RFC3189 - RTP Payload Format for DV (IEC 61834) Video

Network Working Group K. Kobayashi

Request for Comments: 3189 Communication Research Laboratory

Category: Standards Track A. Ogawa

Keio University

S. Casner

Packet Design

C. Bormann

Universitaet Bremen TZI

January 2002

RTP Payload Format for DV (IEC 61834) Video

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.

Abstract

This document specifies the packetization scheme for encapsulating

the compressed digital video data streams commonly known as "DV" into

a payload format for the Real-Time Transport Protocol (RTP).

1. IntrodUCtion

This document specifies payload formats for encapsulating both

consumer- and professional-use DV format data streams into the Real-

time Transport Protocol (RTP), version 2 [6]. DV compression audio

and video formats were designed for helical-scan magnetic tape media.

The DV standards for consumer-market devices, the IEC 61883 and 61834

series, cover many ASPects of consumer-use digital video, including

mechanical specifications of a cassette, magnetic recording format,

error correction on the magnetic tape, DCT video encoding format, and

audio encoding format [1]. The digital interface part of IEC 61883

defines an interface on an IEEE 1394 network [2,3]. This

specification set supports several video formats: SD-VCR (Standard

Definition), HD-VCR (High Definition), SDL-VCR (Standard Definition -

Long), PALPlus, DVB (Digital Video Broadcast) and ATV (Advanced

Television). North American formats are indicated with a number of

lines and "/60", while European formats use "/50". DV standards

extended for professional use were published by SMPTE as 306M and

314M, for different sampling systems, higher color resolution, and

faster bit rates [4,5].

There are two kinds of DV, one for consumer use and the other for

professional. The original "DV" specification designed for

consumer-use digital VCRs is approved as the IEC 61834 standard set.

The specifications for professional DV are published as SMPTE 306M

and 314M. Both encoding formats are based on consumer DV and used in

SMPTE D-7 and D-9 video systems. The RTP payload format specified in

this document supports IEC 61834 consumer DV and professional SMPTE

306M and 314M (DV-Based) formats.

IEC 61834 also includes magnetic tape recording for digital TV

broadcasting systems (such as DVB and ATV) that use MPEG2 encoding.

The payload format for encapsulating MPEG2 into RTP has already been

defined in RFC2250 [7] and others.

Consequently, the payload specified in this document will support six

video formats of the IEC standard: SD-VCR (525/60, 625/50), HD-VCR

(1125/60, 1250/50) and SDL-VCR (525/60, 625/50), and six of the SMPTE

standards: 306M (525/60, 625/50), 314M 25Mbps (525/60, 625/50) and

314M 50Mbps (525/60, 625/50). In the future it can be extended into

other high-definition formats.

Throughout this specification, we make extensive use of the

terminology of IEC and SMPTE standards. The reader should consult

the original references for definitions of these terms.

1.1 Terminology

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 [8].

2. DV format encoding

The DV format only uses the DCT compression technique within each

frame, contrasted with the interframe compression of the MPEG video

standards [9,10]. All video data, including audio and other system

data, are managed within the picture frame unit of video.

The DV video encoding is composed of a three-level hierarchical

structure. A picture frame is divided into rectangle- or clipped-

rectangle-shaped DCT super blocks. DCT super blocks are divided into

27 rectangle- or square-shaped DCT macro blocks.

Audio data is encoded with PCM format. The sampling frequency is 32

kHz, 44.1 kHz or 48 kHz and the quantization is 12-bit non-linear,

16-bit linear or 20-bit linear. The number of channels may be up to

8. Only certain combinations of these parameters are allowed

depending upon the video format; the restrictions are specified in

each document.

A frame of data in the DV format stream is divided into several "DIF

sequences". A DIF sequence is composed of an integral number of 80-

byte DIF blocks. A DIF block is the primitive unit for all treatment

of DV streams. Each DIF block contains a 3-byte ID header that

specifies the type of the DIF block and its position in the DIF

sequence. Five types of DIF blocks are defined: DIF sequence header,

Subcode, Video Auxiliary information (VAUX), Audio, and Video. Audio

DIF blocks are composed of 5 bytes of Audio Auxiliary data (AAUX) and

72 bytes of audio data.

Each RTP packet starts with the RTP header as defined in RFC1889

[6]. No additional payload-format-specific header is required for

this payload format.

2.1 RTP header usage

The RTP header fields that have a meaning specific to the DV format

are described as follows:

Payload type (PT): The payload type is dynamically assigned by means

outside the scope of this document. If multiple DV encoding formats

are to be used within one RTP session, then multiple dynamic payload

types MUST be assigned, one for each DV encoding format. The sender

MUST change to the corresponding payload type whenever the encoding

format is changed.

Timestamp: 32-bit 90 kHz timestamp representing the time at which the

first data in the frame was sampled. All RTP packets within the same

video frame MUST have the same timestamp. The timestamp SHOULD

increment by a multiple of the nominal interval for one frame time,

as given in the following table:

Mode Frame rate (Hz) Increase of one frame

in 90kHz timestamp

525-60 29.97 3003

625-50 25 3600

1125-60 30 3000

1250-50 25 3600

When the DV stream is oBTained from an IEEE 1394 interface, the

progress of video frame times MAY be monitored using the SYT

timestamp carried in the CIP header as specified in IEC 61883 [2].

Marker bit (M): The marker bit of the RTP fixed header is set to one

on the last packet of a video frame, and otherwise, must be zero.

The M bit allows the receiver to know that it has received the last

packet of a frame so it can display the image without waiting for the

first packet of the next frame to arrive to detect the frame change.

However, detection of a frame change MUST NOT rely on the marker bit

since the last packet of the frame might be lost. Detection of a

frame change MUST be based on a difference in the RTP timestamp.

2.2 DV data encapsulation into RTP payload

Integral DIF blocks are placed into the RTP payload beginning

immediately after the RTP header. Any number of DIF blocks may be

packed into one RTP packet, except that all DIF blocks in one RTP

packet must be from the same video frame. DIF blocks from the next

video frame MUST NOT be packed into the same RTP packet even if more

payload space remains. This requirement stems from the fact that the

transition from one video frame to the next is indicated by a change

in the RTP timestamp. It also reduces the processing complexity on

the receiver. Since the RTP payload contains an integral number of

DIF blocks, the length of the RTP payload will be a multiple of 80

bytes.

Audio and video data may be transmitted as one bundled RTP stream or

in separate RTP streams (unbundled). The choice MUST be indicated as

part of the assignment of the dynamic payload type and MUST remain

unchanged for the duration of the RTP session to avoid complicated

procedures of sequence number synchronization. The RTP sender MAY

omit DIF-sequence header and subcode DIF blocks from a stream since

the information is either known out-of-band or may not be required

for RTP transport. When sending DIF-sequence header and subcode DIF

blocks, both types of blocks MUST be included in the video stream.

DV streams include "source" and "source control" packs that carry

information indispensable for proper decoding, such as aspect ratio,

picture position, quantization of audio sampling, number of audio

channels, audio channel assignment, and language of the audio.

However, describing all of these attributes with a signaling protocol

would require large descriptions to enumerate all the combinations.

Therefore, no Session Description Protocol (SDP) [13] parameters for

these attributes are defined in this document. Instead, the RTP

sender MUST transmit at least those VAUX DIF blocks and/or audio DIF

blocks with AAUX information bytes that include "source" and "source

control" packs containing the indispensable information for decoding.

In the case of one bundled stream, DIF blocks for both audio and

video are packed into RTP packets in the same order as they were

encoded.

In the case of an unbundled stream, only the header, subcode, video

and VAUX DIF blocks are sent within the video stream. Audio is sent

in a different stream if desired, using a different RTP payload type.

It is also possible to send audio duplicated in a separate stream, in

addition to bundling it in with the video stream.

When using unbundled mode, it is RECOMMENDED that the audio stream

data be extracted from the DIF blocks and repackaged into the

corresponding RTP payload format for the audio encoding (DAT12, L16,

L20) [11,12] in order to maximize interoperability with non-DV-

capable receivers while maintaining the original source quality.

In the case of unbundled transmission where both audio and video are

sent in the DV format, the same timestamp SHOULD be used for both

audio and video data within the same frame to simplify the lip

synchronization effort on the receiver. Lip synchronization may also

be achieved using reference timestamps passed in RTCP as described in

RFC1889 [6].

The sender MAY reduce the video frame rate by discarding the video

data and VAUX DIF blocks for some of the video frames. The RTP

timestamp must still be incremented to account for the discarded

frames. The sender MAY alternatively reduce bandwidth by discarding

video data DIF blocks for portions of the image which are unchanged

from the previous image. To enable this bandwidth reduction,

receivers SHOULD implement an error concealment strategy to

accommodate lost or missing DIF blocks, e.g., repeating the

corresponding DIF block from the previous image.

3. SDP Signaling for RTP/DV

When using SDP (Session Description Protocol) [13] for negotiation of

the RTP payload information, the format described in this document

SHOULD be used. SDP descriptions will be slightly different for a

bundled stream and an unbundled stream.

When a DV stream is sent to port 31394 using RTP payload type

identifier 111, the m=?? line will be like:

m=video 31394 RTP/AVP 111

The a=rtpmap attribute will be like:

a=rtpmap:111 DV/90000

"DV" is the encoding name for the DV video payload format defined in

this document. The "90000" specifies the RTP timestamp clock rate,

which for the payload format defined in this document is a 90kHz

clock.

In SDP, format-specific parameters are defined as a=fmtp, as below:

a=fmtp:<format> <format-specific parameters>

In the DV video payload format, the a=fmtp line will be used to show

the encoding type within the DV video and will be used as below:

a=fmtp:<payload type> encode=<DV-video encoding>

The required parameter <DV-video encoding> specifies which type of DV

format is used. The DV format name will be one of the following:

SD-VCR/525-60

SD-VCR/625-50

HD-VCR/1125-60

HD-VCR/1250-50

SDL-VCR/525-60

SDL-VCR/625-50

306M/525-60

306M/625-50

314M-25/525-60

314M-25/625-50

314M-50/525-60

314M-50/625-50

In order to show whether the audio data is bundled into the DV stream

or not, a format specific parameter is defined as below:

a=fmtp:<payload type> audio=<audio bundled>

The optional parameter <audio bundled> will be one of the following:

bundled

none (default)

If the fmtp audio parameter is not present, then audio data MUST NOT

be bundled into the DV video stream.

3.1 SDP description for unbundled streams

When using unbundled mode, the RTP streams for video and audio will

be sent separately to different ports or different multicast groups.

When this is done, SDP carries several m=?? lines, one for each media

type of the session (see RFC2327 [13]).

An example SDP description using these attributes is:

v=0

o=ikob 2890844526 2890842807 IN IP4 126.16.64.4

s=POI Seminar

i=A Seminar on how to make Presentations on the Internet

u=http://www.koganei.wide.ad.jp/~ikob/POI/index.Html

e=ikob@koganei.wide.ad.jp (Katsushi Kobayashi)

c=IN IP4 224.2.17.12/127

t=2873397496 2873404696

m=audio 49170 RTP/AVP 112

a=rtpmap:112 L16/32000/2

m=video 50000 RTP/AVP 113

a=rtpmap:113 DV/90000

a=fmtp:113 encode=SD-VCR/525-60

a=fmtp:113 audio=none

This describes a session where audio and video streams are sent

separately. The session is sent to a multicast group 224.2.17.12.

The audio is sent using L16 format, and the video is sent using SD-

VCR 525/60 format which corresponds to NTSC format in consumer DV.

3.2 SDP description for bundled streams

When sending a bundled stream, all the DIF blocks including system

data will be sent through a single RTP stream. An example SDP

description for a bundled DV stream is:

v=0

o=ikob 2890844526 2890842807 IN IP4 126.16.64.4

s=POI Seminar

i=A Seminar on how to make Presentations on the Internet

u=http://www.koganei.wide.ad.jp/~ikob/POI/index.html

e=ikob@koganei.wide.ad.jp (Katsushi Kobayashi)

c=IN IP4 224.2.17.12/127

t=2873397496 2873404696

m=video 49170 RTP/AVP 112 113

a=rtpmap:112 DV/90000

a=fmtp: 112 encode=SD-VCR/525-60

a=fmtp: 112 audio=bundled

a=fmtp: 113 encode=306M/525-60

a=fmtp: 113 audio=bundled

This SDP record describes a session where audio and video streams are

sent bundled. The session is sent to a multicast group 224.2.17.12.

The video is sent using both 525/60 consumer DV and SMPTE standard

306M formats, when the payload type is 112 and 113, respectively.

4. Security Considerations

RTP packets using the payload format defined in this specification

are subject to the security considerations discussed in the RTP

specification [6], and any appropriate RTP profile. This implies

that confidentiality of the media streams is achieved by encryption.

Because the data compression used with this payload format is applied

to end-to-end, encryption may be performed after compression so there

is no conflict between the two operations.

A potential denial-of-service threat exists for data encodings using

compression techniques that have non-uniform receiver-end

computational load. The attacker can inject pathological datagrams

into the stream which are complex to decode and cause the receiver to

be overloaded. However, this encoding does not exhibit any

significant non-uniformity.

As with any IP-based protocol, in some circumstances a receiver may

be overloaded simply by the receipt of too many packets, either

desired or undesired. Network-layer authentication may be used to

discard packets from undesired sources, but the processing cost of

the authentication itself may be too high. In a multicast

environment, pruning of specific sources may be implemented in future

versions of IGMP [14] and in multicast routing protocols to allow a

receiver to select which sources are allowed to reach it.

5. IANA Considerations

This document defines a new RTP payload name and associated MIME

type, DV. The registration forms for the MIME types for both video

and audio are shown in the next sections.

5.1 DV video MIME registration form

MIME media type name: video

MIME subtype name: DV

Required parameters:

encode: type of DV format. Permissible values for encode are

SD-VCR/525-60, SD-VCR/625-50, HD-VCR/1125-60 HD-VCR/1250-50,

SDL-VCR/525-60, SDL-VCR/625-50, 306M/525-60, 306M/625-50,

314M-25/525-60, 314M-25/625-50, 314M-50/525-60, and

314M-50/625-50.

Optional parameters:

audio: whether the DV stream includes audio data or not.

Permissible values for audio are bundled and none. Defaults to

none.

Encoding considerations:

DV video can be transmitted with RTP as specified in RFC3189.

Other transport methods are not specified.

Security considerations:

See Section 4 of RFC3189.

Interoperability considerations: NONE

Published specification: IEC 61834 Standard

SMPTE 306M

SMPTE 314M

RFC3189

Applications which use this media type:

Video communication.

Additional information: None

Magic number(s): None

File extension(s): None

Macintosh File Type Code(s): None

Person & email address to contact for further information:

Katsushi Kobayashi

e-mail: ikob@koganei.wide.ad.jp

Intended usage: COMMON

Author/Change controller:

Katsushi Kobayashi

e-mail: ikob@koganei.wide.ad.jp

5.2 DV audio MIME registration form

MIME media type name: audio

MIME subtype name: DV

Required parameters:

encode: type of DV format. Permissible values for encode are

SD-VCR/525-60, SD-VCR/625-50, HD-VCR/1125-60 HD-VCR/1250-50,

SDL-VCR/525-60, SDL-VCR/625-50, 306M/525-60, 306M/625-50,

314M-25/525-60, 314M-25/625-50, 314M-50/525-60, and

314M-50/625-50.

Optional parameters: NONE

Encoding considerations:

DV audio can be transmitted with RTP as specified in RFC3189.

Other transport methods are not specified.

Security considerations:

See Section 4 of RFC3189.

Interoperability considerations: NONE

Published specification: IEC 61834 Standard

SMPTE 306M

SMPTE 314M

RFC3189

Applications which use this media type:

Audio communication.

Additional information: None

Magic number(s): None

File extension(s): None

Macintosh File Type Code(s): None

Person & email address to contact for further information:

Katsushi Kobayashi

e-mail: ikob@koganei.wide.ad.jp

Intended usage: COMMON

Author/Change controller:

Katsushi Kobayashi

e-mail: ikob@koganei.wide.ad.jp

6. References

[1] IEC 61834, Helical-scan digital video cassette recording system

using 6,35 mm magnetic tape for consumer use (525-60, 625-50,

1125-60 and 1250-50 systems).

[2] IEC 61883, Consumer audio/video equipment - Digital interface.

[3] IEEE Std 1394-1995, Standard for a High Performance Serial Bus

[4] SMPTE 306M, 6.35-mm type D-7 component format - video

compression at 25Mb/s -525/60 and 625/50.

[5] SMPTE 314M, Data structure for DV-based audio and compressed

video 25 and 50Mb/s.

[6] Schulzrinne, H., Casner, S., Frederick, R. and V. Jacobson,

"RTP: A transport protocol for real-time applications", RFC

1889, January 1996.

[7] Hoffman, D., Fernando, G., Goyal, V. and M. Civanlar, "RTP

Payload Format for MPEG1/MPEG2 Video", RFC2250, January 1998.

[8] Bradner, S., "Key words for use in RFCs to Indicate Requirement

Levels", BCP 14, RFC2119, March 1997.

[9] ISO/IEC 11172, Coding of moving pictures and associated audio

for digital storage media up to about 1,5 Mbits/s.

[10] ISO/IEC 13818, Generic coding of moving pictures and associated

audio information.

[11] Schulzrinne, H., "RTP Profile for Audio and Video Conferences

with Minimal Control", RFC1890, January 1996.

[12] Kobayashi, K., Ogawa, A., Casner S. and C. Bormann, "RTP

Payload Format for 12-bit DAT Audio and 20- and 24-bit Linear

Sampled Audio", RFC3190, January 2002.

[13] Handley, M. and V. Jacobson, "SDP: Session Description

Protocol", RFC2327, April 1998.

[14] Deering, S., "Host Extensions for IP Multicasting", STD 5, RFC

1112, August 1989.

7. Authors' Addresses

Katsushi Kobayashi

Communication Research Laboratory

4-2-1 Nukii-kitamachi,

Koganei Tokyo 184-8795 JAPAN

EMail: ikob@koganei.wide.ad.jp

Akimichi Ogawa

Keio University

5322 Endo,

Fujisawa Kanagawa 252 JAPAN

EMail: akimichi@sfc.wide.ad.jp

Stephen L. Casner

Packet Design

2465 Latham Street

Mountain View, CA 94040 United States

EMail: casner@acm.org

Carsten Bormann

Universitaet Bremen TZI

Postfach 330440

D-28334 Bremen, Germany

Phone: +49 421 218 7024

Fax: +49 421 218 7000

EMail: cabo@tzi.orgEMail: cabo@tzi.org

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