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Network Working Group                                          M. CivanlarRequest for Comments: 2343                                         G. CashCategory: Experimental                                          B. Haskell                                                        AT&T Labs-Research                                                                  May 1998RTP Payload Format for Bundled MPEGStatus of this Memo   This memo defines an Experimental Protocol for the Internet   community.  This memo does not specify an Internet standard of any   kind.  Discussion and suggestions for improvement are requested.   Distribution of this memo is unlimited.Copyright Notice   Copyright (C) The Internet Society (1998).  All Rights Reserved.Abstract   This document describes a payload type for bundled, MPEG-2 encoded   video and audio data that may be used with RTP, version 2. Bundling   has some advantages for this payload type particularly when it is   used for video-on-demand applications. This payload type may be used   when its advantages are important enough to sacrifice the modularity   of having separate audio and video streams.1. Introduction   This document describes a bundled packetization scheme for MPEG-2   encoded audio and video streams using the Real-time Transport   Protocol (RTP), version 2 [1].   The MPEG-2 International standard consists of three layers: audio,   video and systems [2]. The audio and the video layers define the   syntax and semantics of the corresponding "elementary streams." The   systems layer supports synchronization and interleaving of multiple   compressed streams, buffer initialization and management, and time   identification.RFC 2250 [3] describes packetization techniques to   transport individual audio and video elementary streams as well as   the transport stream, which is defined at the system layer, using the   RTP.Civanlar, et. al.             Experimental                      [Page 1]

RFC 2343          RTP Payload Format for Bundled MPEG           May 1998   The bundled packetization scheme is needed because it has several   advantages over other schemes for some important applications   including video-on-demand (VOD) where, audio and video are always   used together.  Its advantages over independent packetization of   audio and video are:     1. Uses a single port per "program" (i.e. bundled A/V).  This may     increase the number of streams that can be served e.g., from a VOD     server. Also, it eliminates the performance hit when two ports are     used for the separate audio and video streams on the client side.     2. Provides implicit synchronization of audio and video.  This is     particularly convenient when the A/V data is stored in an     interleaved format at the server.     3. Reduces the header overhead. Since using large packets increases     the effects of losses and delay, audio only packets need to be     smaller increasing the overhead. An A/V bundled format can provide     about 1% overall overhead reduction. Considering the high bitrates     used for MPEG-2 encoded material, e.g. 4 Mbps, the number of bits     saved, e.g. 40 Kbps, may provide noticeable audio or video quality     improvement.     4. May reduce overall receiver buffer size. Audio and video streams     may experience different delays when transmitted separately. The     receiver buffers need to be designed for the longest of these     delays. For example, let's assume that using two buffers, each with     a size B, is sufficient with probability P when each stream is     transmitted individually. The probability that the same buffer size     will be sufficient when both streams need to be received is P times     the conditional probability of B being sufficient for the second     stream given that it was sufficient for the first one. This     conditional probability is, generally, less than one requiring use     of a larger buffer size to achieve the same probability level.     5. May help with the control of the overall bandwidth used by an     A/V program.   And, the advantages over packetization of the transport layer streams   are:     1. Reduced overhead. It does not contain systems layer information     which is redundant for the RTP (essentially they address similar     issues).Civanlar, et. al.             Experimental                      [Page 2]

RFC 2343          RTP Payload Format for Bundled MPEG           May 1998     2. Easier error recovery. Because of the structured packetization     consistent with the application layer framing (ALF) principle, loss     concealment and error recovery can be made simpler and more     effective.2. Encapsulation of Bundled MPEG Video and Audio   Video encapsulation follows rules similar to the ones described in   [3] for encapsulation of MPEG elementary streams. Specifically,     1. The MPEG Video_Sequence_Header, when present, will always be at     the beginning of an RTP payload.     2. An MPEG GOP_header, when present, will always be at the     beginning of the RTP payload, or will follow a     Video_Sequence_Header.     3. An MPEG Picture_Header, when present, will always be at the     beginning of a RTP payload, or will follow a GOP_header.   In addition to these, it is required that:     4. Each packet must contain an integral number of video slices.   It is the application's responsibility to adjust the slice sizes and   the number of slices put in each RTP packet so that lower level   fragmentation does not occur. This approach simplifies the receivers   while somewhat increasing the complexity of the transmitter's   packetizer. Considering that a slice can be as small as a single   macroblock, it is possible to prevent fragmentation for most of the   cases.  If a packet size exceeds the path maximum transmission unit   (path-MTU) [4], this payload type depends on the lower protocol   layers for fragmentation although, this may cause problems with   packet classification for integrated services (e.g. with RSVP).   The video data is followed by a sufficient number of integral audio   frames to cover the duration of the video segment included in a   packet.  For example, if the first packet contains three 1/900   seconds long slices of video, and Layer I audio coding is used at a   44.1kHz sampling rate, only one audio frame covering 384/44100   seconds of audio need be included in this packet. Since the length of   this audio frame (8.71 msec.) is longer than that of the video   segment contained in this packet (3.33 msec), the next few packets   may not contain any audio frames until the packet in which the   covered video time extends outside the length of the previously   transmitted audio frames. Alternatively, it is possible, in this   proposal, to repeat the latest audio frame in "no-audio" packets forCivanlar, et. al.             Experimental                      [Page 3]

RFC 2343          RTP Payload Format for Bundled MPEG           May 1998   packet loss resilience. Again, it is the application's responsibility   to adjust the bundled packet size according to the minimum MTU size   to prevent fragmentation.2.1. RTP Fixed Header for BMPEG Encapsulation   The following RTP header fields are used:     Payload Type: A distinct payload type number, which may be dynamic,     should be assigned to BMPEG.     M Bit: Set for packets containing end of a picture.     timestamp: 32-bit 90 kHz timestamp representing sampling time of     the MPEG picture. May not be monotonically increasing if B pictures     are present. Same for all packets belonging to the same picture.     For packets that contain only a sequence, extension and/or GOP     header, the timestamp is that of the subsequent picture.2.2. BMPEG Specific Header:    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   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+   | P |N|MBZ|    Audio Length   | |         Audio Offset          |   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+                                 MBZ    P: Picture type (2 bits). I (0), P (1), B (2).    N: Header data changed (1 bit). Set if any part of the video    sequence, extension, GOP and picture header data is different than    that of the previously sent headers. It gets reset when all the    header data gets repeated (see Appendix 1).    MBZ: Must be zero. Reserved for future use.    Audio Length: (10 bits) Length of the audio data in this packet in    bytes. Start of the audio data is found by subtracting "Audio    Length" from the total length of the received packet.    Audio Offset: (16 bits) The offset between the start of the audio    frame and the RTP timestamp for this packet in number of audio    samples (for multi-channel sources, a set of samples covering all    channels is counted as one sample for this purpose.)Civanlar, et. al.             Experimental                      [Page 4]

RFC 2343          RTP Payload Format for Bundled MPEG           May 1998    Audio offset is a signed integer in two's complement form. It allows    a ~ +/- 750 msec offset at 44.1 KHz audio sampling rate. For a very    low video frame rate (e.g., a frame per second), this offset may not    be sufficient and this payload format may not be usable.    If  B frames are present, audio frames are not re-ordered along with    video.  Instead, they are packetized along with video frames in    their transmission order  (e.g., an audio segment packetized with a    video segment corresponding to a P picture may belong to a B    picture, which will be transmitted later and should be rendered at    the same time with this audio segment.) Even though the video    segments are reordered, the audio offset for a particular audio    segment is still relative to the RTP timestamp in the packet    containing that audio segment.    Since a special picture counter, such as  the "temporal reference    (TR)" field of [3], is not included in this payload format, lost GOP    headers may not be detected.  The only effect of this may be    incorrect decoding of the B pictures immediately following the lost    GOP header for some edited video material.3. Security Considerations   RTP packets using the payload format defined in this specification   are subject to the security considerations discussed in the RTP   specification [1]. This implies that confidentiality of the media   streams is achieved by encryption. Because the data compression used   with this payload format is applied end-to-end, encryption may be   performed after compression so there is no conflict between the two   operations.   This payload type does not exhibit any significant non-uniformity in   the receiver side computational complexity for packet processing  to   cause a potential denial-of-service threat.   A security review of this payload format found no additional   considerations beyond those in the RTP specification.Civanlar, et. al.             Experimental                      [Page 5]

RFC 2343          RTP Payload Format for Bundled MPEG           May 1998Appendix 1. Error Recovery   Packet losses can be detected from a combination of the sequence   number and the timestamp fields of the RTP fixed header. The extent   of the loss can be determined from the timestamp, the slice number   and the horizontal location of the first slice in the packet. The   slice number and the horizontal location can be determined from the   slice header and the first macroblock address increment, which are   located at fixed bit positions.   If lost data consists of slices all from the same picture, new data   following the loss may simply be given to the video decoder which   will normally repeat missing pixels from a previous picture. The next   audio frame must be played at the appropriate time determined by the   timestamp and the audio offset contained in the received packet.   Appropriate audio frames (e.g., representing background noise) may   need to be fed to the audio decoder in place of the lost audio frames   to keep the lip-synch and/or to conceal the effects of the losses.   If the received new data after a loss is from the next picture (i.e.   no complete picture loss) and the N bit is not set, previously   received headers for the particular picture type (determined from the   P bits) can be given to the video decoder followed by the new data.   If N is set, data deletion until a new picture start code is   advisable unless headers are made available to the receiver through   some other channel.   If data for more than one picture is lost and headers are not   available, unless N is zero and at least one packet has been received   for every intervening picture of the same type and that the N bit was   0 for each of those pictures, resynchronization to a new video   sequence header is advisable.   In all cases of heavy packet losses, if the correct headers for the   missing Pictures are available, they can be given to the video   decoder and the received data can be used irrespective of the N bit   value or the number of lost pictures.Appendix 2. Resynchronization   As described in [3], use of frequent video sequence headers makes it   possible to join in a program at arbitrary times. Also, it reduces   the resynchronization time after severe losses.Civanlar, et. al.             Experimental                      [Page 6]

RFC 2343          RTP Payload Format for Bundled MPEG           May 1998References   [1] Schulzrinne, H., Casner, S., Frederick, R., and V. Jacobson,       "RTP: A Transport Protocol for Real-Time Applications",RFC 1889,       January 1996.   [2] ISO/IEC International Standard 13818; "Generic coding of moving       pictures and associated audio information," November 1994.   [3] Hoffman, D., Fernando, G., Goyal, V., and M. Civanlar, "RTP       Payload Format for MPEG1/MPEG2 Video",RFC 2250, January 1998.   [4] Mogul, J., and S. Deering, "Path MTU Discovery",RFC 1191,       November 1990.Authors'  Addresses   M. Reha Civanlar   AT&T Labs-Research   100 Schultz Drive   Red Bank, NJ 07701   USA   EMail: civanlar@research.att.com   Glenn L. Cash   AT&T Labs-Research   100 Schultz Drive   Red Bank, NJ 07701   USA   EMail: glenn@research.att.com   Barry G. Haskell   AT&T Labs-Research   100 Schultz Drive   Red Bank, NJ 07701   USA   EMail: bgh@research.att.comCivanlar, et. al.             Experimental                      [Page 7]

RFC 2343          RTP Payload Format for Bundled MPEG           May 1998Full Copyright Statement   Copyright (C) The Internet Society (1998).  All Rights Reserved.   This document and translations of it may be copied and furnished to   others, and derivative works that comment on or otherwise explain it   or assist in its implementation may be prepared, copied, published   and distributed, in whole or in part, without restriction of any   kind, provided that the above copyright notice and this paragraph are   included on all such copies and derivative works.  However, this   document itself may not be modified in any way, such as by removing   the copyright notice or references to the Internet Society or other   Internet organizations, except as needed for the purpose of   developing Internet standards in which case the procedures for   copyrights defined in the Internet Standards process must be   followed, or as required to translate it into languages other than   English.   The limited permissions granted above are perpetual and will not be   revoked by the Internet Society or its successors or assigns.   This document and the information contained herein is provided on an   "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING   TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING   BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION   HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF   MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.Civanlar, et. al.             Experimental                      [Page 8]