rfc5691









Network Working Group                                         F. de Bont
Request for Comments: 5691                           Philips Electronics
Updates: 3640                                                  S. Doehla
Category: Standards Track                                 Fraunhofer IIS
                                                              M. Schmidt
                                                      Dolby Laboratories
                                                        R. Sperschneider
                                                          Fraunhofer IIS
                                                            October 2009


               RTP Payload Format for Elementary Streams
                 with MPEG Surround Multi-Channel Audio

Abstract

   This memo describes extensions for the RTP payload format defined in
   RFC 3640 for the transport of MPEG Surround multi-channel audio.
   Additional Media Type parameters are defined to signal backwards-
   compatible transmission inside an MPEG-4 Audio elementary stream.  In
   addition, a layered transmission scheme that doesn't use the MPEG-4
   systems framework is presented to transport an MPEG Surround
   elementary stream via RTP in parallel with an RTP stream containing
   the downmixed audio data.

Status of This Memo

   This document specifies an Internet standards track protocol for the
   Internet community, and requests discussion and suggestions for
   improvements.  Please refer to the current edition of the "Internet
   Official Protocol Standards" (STD 1) for the standardization state
   and status of this protocol.  Distribution of this memo is unlimited.

Copyright Notice

   Copyright (c) 2009 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 BSD License.




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Table of Contents

   1. Introduction ....................................................2
   2. Conventions .....................................................3
   3. Definitions and Abbreviations ...................................3
      3.1. Definitions ................................................3
      3.2. Abbreviations ..............................................4
   4. Transport of MPEG Surround ......................................4
      4.1. Embedded Spatial Audio Data in AAC Payloads ................4
      4.2. MPEG Surround Elementary Stream ............................5
           4.2.1. Low Bitrate MPEG Surround ...........................7
           4.2.2. High Bitrate MPEG Surround ..........................8
   5. IANA Considerations .............................................8
      5.1. Media Type Registration ....................................9
      5.2. Registration of Mode Definitions with IANA .................9
      5.3. Usage of SDP ..............................................10
   6. Security Considerations ........................................10
   7. References .....................................................11
      7.1. Normative References ......................................11
      7.2. Informative References ....................................11

1.  Introduction

   MPEG Surround (Spatial Audio Coding, SAC) [23003-1] is an
   International Standard that was finalized by MPEG in January 2007.
   It is capable of re-creating N channels based on M < N transmitted
   channels and additional control data.  In the preferred modes of
   operating the Spatial Audio Coding system, the M channels can either
   be a single mono channel or a stereo channel pair.  The control data
   represents a significantly lower data rate than the data rate
   required for transmitting all N channels, making the coding very
   efficient while at the same time ensuring compatibility with M
   channel devices.

   The MPEG Surround standard incorporates a number of tools that enable
   features that allow for broad application of the standard.  A key
   feature is the ability to scale the spatial image quality gradually
   from very low spatial overhead towards transparency.  Another key
   feature is that the decoder input can be made compatible to existing
   matrixed surround technologies.

   As an example, for 5.1 multi-channel audio, the MPEG Surround encoder
   creates a stereo (or mono) downmix signal and spatial information
   describing the full 5.1 material in a highly efficient, parameterised
   format.  The spatial information is transmitted alongside the
   downmix.





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   By using MPEG Surround, existing services can easily be upgraded to
   provide surround sound in a backwards-compatible fashion.  While a
   stereo decoder in an existing legacy consumer device ignores the MPEG
   Surround data and plays back the stereo signal without any quality
   degradation, an MPEG-Surround-enabled decoder will deliver high
   quality, multi-channel audio.

   The MPEG Surround decoder can operate in modes that render the multi-
   channel signal to multi-channel or stereo output, or it can operate
   in a two-channel headphone mode to produce a virtual surround output
   signal.

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 [RFC2119].

3.  Definitions and Abbreviations

3.1.  Definitions

   This memo makes use of the definitions specified in [14496-1],
   [14496-3], [23003-1], and [RFC3640].  Frequently used terms are
   summed up for convenience:

   Access Unit:  An MPEG Access Unit is the smallest data entity to
      which timing information is attributed.  In the case of audio, an
      Access Unit is the smallest individually accessible portion of
      coded audio data within an elementary stream.

   AudioSpecificConfig():  Extends the class DecoderSpecificInfo(), as
      defined in [14496-1], when the objectType indication refers to a
      stream complying with [14496-3].  AudioSpecificConfig() is used as
      the configuration structure for MPEG-4 audio as specified in
      [14496-3].  It contains the field audioObjectType, which
      distinguishes between the different audio codecs defined in
      [14496-3], general audio information (e.g., the sampling frequency
      and number of channels), and further codec-dependent information
      structures.

   SpatialSpecificConfig():  Configuration structure for MPEG Surround
      audio coding, as specified in [23003-1].  An AudioSpecificConfig()
      with an audioObjectType of value 30 contains a
      SpatialSpecificConfig() structure.






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3.2.  Abbreviations

     AOT:    Audio Object Type
     AAC:    Advanced Audio Coding
     ASC:    AudioSpecificConfig() structure
     AU:     Access Unit
     HE AAC: High Efficiency AAC
     PLI:    Profile and Level Indication
     SSC:    SpatialSpecificConfig() structure

4.  Transport of MPEG Surround

   From a top-level perspective, MPEG Surround data can be subdivided
   into configuration data contained in the SpatialSpecificConfig()
   (SSC) and the SpatialFrame(), which contains the MPEG Surround
   payload.  The configuration data can be signaled in-band or out-of-
   band.  In the case of in-band signaling the SSC is conveyed in a
   SacDataFrame() jointly with a SpatialFrame().  In the case of out-of-
   band signaling, the SSC is transmitted to the decoder separately,
   e.g., by Session Description Protocol (SDP) [RFC4566] means.

   SpatialFrame()s may be transmitted either embedded into the downmix
   stream (Section 4.1) or as individual elementary streams besides the
   downmix audio stream (Section 4.2).

   The buffer definition for AAC decoders limits the size of an AU, as
   specified in [14496-3].  For high-bitrate applications that exceed
   this limit, all MPEG Surround data MUST be put in a separate stream,
   as defined in Section 4.2.

4.1.  Embedded Spatial Audio Data in AAC Payloads

   [14496-3] defines the extension_payload() as a mechanism for
   transport of extension data inside AAC payloads.  Typical extension
   data include Spectral Band Replication (SBR) data and MPEG Surround
   data, i.e., a SacDataFrame() in extension_payload()s of type
   EXT_SAC_DATA. extension_payload()s reside inside the downmix AAC
   elementary stream.  The resulting single elementary stream is
   transported as specified in [RFC3640].  As AAC decoders are required
   to skip unknown extension data, MPEG Surround data can be embedded in
   backwards-compatible fashion and be transported with the mechanism
   already described in [RFC3640].

   The SacDataFrame() includes a SpatialFrame() and an optional header
   that contains an SSC.  Any SSC in a SacDataFrame() MUST be identical
   to the SSC conveyed via SDP for that stream.





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   No new mode is introduced for SpatialFrame()s being embedded into AAC
   payloads.  Either the mode AAC-lbr or the mode AAC-hbr SHOULD be
   used.  The additional Media Type parameters, as defined in
   Section 5.1, SHOULD be present when SpatialFrame()s are embedded into
   AAC payloads.

   For example:

   m=audio 5000 RTP/AVP 96
   a=rtpmap:96 mpeg4-generic/48000/2
   a=fmtp:96 streamType=5; profile-level-id=44; mode=AAC-hbr; config=131
     056E598; sizeLength=13; indexLength=3; indexDeltaLength=3; constant
     Duration=2048; MPS-profile-level-id=55; MPS-config=F1B4CF920442029B
     501185B6DA00;

   In this example, the stream specifies the HE AAC Profile at Level 2
   [Profile and Level Indication (PLI) 44] and the config string
   contains the hexadecimal representation of the HE AAC ASC
   [audioObjectType=2 (AAC LC); extensionAudioObjectType=5 (SBR);
   samplingFrequencyIndex=0x6 (24kHz);
   extensionSamplingFrequencyIndex=0x3 (48kHz); channelConfiguration=2
   (2.0 channels)] of the downmix AAC elementary stream that is using
   explicit backwards-compatible signaling.

   Furthermore, the stream specifies the MPEG Surround Baseline Profile
   at Level 3 (PLI55) and the MPS-config string contains the hexadecimal
   representation of the MPEG Surround ASC [audioObjectType=30 (MPEG
   Surround); samplingFrequencyIndex=0x3 (48kHz); channelConfiguration=6
   (5.1 channels); sacPayloadEmbedding=1; SSC=(48 kHz; 32 slots; 525
   tree; ResCoding=1; ResBands=[0,13,13,13])].

   Note that the a=fmtp line of the example above has been wrapped to
   fit the page; it would comprise a single line in the SDP file.

4.2.  MPEG Surround Elementary Stream

   MPEG Surround SpatialFrame()s can be present in an individual
   elementary stream.  This stream complements the stream containing the
   downmix audio data, which may be coded by an arbitrary coding scheme.
   MPEG Surround elementary streams are packetized as specified in
   [RFC3640].  The mode signaled and used for an MPEG Surround
   elementary stream MUST be either MPS-hbr or MPS-lbr.  The MPS-hbr
   mode SHALL be used when the frame size may exceed 63 bytes, e.g.,
   when high-bitrate residual coding is in use.

   The dependency relationships between the MPEG Surround elementary
   stream and the downmix stream are signaled as specified in [RFC5583].




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   The media clocks of the MPEG Surround elementary stream and the
   downmix stream SHALL operate in the same clock domain, i.e., the
   clocks are derived from a common clock and MUST NOT drift.  RTCP
   sender reports MUST indicate that the stream timestamps are not
   drifting, i.e., that a single sender report for each stream is
   sufficient to establish unambiguous timing.  The sampling rate of the
   MPEG Surround signal and the decoded downmix signal MUST be
   identical.

   If HE AAC is used as the coding scheme for the downmix, the RTP
   clock-rate of the downmix MAY be the sampling rate of the AAC core,
   i.e., the clock-rate of the MPEG Surround elementary stream is an
   integer multiple of the clock-rate of the downmix stream.

   Note that separate RTP streams have different random RTP timestamp
   offsets, and therefore RTCP MUST be used to synchronize the coded
   downmix audio data and the MPEG Surround elementary stream.

   For example:

   a=group:DDP L1 L2

   m=audio 5000 RTP/AVP 96
   a=rtpmap:96 mpeg4-generic/48000/2
   a=fmtp:96 streamType=5; profile-level-id=44; mode=AAC-hbr; config=2B1
     18800; sizeLength=13; indexLength=3; indexDeltaLength=3; constantDu
     ration=2048
   a=mid:L1

   m=audio 5002 RTP/AVP 97
   a=rtpmap:97 mpeg4-generic/48000/6
   a=fmtp:97 streamType=5; profile-level-id=55; mode=MPS-hbr; config=F1B
     0CF920460029B601189E79E70; sizeLength=13; indexLength=3;  indexDelt
     aLength=3; constantDuration=2048
   a=mid:L2
   a=depend:97 lay L1:96

   In this example, the first stream specifies the HE AAC Profile at
   Level 2 (PLI44) and the config string contains the hexadecimal
   representation of the HE AAC ASC [audioObjectType=2 (AAC LC);
   extensionAudioObjectType=5 (SBR); samplingFrequencyIndex=0x6 (24kHz);
   extensionSamplingFrequencyIndex=0x3 (48kHz); channelConfiguration=2
   (2.0 channels)].








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   The second stream specifies Baseline MPEG Surround Profile at Level 3
   (PLI55) and the config string contains the hexadecimal representation
   of the ASC [AOT=30(MPEG Surround); 48 kHz; 5.1-ch;
   sacPayloadEmbedding=0; SSC=(48 kHz; 32 slots; 525 tree; ResCoding=1;
   ResBands=[7,7,7,7])].

   Note that the a=fmtp lines of the example above have been wrapped to
   fit the page; they would each comprise a single line in the SDP file.

4.2.1.  Low Bitrate MPEG Surround

   This mode is signaled by mode=MPS-lbr.  This mode supports the
   transport of one or more complete Access Units, each consisting of a
   single MPEG Surround SpatialFrame().  The AUs can be variably sized
   and interleaved.  The maximum size of a SpatialFrame() is 63 bytes.
   Fragmentation MUST NOT be used in this mode.  Receivers MUST support
   de-interleaving.

   The payload configuration is the same as in the AAC-lbr mode.  It
   consists of the AU Header Section, followed by concatenated AUs.
   Note that Access Units are byte-aligned.  The Auxiliary Section MUST
   be empty in the MPS-lbr mode.  The 1-octet AU-header MUST provide:

   1.  the size of each AAC frame, encoded as 6 bits.

   2.  2 bits of index information for computing the sequence (and hence
       timing) of each SpatialFrame().

   The concatenated AU Header Section MUST be preceded by the 16-bit AU-
   headers-length field.

   In addition to the required Media format parameters, the following
   parameters MUST be present with fixed values: sizeLength (fixed value
   6), indexLength (fixed value 2), and indexDeltaLength (fixed value
   2).  The parameter maxDisplacement MUST be present when interleaving.
   SpatialFrame()s always have a fixed duration per AU; the fixed
   duration MUST be signaled by the Media format parameter
   constantDuration.

   The value of the "config" parameter is the hexadecimal representation
   of the ASC, as defined in [14496-3], with an AOT of 30 and the
   sacPayloadEmbedding flag set to 0.

   The "profile-level-id" parameter SHALL contain a valid PLI for MPEG
   Surround, as specified in [14496-3].






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4.2.2.  High Bitrate MPEG Surround

   This mode is signaled by mode=MPS-hbr.  This mode supports the
   transportation of either one fragment of an Access Unit or one
   complete AU or several complete AUs.  Each AU consists of a single
   MPEG Surround SpatialFrame().  The AUs can be variably sized and
   interleaved.  The maximum size of a SpatialFrame() is 8191 bytes.
   Receivers MUST support de-interleaving.

   The payload configuration is the same as in the AAC-hbr mode.  It
   consists of the AU Header Section, followed by either one
   SpatialFrame(), a fragment of a SpatialFrame(), or several
   concatenated SpatialFrame()s.  Note that Access Units are byte-
   aligned.  The Auxiliary Section MUST be empty in the MPS-hbr mode.
   The 2-octet AU-header MUST provide:

   1.  the size of each AAC frame, encoded as 13 bits.

   2.  3 bits of index information for computing the sequence (and hence
       timing) of each SpatialFrame(), i.e., the AU-Index or AU-Index-
       delta field.

   Each AU-Index field MUST be coded with the value 0.  The concatenated
   AU Header Section MUST be preceded by the 16-bit AU-headers-length
   field.

   In addition to the required Media format parameters, the following
   parameters MUST be present with fixed values: sizeLength (fixed value
   13), indexLength (fixed value 3), and indexDeltaLength (fixed value
   3).  The parameter maxDisplacement MUST be present when interleaving.
   SpatialFrame()s always have a fixed duration per AU; the fixed
   duration MUST be signaled by the Media format parameter
   constantDuration.

   The value of the "config" parameter is the hexadecimal representation
   of the ASC, as defined in [14496-3], with an AOT of 30 and the
   sacPayloadEmbedding flag set to 0.

   The "profile-level-id" parameter SHALL contain a valid PLI for MPEG
   Surround, as specified in [14496-3].

5.  IANA Considerations

   This memo defines additional optional format parameters to the Media
   type "audio" and its subtype "mpeg4-generic".  These parameters SHALL
   only be used in combination with the AAC-lbr or AAC-hbr modes (cf.
   Section 3.3 of [RFC3640]) of "mpeg4-generic".




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5.1.  Media Type Registration

   This memo defines the following additional optional parameters, which
   SHALL be used if MPEG Surround data is present inside the payload of
   an AAC elementary stream.

   MPS-profile-level-id:  A decimal representation of the MPEG Surround
      Profile and Level indication as defined in [14496-3].  This
      parameter MUST be used in the capability exchange or session
      set-up procedure to indicate the MPEG Surround Profile and Level
      that the decoder must be capable of in order to decode the stream.

   MPS-config:  A hexadecimal representation of an octet string that
      expresses the AudioSpecificConfig (ASC), as defined in [14496-3],
      for MPEG Surround.  The ASC is mapped onto the hexadecimal octet
      string in a most significant bit (MSB)-first basis.  The AOT in
      this ASC SHALL have the value 30.  The SSC inside the ASC MUST
      have the sacPayloadEmbedding flag set to 1.

5.2.  Registration of Mode Definitions with IANA

   This section of this memo requests the registration of the "MPS-hbr"
   value and the "MPS-lbr" value for the "mode" parameter of the "mpeg4-
   generic" media subtype within the media type "audio".  The "mpeg4-
   generic" media subtype is defined in [RFC3640], and [RFC3640] defines
   a repository for the "mode" parameter.  This memo registers the modes
   "MPS-hbr" and "MPS-lbr" to support MPEG Surround elementary streams.

   Media type name:

      audio

   Subtype name:

      mpeg4-generic

   Required parameters:

      The "mode" parameter is required by [RFC3640].  This memo
      specifies the additional modes "MPS-hbr" and "MPS-lbr", in
      accordance with [RFC3640].

   Optional parameters:

      For the modes "AAC-hbr" and "AAC-lbr", this memo specifies the
      additional optional parameters "MPS-profile-level-id" and "MPS-
      config".  See Section 4.1 for usage details.




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      Optional parameters for the modes "MPS-hbr" and "MPS-lbr" may be
      used as specified in [RFC3640].  The optional parameters "MPS-
      profile-level-id" and "MPS-config" SHALL NOT be used for the modes
      "MPS-hbr" and "MPS-lbr".

5.3.  Usage of SDP

   It is assumed that the Media format parameters are conveyed via an
   SDP message, as specified in Section 4.4 of [RFC3640].

6.  Security Considerations

   RTP packets using the payload format defined in this specification
   are subject to the security considerations discussed in the RTP
   specification [RFC3550], in the RTP payload format specification for
   MPEG-4 elementary streams [RFC3640] (which is extended with this
   memo), and in any applicable RTP profile.  The main security
   considerations for the RTP packet carrying the RTP payload format
   defined within this memo are confidentiality, integrity, and source
   authenticity.  Confidentiality is achieved by encryption of the RTP
   payload.  Integrity of the RTP packets is achieved through a suitable
   cryptographic integrity-protection mechanism.  Such a cryptographic
   system may also allow the authentication of the source of the
   payload.  A suitable security mechanism for this RTP payload format
   should provide confidentiality, integrity protection, and source
   authentication capable of at least determining if an RTP packet is
   from a member of the RTP session.

   The AAC audio codec includes an extension mechanism to transmit extra
   data within a stream that is gracefully skipped by decoders that do
   not support this extra data.  This covert channel may be used to
   transmit unauthorized data in an otherwise valid stream.

   Note that the appropriate mechanism to provide security to RTP and
   payloads following this memo may vary.  It is dependent on the
   application, the transport, and the signaling protocol employed.
   Therefore, a single mechanism is not sufficient; although, if
   suitable, usage of the Secure Real-time Transport Protocol (SRTP)
   [RFC3711] is recommended.  Other mechanisms that may be used are
   IPsec [RFC4301] and Transport Layer Security (TLS) [RFC5246] (RTP
   over TCP); other alternatives may exist.










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7.  References

7.1.  Normative References

   [14496-1]  MPEG, "ISO/IEC International Standard 14496-1 - Coding of
              audio-visual objects, Part 1 Systems", 2004.

   [14496-3]  MPEG, "ISO/IEC International Standard 14496-3 - Coding of
              audio-visual objects, Part 3 Audio", 2009.

   [23003-1]  MPEG, "ISO/IEC International Standard 23003-1 - MPEG
              Surround (MPEG D)", 2007.

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119, March 1997.

   [RFC3550]  Schulzrinne, H., Casner, S., Frederick, R., and V.
              Jacobson, "RTP: A Transport Protocol for Real-Time
              Applications", STD 64, RFC 3550, July 2003.

   [RFC3640]  van der Meer, J., Mackie, D., Swaminathan, V., Singer, D.,
              and P. Gentric, "RTP Payload Format for Transport of
              MPEG-4 Elementary Streams", RFC 3640, November 2003.

   [RFC4566]  Handley, M., Jacobson, V., and C. Perkins, "SDP: Session
              Description Protocol", RFC 4566, July 2006.

   [RFC5583]  Schierl, T. and S. Wenger, "Signaling Media Decoding
              Dependency in the Session Description Protocol (SDP)",
              RFC 5583, July 2009.

7.2.  Informative References

   [RFC3711]  Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K.
              Norrman, "The Secure Real-time Transport Protocol (SRTP)",
              RFC 3711, March 2004.

   [RFC4301]  Kent, S. and K. Seo, "Security Architecture for the
              Internet Protocol", RFC 4301, December 2005.

   [RFC5246]  Dierks, T. and E. Rescorla, "The Transport Layer Security
              (TLS) Protocol Version 1.2", RFC 5246, August 2008.









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Authors' Addresses

   Frans de Bont
   Philips Electronics
   High Tech Campus 5
   5656 AE Eindhoven,
   NL

   Phone: ++31 40 2740234
   EMail: frans.de.bont@philips.com


   Stefan Doehla
   Fraunhofer IIS
   Am Wolfmantel 33
   91058 Erlangen,
   DE

   Phone: +49 9131 776 6042
   EMail: stefan.doehla@iis.fraunhofer.de


   Malte Schmidt
   Dolby Laboratories
   Deutschherrnstr. 15-19
   90537 Nuernberg,
   DE

   Phone: +49 911 928 91 42
   EMail: malte.schmidt@dolby.com


   Ralph Sperschneider
   Fraunhofer IIS
   Am Wolfmantel 33
   91058 Erlangen,
   DE

   Phone: +49 9131 776 6167
   EMail: ralph.sperschneider@iis.fraunhofer.de











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