY select + from the various operation points offered in the sprop- + scalability-information or sprop-operation-point-info parameters + by including scalable-layer-id in the answer. By this, the + answerer indicates its selection of a particular operation point + in the received and/or in the sent stream. When such operation + point selection takes place, i.e., the answerer includes scalable- + layer-id in the answer, the media configuration parameters MUST + NOT be present in the answer. Rather, the media configuration + that the answerer will use for receiving and/or sending is the one + used for the selected operation point as indicated in the offer. + + Informative note: The ability to perform operation point + selection enables a receiver to utilize the scalable nature of + an SVC stream. + + o The parameter max-recv-level, when present, declares the highest + level supported for receiving. In case max-recv-level is not + present, the highest level supported for receiving is equal to the + + + + + +Wenger, et al. Standards Track [Page 77] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + default level indicated by the level part of profile-level-id. + max-recv-level, when present, MUST be higher than the default + level. + + o The parameter max-recv-base-level, when present, declares the + highest level of the base layer supported for receiving. When + max-recv-base-level is not present, the highest level supported + for the base layer is not constrained separately from the SVC + stream containing the base layer. The endpoint at the other side + MUST NOT send a scalable stream for which the base layer is of a + level higher than max-recv-base-level. Parameters declaring + receiver capabilities above the default level (max-mbps, max- + smbps, max-fs, max-cpb, max-dpb, max-br, and max-recv-level) do + not apply to the base layer when max-recv-base-level is present. + + o The parameters sprop-deint-buf-req, sprop-interleaving-depth, + sprop-max-don-diff, sprop-init-buf-time, sprop-mst-csdon-always- + present, sprop-remux-buf-req, sprop-mst-remux-buf-size, sprop- + remux-init-buf-time, sprop-mst-max-don-diff, sprop-scalability- + information, sprop-operation-point-info, sprop-no-NAL-reordering- + required, and sprop-avc-ready describe the properties of the NAL + unit stream that the offerer or answerer is sending for the media + format configuration. This differs from the normal usage of the + Offer/Answer parameters: normally such parameters declare the + properties of the stream that the offerer or the answerer is able + to receive. When dealing with SVC, the offerer assumes that the + answerer will be able to receive media encoded using the + configuration being offered. + + Informative note: The above parameters apply for any stream + sent by the declaring entity with the same configuration; i.e., + they are dependent on their source. Rather than being bound to + the payload type, the values may have to be applied to another + payload type when being sent, as they apply for the + configuration. + + o The capability parameters max-mbps, max-fs, max-cpb, max-dpb, max- + br, redundant-pic-cap, and max-rcmd-nalu-size MAY be used to + declare further capabilities of the offerer or answerer for + receiving. These parameters MUST NOT be present when the + direction attribute is sendonly, and the parameters describe the + limitations of what the offerer or answerer accepts for receiving + streams. + + o When mst-mode is not present and packetization-mode is equal to 2, + the following applies. + + + + + +Wenger, et al. Standards Track [Page 78] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o An offerer has to include the size of the de-interleaving + buffer, sprop-deint-buf-req, in the offer. To enable the + offerer and answerer to inform each other about their + capabilities for de-interleaving buffering, both parties are + RECOMMENDED to include deint-buf-cap. It is also RECOMMENDED + to consider offering multiple payload types with different + buffering requirements when the capabilities of the receiver + are unknown. + + o When mst-mode is present and equal to "NI-C", "NI-TC", or "I-C", + the following applies. + + o An offerer has to include sprop-remux-buf-req in the offer. To + enable the offerer and answerer to inform each other about + their capabilities for re-multiplexing buffering, both parties + are RECOMMENDED to include remux-buf-cap. It is also + RECOMMENDED to consider offering multiple payload types with + different buffering requirements when the capabilities of the + receiver are unknown. + + o The sprop-parameter-sets or sprop-level-parameter-sets parameter, + when present (included in the "a=fmtp" line of SDP or conveyed + using the "fmtp" source attribute as specified in Section 6.3 of + [RFC5576]), is used for out-of-band transport of parameter sets. + However, when out-of-band transport of parameter sets is used, + parameter sets MAY still be additionally transported in-band. + + The answerer MAY use either out-of-band or in-band transport of + parameter sets for the stream it is sending, regardless of whether + out-of-band parameter sets transport has been used in the offerer- + to-answerer direction. Parameter sets included in an answer are + independent of those parameter sets included in the offer, as they + are used for decoding two different video streams, one from the + answerer to the offerer, and the other in the opposite direction. + + The following rules apply to transport of parameter sets in the + offerer-to-answerer direction. + + o An offer MAY include either or both of sprop-parameter- sets + and sprop-level-parameter-sets. If neither sprop-parameter- + sets nor sprop-level-parameter-sets is present in the offer, + then only in-band transport of parameter sets is used. + + o If the answer includes in-band-parameter-sets equal to 1, then + the offerer MUST transmit parameter sets in-band. Otherwise, + the following applies. + + + + + +Wenger, et al. Standards Track [Page 79] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + o If the level to use in the offerer-to-answerer direction is + equal to the default level in the offer, the following + applies. + + The answerer MUST be prepared to use the parameter sets + included in sprop-parameter-sets, when present, for + decoding the incoming NAL unit stream, and ignore sprop- + level-parameter-sets, when present. + + When sprop-parameter-sets is not present in the offer, + in-band transport of parameter sets MUST be used. + + o Otherwise (the level to use in the offerer-to-answerer + direction is not equal to the default level in the offer), + the following applies. + + The answerer MUST be prepared to use the parameter sets + that are included in sprop-level-parameter-sets for the + accepted level (i.e., the default level in the answer, + which is also the level to use in the offerer-to-answerer + direction), when present, for decoding the incoming NAL + unit stream, and ignore all other parameter sets included + in sprop-level-parameter-sets and sprop-parameter-sets, + when present. + + When no parameter sets for the accepted level are present + in the sprop-level-parameter-sets, in-band transport of + parameter sets MUST be used. + + The following rules apply to transport of parameter sets in the + answerer-to-offerer direction. + + o An answer MAY include either sprop-parameter-sets or sprop- + level-parameter-sets, but MUST NOT include both of the two. If + neither sprop-parameter-sets nor sprop-level-parameter-sets is + present in the answer, then only in-band transport of parameter + sets is used. + + o If the offer includes in-band-parameter-sets equal to 1, then + the answerer MUST NOT include sprop-parameter-sets or sprop- + level-parameter-sets in the answer and MUST transmit parameter + sets in-band. Otherwise, the following applies. + + o If the level to use in the answerer-to-offerer direction is + equal to the default level in the answer, the following + applies. + + + + + +Wenger, et al. Standards Track [Page 80] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + The offerer MUST be prepared to use the parameter sets + included in sprop-parameter-sets, when present, for + decoding the incoming NAL unit stream, and ignore sprop- + level-parameter-sets, when present. + + When sprop-parameter-sets is not present in the answer, + the answerer MUST transmit parameter sets in-band. + + o Otherwise (the level to use in the answerer-to-offerer + direction is not equal to the default level in the answer), + the following applies. + + The offerer MUST be prepared to use the parameter sets + that are included in sprop-level-parameter-sets for the + level to use in the answerer-to-offerer direction, when + present in the answer, for decoding the incoming NAL unit + stream, and ignore all other parameter sets included in + sprop-level-parameter-sets and sprop-parameter-sets, when + present in the answer. + + When no parameter sets for the level to use in the + answerer-to-offerer direction are present in sprop-level- + parameter-sets in the answer, the answerer MUST transmit + parameter sets in-band. + + When sprop-parameter-sets or sprop-level-parameter-sets is + conveyed using the "fmtp" source attribute as specified in Section + 6.3 of [RFC5576], the receiver of the parameters MUST store the + parameter sets included in the sprop-parameter-sets or sprop- + level-parameter-sets for the accepted level and associate them to + the source given as a part of the "fmtp" source attribute. + Parameter sets associated with one source MUST only be used to + decode NAL units conveyed in RTP packets from the same source. + When this mechanism is in use, SSRC collision detection and + resolution MUST be performed as specified in [RFC5576]. + + Informative note: Conveyance of sprop-parameter-sets and sprop- + level-parameter-sets using the "fmtp" source attribute may be + used in topologies like Topo-Video-switch-MCU [RFC5117] to + enable out-of-band transport of parameter sets. + + For streams being delivered over multicast, the following rules + apply: + + o The media format configuration is identified by profile-level- id, + including the level part, packetization-mode, and mst-mode. These + media format configuration parameters (including the level part of + profile-level-id) MUST be used symmetrically; i.e., the answerer + + + +Wenger, et al. Standards Track [Page 81] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + MUST either maintain all configuration parameters or remove the + media format (payload type) completely. Note that this implies + that the level part of profile-level-id for Offer/Answer in + multicast is not changeable. + + To simplify handling and matching of these configurations, the + same RTP payload type number used in the offer should also be used + in the answer, as specified in [RFC3264]. An answer MUST NOT + contain a payload type number used in the offer unless the + configuration is the same as in the offer. + + o Parameter sets received MUST be associated with the originating + source, and MUST be only used in decoding the incoming NAL unit + stream from the same source. + + o The rules for other parameters are the same as above for unicast + as long as the above rules are obeyed. + + Table 14 lists the interpretation of all the parameters that MUST be + used for the various combinations of offer, answer, and direction + attributes. Note that the two columns wherein the scalable-layer-id + parameter is used only apply to answers, whereas the other columns + apply to both offers and answers. + + Table 14. Interpretation of parameters for various combinations of + offers, answers, direction attributes, with and without scalable- + layer-id. Columns that do not indicate offer or answer apply to + both. + + + + + + + + + + + + + + + + + + + + + + + +Wenger, et al. Standards Track [Page 82] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + sendonly --+ + answer: recvonly,scalable-layer-id --+ | + recvonly w/o scalable-layer-id --+ | | + answer: sendrecv, scalable-layer-id --+ | | | + sendrecv w/o scalable-layer-id --+ | | | | + | | | | | + profile-level-id C X C X P + max-recv-level R R R R - + max-recv-base-level R R R R - + packetization-mode C X C X P + mst-mode C X C X P + sprop-avc-ready P P - - P + sprop-deint-buf-req P P - - P + sprop-init-buf-time P P - - P + sprop-interleaving-depth P P - - P + sprop-max-don-diff P P - - P + sprop-mst-csdon-always-present P P - - P + sprop-mst-max-don-diff P P - - P + sprop-mst-remux-buf-size P P - - P + sprop-no-NAL-reordering-required P P - - P + sprop-operation-point-info P P - - P + sprop-remux-buf-req P P - - P + sprop-remux-init-buf-time P P - - P + sprop-scalability-info P P - - P + deint-buf-cap R R R R - + max-br R R R R - + max-cpb R R R R - + max-dpb R R R R - + max-fs R R R R - + max-mbps R R R R - + max-rcmd-nalu-size R R R R - + redundant-pic-cap R R R R - + remux-buf-cap R R R R - + in-band-parameter-sets R R R R - + sprop-parameter-sets S S - - S + sprop-level-parameter-sets S S - - S + scalable-layer-id X O X O - + + Legend: + + C: configuration for sending and receiving streams + P: properties of the stream to be sent + R: receiver capabilities + S: out-of-band parameter sets + O: operation point selection + X: MUST NOT be present + -: not usable, when present SHOULD be ignored + + + + +Wenger, et al. Standards Track [Page 83] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Parameters used for declaring receiver capabilities are in general + downgradable; i.e., they express the upper limit for a sender's + possible behavior. Thus, a sender MAY select to set its encoder + using only lower/lesser or equal values of these parameters. + + Parameters declaring a configuration point are not changeable, with + the exception of the level part of the profile-level-id parameter for + unicast usage. This expresses values a receiver expects to be used + and must be used verbatim on the sender side. If level downgrading + (for profile-level-id) is used, an answerer MUST NOT include the + scalable-layer-id parameter. + + When a sender's capabilities are declared, and non-downgradable + parameters are used in this declaration, then these parameters + express a configuration that is acceptable for the sender to receive + streams. In order to achieve high interoperability levels, it is + often advisable to offer multiple alternative configurations, e.g., + for the packetization mode. It is impossible to offer multiple + configurations in a single payload type. Thus, when multiple + configuration offers are made, each offer requires its own RTP + payload type associated with the offer. + + A receiver SHOULD understand all media type parameters, even if it + only supports a subset of the payload format's functionality. This + ensures that a receiver is capable of understanding when an offer to + receive media can be downgraded to what is supported by the receiver + of the offer. + + An answerer MAY extend the offer with additional media format + configurations. However, to enable their usage, in most cases a + second offer is required from the offerer to provide the stream + property parameters that the media sender will use. This also has + the effect that the offerer has to be able to receive this media + format configuration, not only to send it. + + If an offerer wishes to have non-symmetric capabilities between + sending and receiving, the offerer can allow asymmetric levels via + level-asymmetry-allowed equal to 1. Alternatively, the offerer can + offer different RTP sessions, i.e., different media lines declared as + "recvonly" and "sendonly", respectively. This may have further + implications on the system, and may require additional external + semantics to associate the two media lines. + +7.2.3. Dependency Signaling in Multi-Session Transmission + + If MST is used, the rules on signaling media decoding dependency in + SDP as defined in [RFC5583] apply. The rules on "hierarchical or + layered encoding" with multicast in Section 5.7 of [RFC4566] do not + + + +Wenger, et al. Standards Track [Page 84] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + apply, i.e., the notation for Connection Data "c=" SHALL NOT be used + with more than one address. Additionally, the order of dependencies + of the RTP sessions indicated by the "a=depend" attribute as defined + in [RFC5583] MUST represent the decoding order of the VC) NAL units + in an access unit, i.e., the order of session dependency is given + from the base or the lowest enhancement RTP session (the most + important) to the highest enhancement RTP session (the least + important). + +7.2.4. Usage in Declarative Session Descriptions + + When SVC over RTP is offered with SDP in a declarative style, as in + Real Time Streaming Protocol (RTSP) [RFC2326] or Session Announcement + Protocol (SAP) [RFC2974], the following considerations are necessary. + + o All parameters capable of indicating both stream properties and + receiver capabilities are used to indicate only stream properties. + For example, in this case, the parameter profile-level-id declares + the values used by the stream, not the capabilities for receiving + streams. This results in that the following interpretation of the + parameters MUST be used: + + Declaring actual configuration or stream properties: + + - profile-level-id + - packetization-mode + - mst-mode + - sprop-deint-buf-req + - sprop-interleaving-depth + - sprop-max-don-diff + - sprop-init-buf-time + - sprop-mst-csdon-always-present + - sprop-mst-remux-buf-size + - sprop-remux-buf-req + - sprop-remux-init-buf-time + - sprop-mst-max-don-diff + - sprop-scalability-info + - sprop-operation-point-info + - sprop-no-NAL-reordering-required + - sprop-avc-ready + + Out-of-band transporting of parameter sets: + + - sprop-parameter-sets + - sprop-level-parameter-sets + + + + + + +Wenger, et al. Standards Track [Page 85] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Not usable (when present, they SHOULD be ignored): + + - max-mbps + - max-fs + - max-cpb + - max-dpb + - max-br + - max-recv-level + - max-recv-base-level + - redundant-pic-cap + - max-rcmd-nalu-size + - deint-buf-cap + - remux-buf-cap + - scalable-layer-id + + o A receiver of the SDP is required to support all parameters and + values of the parameters provided; otherwise, the receiver MUST + reject (RTSP) or not participate in (SAP) the session. It falls + on the creator of the session to use values that are expected to + be supported by the receiving application. + +7.3. Examples + + In the following examples, "{data}" is used to indicate a data string + encoded as base64. + +7.3.1. Example for Offering a Single SVC Session + + Example 1: The offerer offers one video media description including + two RTP payload types. The first payload type offers H264, and the + second offers H264-SVC. Both payload types have different fmtp + parameters as profile-level-id, packetization-mode, and sprop- + parameter-sets. + + Offerer -> Answerer SDP message: + + m=video 20000 RTP/AVP 97 96 + a=rtpmap:96 H264/90000 + a=fmtp:96 profile-level-id=4de00a; packetization-mode=0; + sprop-parameter-sets={sps0},{pps0}; + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 profile-level-id=53000c; packetization-mode=1; + sprop-parameter-sets={sps0},{pps0},{sps1},{pps1}; + + If the answerer does not support media subtype H264-SVC, it can issue + an answer accepting only the base layer offer (payload type 96). In + the following example, the receiver supports H264-SVC, so it lists + payload type 97 first as the preferred option. + + + +Wenger, et al. Standards Track [Page 86] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Answerer -> Offerer SDP message: + + m=video 40000 RTP/AVP 97 96 + a=rtpmap:96 H264/90000 + a=fmtp:96 profile-level-id=4de00a; packetization-mode=0; + sprop-parameter-sets={sps2},{pps2}; + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 profile-level-id=53000c; packetization-mode=1; + sprop-parameter-sets={sps2},{pps2},{sps3},{pps3}; + +7.3.2. Example for Offering a Single SVC Session Using + scalable-layer-id + + Example 2: Offerer offers the same media configurations as shown in + the example above for receiving and sending the stream, but using a + single RTP payload type and including sprop-operation-point-info. + + Offerer -> Answerer SDP message: + + m=video 20000 RTP/AVP 97 + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 profile-level-id=53000c; packetization-mode=1; + sprop-parameter-sets={sps0},{sps1},{pps0},{pps1}; + sprop-operation-point-info=<1,0,0,0,4de00a,3200,176,144,128, + 256>,<2,1,1,0,53000c,6400,352,288,256,512>; + + In this example, the receiver supports H264-SVC and chooses the lower + operation point offered in the RTP payload type for sending and + receiving the stream. + + Answerer -> Offerer SDP message: + + m=video 40000 RTP/AVP 97 + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 sprop-parameter-sets={sps2},{sps3},{pps2},{pps3}; + scalable-layer-id=1; + + In an equivalent example showing the use of sprop-scalability-info + instead using the sprop-operation-point-info, the sprop-operation- + point-info would be exchanged by the sprop-scalability-info followed + by the binary (base16) representation of the Scalability Information + SEI message. + +7.3.3. Example for Offering Multiple Sessions in MST + + Example 3: In this example, the offerer offers a multi-session + transmission with up to three sessions. The base session media + description includes payload types that are backward compatible with + + + +Wenger, et al. Standards Track [Page 87] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + [RFC6184], and three different payload types are offered. The other + two media are using payload types with media subtype H264-SVC. In + each media description, different values of profile-level-id, + packetization-mode, mst-mode, and sprop-parameter-sets are offered. + + Offerer -> Answerer SDP message: + + a=group:DDP L1 L2 L3 + m=video 20000 RTP/AVP 96 97 98 + a=rtpmap:96 H264/90000 + a=fmtp:96 profile-level-id=4de00a; packetization-mode=0; + mst-mode=NI-T; sprop-parameter-sets={sps0},{pps0}; + a=rtpmap:97 H264/90000 + a=fmtp:97 profile-level-id=4de00a; packetization-mode=1; + mst-mode=NI-TC; sprop-parameter-sets={sps0},{pps0}; + a=rtpmap:98 H264/90000 + a=fmtp:98 profile-level-id=4de00a; packetization-mode=2; + mst-mode=I-C; init-buf-time=156320; + sprop-parameter-sets={sps0},{pps0}; + a=mid:L1 + m=video 20002 RTP/AVP 99 100 + a=rtpmap:99 H264-SVC/90000 + a=fmtp:99 profile-level-id=53000c; packetization-mode=1; + mst-mode=NI-T; sprop-parameter-sets={sps1},{pps1}; + a=rtpmap:100 H264-SVC/90000 + a=fmtp:100 profile-level-id=53000c; packetization-mode=2; + mst-mode=I-C; sprop-parameter-sets={sps1},{pps1}; + a=mid:L2 + a=depend:99 lay L1:96,97; 100 lay L1:98 + m=video 20004 RTP/AVP 101 + a=rtpmap:101 H264-SVC/90000 + a=fmtp:101 profile-level-id=53001F; packetization-mode=1; + mst-mode=NI-T; sprop-parameter-sets={sps2},{pps2}; + a=mid:L3 + a=depend:101 lay L1:96,97 L2:99 + + It is assumed that in this example the answerer only supports the NI- + T mode for multi-session transmission. For this reason, it chooses + the corresponding payload type (96) for the base RTP session. For + the two enhancement RTP sessions, the answerer also chooses the + payload types that use the NI-T mode (99 and 101). + + + + + + + + + + +Wenger, et al. Standards Track [Page 88] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + Answerer -> Offerer SDP message: + + a=group:DDP L1 L2 L3 + m=video 40000 RTP/AVP 96 + a=rtpmap:96 H264/90000 + a=fmtp:96 profile-level-id=4de00a; packetization-mode=0; + mst-mode=NI-T; sprop-parameter-sets={sps3},{pps3}; + a=mid:L1 + m=video 40002 RTP/AVP 99 + a=rtpmap:99 H264-SVC/90000 + a=fmtp:99 profile-level-id=53000c; packetization-mode=1; + mst-mode=NI-T; sprop-parameter-sets={sps4},{pps4}; + a=mid:L2 + a=depend:99 lay L1:96 + m=video 40004 RTP/AVP 101 + a=rtpmap:101 H264-SVC/90000 + a=fmtp:101 profile-level-id=53001F; packetization-mode=1; + mst-mode=NI-T; sprop-parameter-sets={sps5},{pps5}; + a=mid:L3 + a=depend:101 lay L1:96 L2:99 + +7.3.4. Example for Offering Multiple Sessions in MST Including + Operation with Answerer Using scalable-layer-id + + Example 4: In this example, the offerer offers a multi-session + transmission of three layers with up to two sessions. The base + session media description has a payload type that is backward + compatible with [RFC6184]. Note that no parameter sets are provided, + in which case in-band transport must be used. The other media + description contains two enhancement layers and uses the media + subtype H264-SVC. It includes two operation point definitions. + + Offerer -> Answerer SDP message: + + a=group:DDP L1 L2 + m=video 20000 RTP/AVP 96 + a=rtpmap:96 H264/90000 + a=fmtp:96 profile-level-id=4de00a; packetization-mode=0; + mst-mode=NI-T; + a=mid:L1 + m=video 20002 RTP/AVP 97 + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 profile-level-id=53001F; packetization-mode=1; + mst-mode=NI-TC; sprop-operation-point-info=<2,0,1,0,53000c, + 3200,352,288,384,512>,<3,1,2,0,53001F,6400,704,576,768,1024>; + a=mid:L2 + a=depend:97 lay L1:96 + + + + +Wenger, et al. Standards Track [Page 89] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + It is assumed that the answerer wants to send and receive the base + layer (payload type 96), but it only wants to send and receive the + lower enhancement layer, i.e., the one with layer id equal to 2. For + this reason, the response will include the selection of the desired + layer by setting scalable-layer-id equal to 2. Note that the answer + only includes the scalable-layer-id information. The answer could + include sprop-parameter-sets in the response. + + Answerer -> Offerer SDP message: + + a=group:DDP L1 L2 + m=video 40000 RTP/AVP 96 + a=rtpmap:96 H264/90000 + a=fmtp:96 profile-level-id=4de00a; packetization-mode=0; + mst-mode=NI-T; + a=mid:L1 + m=video 40002 RTP/AVP 97 + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 scalable-layer-id=2; + a=mid:L2 + a=depend:97 lay L1:96 + +7.3.5. Example for Negotiating an SVC Stream with a Constrained Base + Layer in SST + + Example 5: The offerer (Alice) offers one video description including + two RTP payload types with differing levels and packetization modes. + + Offerer -> Answerer SDP message: + + m=video 20000 RTP/AVP 97 96 + a=rtpmap:96 H264-SVC/90000 + a=fmtp:96 profile-level-id=53001e; packetization-mode=0; + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 profile-level-id=53001f; packetization-mode=1; + + The answerer (Bridge) chooses packetization mode 1, and indicates + that it would receive an SVC stream with the base layer being + constrained. + + Answerer -> Offerer SDP message: + + m=video 40000 RTP/AVP 97 + a=rtpmap:97 H264-SVC/90000 + a=fmtp:97 profile-level-id=53001f; packetization-mode=1; + max-recv-base-level=000d + + + + + +Wenger, et al. Standards Track [Page 90] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + The answering endpoint must send an SVC stream at Level 3.1. Since + the offering endpoint did not declare max-recv-base-level, the base + layer of the SVC stream the answering endpoint must send is not + specifically constrained. The offering endpoint (Alice) must send an + SVC stream at Level 3.1, for which the base layer must be of a level + not higher than Level 1.3. + +7.4. Parameter Set Considerations + + Section 8.4 of [RFC6184] applies in this memo, with the following + applies additionally for multi-session transmission (MST). + + In MST, regardless of out-of-band or in-band transport of parameter + sets are in use, parameter sets required for decoding NAL units + carried in one particular RTP session SHOULD be carried in the same + session, MAY be carried in a session that the particular RTP session + depends on, and MUST NOT be carried in a session that the particular + RTP session does not depend on. + +8. Security Considerations + + The security considerations of the RTP Payload Format for H.264 Video + specification [RFC6184] apply. Additionally, the following applies. + + Decoders MUST exercise caution with respect to the handling of + reserved NAL unit types and reserved SEI messages, particularly if + they contain active elements, and MUST restrict their domain of + applicability to the presentation containing the stream. The safest + way is to simply discard these NAL units and SEI messages. + + When integrity protection is applied to a stream, care MUST be taken + that the stream being transported may be scalable; hence a receiver + may be able to access only part of the entire stream. + + End-to-end security with either authentication, integrity, or + confidentiality protection will prevent a MANE from performing media- + aware operations other than discarding complete packets. And in the + case of confidentiality protection it will even be prevented from + performing discarding of packets in a media-aware way. To allow any + MANE to perform its operations, it will be required to be a trusted + entity that is included in the security context establishment. This + applies both for the media path and for the RTCP path, if RTCP + packets need to be rewritten. + + + + + + + + +Wenger, et al. Standards Track [Page 91] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +9. Congestion Control + + Within any given RTP session carrying payload according to this + specification, the provisions of Section 10 of [RFC6184] apply. + Reducing the session bitrate is possible by one or more of the + following means: + + a) Within the highest layer identified by the DID field remove any + NAL units with QID higher than a certain value. + + b) Remove all NAL units with TID higher than a certain value. + + c) Remove all NAL units associated with a DID higher than a certain + value. + + Informative note: Removal of all coded slice NAL units + associated with DIDs higher than a certain value in the entire + stream is required in order to preserve conformance of the + resulting SVC stream. + + d) Utilize the PRID field to indicate the relative importance of NAL + units, and remove all NAL units associated with a PRID higher than + a certain value. Note that the use of the PRID is application- + specific. + + e) Remove NAL units or entire packets according to application- + specific rules. The result will depend on the particular coding + structure used as well as any additional application-specific + functionality (e.g., concealment performed at the receiving + decoder). In general, this will result in the reception of a non- + conforming bitstream and hence the decoder behavior is not + specified by [H.264]. Significant artifacts may therefore appear + in the decoded output if the particular decoder implementation + does not take appropriate action in response to congestion + control. + + Informative note: The discussion above is centered on NAL units + rather than packets, primarily because that is the level where + senders can meaningfully manipulate the scalable bitstream. The + mapping of NAL units to RTP packets is fairly flexible when using + aggregation packets. Depending on the nature of the congestion + control algorithm, the "dimension" of congestion measurement + (packet count or bitrate) and reaction to it (reducing packet + count or bitrate or both) can be adjusted accordingly. + + All aforementioned means are available to the RTP sender, regardless + of whether that sender is located in the sending endpoint or in a + mixer-based MANE. + + + +Wenger, et al. Standards Track [Page 92] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + When a translator-based MANE is employed, then the MANE MAY + manipulate the session only on the MANE's outgoing path, so that the + sensed end-to-end congestion falls within the permissible envelope. + As with all translators, in this case, the MANE needs to rewrite RTCP + RRs to reflect the manipulations it has performed on the session. + + Informative note: Applications MAY also implement, in addition or + separately, other congestion control mechanisms, e.g., as + described in [RFC5775] and [Yan]. + +10. IANA Considerations + + A new media type, as specified in Section 7.1 of this memo, has been + registered with IANA. + +11. Informative Appendix: Application Examples + +11.1. Introduction + + Scalable video coding is a concept that has been around since at + least MPEG-2 [MPEG2], which goes back as early as 1993. + Nevertheless, it has never gained wide acceptance, perhaps partly + because applications didn't materialize in the form envisioned during + standardization. + + ISO/IEC MPEG and ITU-T VCEG, respectively, performed a requirement + analysis for the SVC project. The MPEG and VCEG requirement + documents are available in [JVT-N026] and [JVT-N027], respectively. + + The following introduces four main application scenarios that the + authors consider relevant and that are implementable with this + specification. + +11.2. Layered Multicast + + This well-understood form of the use of layered coding [McCanne] + implies that all layers are individually conveyed in their own RTP + packet streams, each carried in its own RTP session using the IP + (multicast) address and port number as the single demultiplexing + point. Receivers "tune" into the layers by subscribing to the IP + multicast, normally by using IGMP [IGMP]. Depending on the + application scenario, it is also possible to convey a number of + layers in one RTP session, when finer operation points within the + subset of layers are not needed. + + Layered multicast has the great advantage of simplicity and easy + implementation. However, it has also the great disadvantage of + utilizing many different transport addresses. While the authors + + + +Wenger, et al. Standards Track [Page 93] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + consider this not to be a major problem for a professionally + maintained content server, receiving client endpoints need to open + many ports to IP multicast addresses in their firewalls. This is a + practical problem from a firewall and network address translation + (NAT) viewpoint. Furthermore, even today IP multicast is not as + widely deployed as many wish. + + The authors consider layered multicast an important application + scenario for the following reasons. First, it is well understood and + the implementation constraints are well known. Second, there may + well be large-scale IP networks outside the immediate Internet + context that may wish to employ layered multicast in the future. One + possible example could be a combination of content creation and core- + network distribution for the various mobile TV services, e.g., those + being developed by 3GPP (MBMS) [MBMS] and DVB (DVB-H) [DVB-H]. + +11.3. Streaming + + In this scenario, a streaming server has a repository of stored SVC + coded layers for a given content. At the time of streaming, and + according to the capabilities, connectivity, and congestion situation + of the client(s), the streaming server generates and serves a + scalable stream. Both unicast and multicast serving is possible. At + the same time, the streaming server may use the same repository of + stored layers to compose different streams (with a different set of + layers) intended for other audiences. + + As every endpoint receives only a single SVC RTP session, the number + of firewall pinholes can be optimized to one. + + The main difference between this scenario and straightforward + simulcasting lies in the architecture and the requirements of the + streaming server, and is therefore out of the scope of IETF + standardization. However, compelling arguments can be made why such + a streaming server design makes sense. One possible argument is + related to storage space and channel bandwidth. Another is bandwidth + adaptability without transcoding -- a considerable advantage in a + congestion controlled network. When the streaming server learns + about congestion, it can reduce the sending bitrate by choosing fewer + layers when composing the layered stream; see Section 9. SVC is + designed to gracefully support both bandwidth ramp-down and bandwidth + ramp-up with a considerable dynamic range. This payload format is + designed to allow for bandwidth flexibility in the mentioned sense. + While, in theory, a transcoding step could achieve a similar dynamic + range, the computational demands are impractically high and video + quality is typically lowered -- therefore, few (if any) streaming + servers implement full transcoding. + + + + +Wenger, et al. Standards Track [Page 94] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +11.4. Videoconferencing (Unicast to MANE, Unicast to Endpoints) + + Videoconferencing has traditionally relied on Multipoint Control + Units (MCUs). These units connect endpoints in a star configuration + and operate as follows. Coded video is transmitted from each + endpoint to the MCU, where it is decoded, scaled, and composited to + construct output frames, which are then re-encoded and transmitted to + the endpoint(s). In systems supporting personalized layout (each + user is allowed to select the layout of his/her screen), the + compositing and encoding process is performed for each of the + receiving endpoints. Even without personalized layout, rate matching + still requires that the encoding process at the MCU is performed + separately for each endpoint. As a result, MCUs have considerable + complexity and introduce significant delay. The cascaded encodings + also reduce the video quality. Particularly for multipoint + connections, interactive communication is cumbersome as the end-to- + end delay is very high [G.114]. A simpler architecture is the + switching MCU, in which one of the incoming video streams is + redirected to the receiving endpoints. Obviously, only one user at a + time can be seen and rate matching cannot be performed, thus forcing + all transmitting endpoints to transmit at the lowest bit rate + available in the MCU-to-endpoint connections. + + With scalable video coding the MCU can be replaced with an + application-level router (ALR): this unit simply selects which + incoming packets should be transmitted to which of the receiving + endpoints [Eleft]. In such a system, each endpoint performs its own + composition of the incoming video streams. Assuming, for example, a + system that uses spatial scalability with two layers, personalized + layout is equivalent to instructing the ALR to only send the required + packets for the corresponding resolution to the particular endpoint. + Similarly, rate matching at the ALR for a particular endpoint can be + performed by selecting an appropriate subset of the incoming video + packets to transmit to the particular endpoint. Personalized layout + and rate matching thus become routing decisions, and require no + signal processing. Note that scalability also allows participants to + enjoy the best video quality afforded by their links, i.e., users no + longer have to be forced to operate at the quality supported by the + weakest endpoint. Most importantly, the ALR has an insignificant + contribution to the end-to-end delay, typically an order of magnitude + less than an MCU. This makes it possible to have fully interactive + multipoint conferences with even a very large number of participants. + There are significant advantages as well in terms of error resilience + and, in fact, error tolerance can be increased by nearly an order of + magnitude here as well (e.g., using unequal error protection). + Finally, the very low delay of an ALR allows these systems to be + + + + + +Wenger, et al. Standards Track [Page 95] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + cascaded, with significant benefits in terms of system design and + deployment. Cascading of traditional MCUs is impossible due to the + very high delay that even a single MCU introduces. + + Scalable video coding enables a very significant paradigm shift in + videoconferencing systems, bringing the complexity of video + communication systems (particularly the servers residing within the + network) in line with other types of network applications. + +11.5. Mobile TV (Multicast to MANE, Unicast to Endpoint) + + This scenario is a bit more complex, and designed to optimize the + network traffic in a core network, while still requiring only a + single pinhole in the endpoint's firewall. One of its key + applications is the mobile TV market. + + Consider a large private IP network, e.g., the core network of the + Third Generation Partnership Project (3GPP). Streaming servers + within this core network can be assumed to be professionally + maintained. It is assumed that these servers can have many ports + open to the network and that layered multicast is a real option. + Therefore, the streaming server multicasts SVC scalable layers, + instead of simulcasting different representations of the same content + at different bitrates. + + Also consider many endpoints of different classes. Some of these + endpoints may lack the processing power or the display size to + meaningfully decode all layers; others may have these capabilities. + Users of some endpoints may wish not to pay for high quality and are + happy with a base service, which may be cheaper or even free. Other + users are willing to pay for high quality. Finally, some connected + users may have a bandwidth problem in that they can't receive the + bandwidth they would want to receive -- be it through congestion, + connectivity, change of service quality, or for whatever other + reasons. However, all these users have in common that they don't + want to be exposed too much, and therefore the number of firewall + pinholes needs to be small. + + This situation can be handled best by introducing middleboxes close + to the edge of the core network, which receive the layered multicast + streams and compose the single SVC scalable bitstream according to + the needs of the endpoint connected. These middleboxes are called + MANEs throughout this specification. In practice, the authors + envision the MANE to be part of (or at least physically and + topologically close to) the base station of a mobile network, where + all the signaling and media traffic necessarily are multiplexed on + the same physical link. + + + + +Wenger, et al. Standards Track [Page 96] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + MANEs necessarily need to be fairly complex devices. They certainly + need to understand the signaling, so, for example, to associate the + payload type octet in the RTP header with the SVC payload type. + + A MANE may aggregate multiple RTP streams, possibly from multiple RTP + sessions, thus to reduce the number of firewall pinholes required at + the endpoints, or may optimize the outgoing RTP stream to the MTU + size of the outgoing path by utilizing the aggregation and + fragmentation mechanisms of this memo. This type of MANE is + conceptually easy to implement and can offer powerful features, + primarily because it necessarily can "see" the payload (including the + RTP payload headers), utilize the wealth of layering information + available therein, and manipulate it. + + A MANE can also perform stream thinning, in order to adhere to + congestion control principles as discussed in Section 9. While the + implementation of the forward (media) channel of such a MANE appears + to be comparatively simple, the need to rewrite RTCP RRs makes even + such a MANE a complex device. + + While the implementation complexity of either case of a MANE, as + discussed above, is fairly high, the computational demands are + comparatively low. + +12. Acknowledgements + + Miska Hannuksela contributed significantly to the designs of the + PACSI NAL unit and the NI-C mode for decoding order recovery. Roni + Even organized and coordinated the design team for the development of + this memo, and provided valuable comments. Jonathan Lennox + contributed to the NAL unit reordering algorithm for MST and provided + input on several parts of this memo. Peter Amon, Sam Ganesan, Mike + Nilsson, Colin Perkins, and Thomas Wiegand were members of the design + team and provided valuable contributions. Magnus Westerlund has also + made valuable comments. Charles Eckel and Stuart Taylor provided + valuable comments after the first WGLC for this document. Xiaohui + (Joanne) Wei helped improving Table 13 and the SDP examples. + + The work of Thomas Schierl has been supported by the European + Commission under contract number FP7-ICT-248036, project COAST. + +13. References + +13.1. Normative References + + [H.264] ITU-T Recommendation H.264, "Advanced video coding for + generic audiovisual services", March 2010. + + + + +Wenger, et al. Standards Track [Page 97] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + [RFC6184] Wang, Y.-K., Even, R., Kristensen, T., and R. Jesup, "RTP + Payload Format for H.264 Video", RFC 6184, May 2011. + + [ISO/IEC14496-10] + ISO/IEC International Standard 14496-10:2005. + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, March 1997. + + [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. + + [RFC4288] Freed, N. and J. Klensin, "Media Type Specifications and + Registration Procedures", BCP 13, RFC 4288, December 2005. + + [RFC4566] Handley, M., Jacobson, V., and C. Perkins, "SDP: Session + Description Protocol", RFC 4566, July 2006. + + [RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data + Encodings", RFC 4648, October 2006. + + [RFC5576] Lennox, J., Ott, J., and T. Schierl, "Source-Specific + Media Attributes in the Session Description Protocol + (SDP)", RFC 5576, June 2009. + + [RFC5583] Schierl, T. and S. Wenger, "Signaling Media Decoding + Dependency in the Session Description Protocol (SDP)", RFC + 5583, July 2009. + + [RFC6051] Perkins, C. and T. Schierl, "Rapid Synchronisation of RTP + Flows", RFC 6051, November 2010. + +13.2. Informative References + + [DVB-H] DVB - Digital Video Broadcasting (DVB); DVB-H + Implementation Guidelines, ETSI TR 102 377, 2005. + + [Eleft] Eleftheriadis, A., R. Civanlar, and O. Shapiro, + "Multipoint Videoconferencing with Scalable Video Coding", + Journal of Zhejiang University SCIENCE A, Vol. 7, Nr. 5, + April 2006, pp. 696-705. (Proceedings of the Packet Video + 2006 Workshop.) + + + + +Wenger, et al. Standards Track [Page 98] + +RFC 6190 RTP Payload Format for SVC May 2011 + + + [G.114] ITU-T Rec. G.114, "One-way transmission time", May 2003. + + [H.241] ITU-T Rec. H.241, "Extended video procedures and control + signals for H.300-series terminals", May 2006. + + [IGMP] Cain, B., Deering, S., Kouvelas, I., Fenner, B., and A. + Thyagarajan, "Internet Group Management Protocol, Version + 3", RFC 3376, October 2002. + + [JVT-N026] Ohm J.-R., Koenen, R., and Chiariglione, L. (ed.), "SVC + requirements specified by MPEG (ISO/IEC JTC1 SC29 WG11)", + JVT-N026, available from http://ftp3.itu.ch/av-arch/ + jvt-site/2005_01_HongKong/JVT-N026.doc, Hong Kong, China, + January 2005. + + [JVT-N027] Sullivan, G. and Wiegand, T. (ed.), "SVC requirements + specified by VCEG (ITU-T SG16 Q.6)", JVT-N027, available + from http://ftp3.itu.int/av-arch/ + jvt-site/2005_01_HongKong/JVT-N027.doc, Hong Kong, China, + January 2005. + + [McCanne] McCanne, S., Jacobson, V., and Vetterli, M., "Receiver- + driven layered multicast", in Proc. of ACM SIGCOMM'96, + pages 117-130, Stanford, CA, August 1996. + + [MBMS] 3GPP - Technical Specification Group Services and System + Aspects; Multimedia Broadcast/Multicast Service (MBMS); + Protocols and codecs (Release 6), December 2005. + + [MPEG2] ISO/IEC International Standard 13818-2:1993. + + [RFC2326] Schulzrinne, H., Rao, A., and R. Lanphier, "Real Time + Streaming Protocol (RTSP)", RFC 2326, April 1998. + + [RFC2974] Handley, M., Perkins, C., and E. Whelan, "Session + Announcement Protocol", RFC 2974, October 2000. + + [RFC5117] Westerlund, M. and S. Wenger, "RTP Topologies", RFC 5117, + January 2008. + + [RFC5775] Luby, M., Watson, M., and L. Vicisano, "Asynchronous + Layered Coding (ALC) Protocol Instantiation", RFC 5775, + April 2010. + + [Yan] Yan, J., Katrinis, K., May, M., and Plattner, R., "Media- + and TCP-friendly congestion control for scalable video + streams", in IEEE Trans. Multimedia, pages 196-206, April + 2006. + + + +Wenger, et al. Standards Track [Page 99] + +RFC 6190 RTP Payload Format for SVC May 2011 + + +Authors' Addresses + + Stephan Wenger + 2400 Skyfarm Dr. + Hillsborough, CA 94010 + USA + + Phone: +1-415-713-5473 + EMail: stewe@stewe.org + + + Ye-Kui Wang + Huawei Technologies + 400 Crossing Blvd, 2nd Floor + Bridgewater, NJ 08807 + USA + + Phone: +1-908-541-3518 + EMail: yekui.wang@huawei.com + + + Thomas Schierl + Fraunhofer HHI + Einsteinufer 37 + D-10587 Berlin + Germany + + Phone: +49-30-31002-227 + EMail: ts@thomas-schierl.de + + + Alex Eleftheriadis + Vidyo, Inc. + 433 Hackensack Ave. + Hackensack, NJ 07601 + USA + + Phone: +1-201-467-5135 + EMail: alex@vidyo.com + + + + + + + + + + + + +Wenger, et al. Standards Track [Page 100] + -- cgit v1.2.3