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Application avtcore Internet-Draft A visual volumetric video-based coding (V3C) bitstream is composed of V3C units that contain V3C atlas sub-bitstreams, V3C video sub-bitstreams, and a V3C parameter set. This memo describes an RTP payload format for V3C atlas sub-bitstreams. The RTP payload format for V3C video sub-bitstreams is defined by relevant Internet Standards for the applicable video codec. The V3C RTP payload format allows for packetization of one or more V3C atlas Network Abstraction Layer (NAL) units in an RTP packet payload as well as fragmentation of a V3C atlas NAL unit into multiple RTP packets. The memo also describes the mechanisms for grouping RTP streams of V3C component sub-bitstreams, providing a complete solution for streaming V3C encoded content.

Introduction Volumetric video, similar to conventional 2D video, when uncompressed, is represented by a large amount of data. The Visual Volumetric Video-based Coding (V3C) specification leverages the compression efficiency of existing 2D video codecs to reduce the amount of data needed for storage and transmission of volumetric video. V3C is a generic mechanism for volumetric video coding, and it can be used by applications targeting volumetric content, such as point clouds, Video-based Point Cloud Compression (V-PCC) , and immersive video with depth, MPEG Immersive Video (MIV) . A V3C encoder converts volumetric frames, i.e., 3D volumetric information, into a collection of 2D frames and associated data, known as atlas data. The converted 2D frames are subsequently coded using any video or image codec, e.g., ISO/IEC International Standard 14496-10 (Advanced Video Coding, AVC/H.264) , ISO/IEC International Standard 23008-2 (High Efficiency Video Coding, HEVC/H.265) or ISO/IEC International Standard 23090-3 (Versatile Video Coding, VVC/H.266) . The atlas data is coded with mechanisms specified in . V3C utilizes high level syntax (HLS) design, familiar from conventional 2D video codecs, to represent the associated coded data, i.e., atlas data. The coded atlas data is represented by Network Abstraction Layer (NAL) units. Consequently, RTP payload format for V3C atlas data described in this memo shares design philosophy, security, congestion control, and overall implementation complexity with the other NAL unit-based RTP payload formats such as the ones defined in , , and .

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 . The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 when, and only when, they appear in all capitals, as shown here. All fields defined in this specification related to RTP payload structures SHALL be considered in network order.

Definitions, and abbreviations

Definitions

General This document uses the definitions of . below lists relevant definitions from for convenience.

Definitions from the V3C specification atlas: collection of 2D bounding boxes and their associated information placed onto a rectangular frame and corresponding to a volume in 3D space on which volumetric data is rendered. atlas bitstream: sequence of bits that forms the representation of atlas frames and associated data forming one or more coded atlas sequences. atlas coding layer NAL unit: collective term for coded atlas tile layer NAL units and the subset of NAL units that have reserved values of nal_unit_type that are classified as being of type class equal to ACL in this document. atlas frame: 2D rectangular array of atlas samples onto which patches are projected and additional information related to the patches, corresponding to a volumetric frame. attribute: scalar or vector property optionally associated with each point in a volumetric frame such as colour, reflectance, surface normal, timestamps, material ID, etc. coded atlas sequence: sequence of coded atlas access units, in decoding order, of an IRAP coded atlas access unit, followed by zero or more coded atlas access units that are not IRAP coded atlas access units, including all subsequent access units up to but not including any subsequent coded atlas access unit that is an IRAP coded atlas access unit. coded atlas access unit: set of atlas NAL units that are associated with each other according to a specified classification rule, are consecutive in decoding order, and contain all atlas NAL units pertaining to one particular output time. coded visual volumetric video-based coding (V3C) sequence: sequence of V3C atlas and video sub-bitstream(s) identified and separated by appropriate delimiters, required to start with a VPS, included in at least one V3C unit or provided through external means. network abstraction layer unit: syntax structure containing an indication of the type of data to follow and bytes containing that data in the form of an RBSP. patch: rectangular region within an atlas associated with volumetric information. raw byte sequence payload: syntax structure containing an integer number of bytes that is encapsulated in a NAL unit and that is either empty or has the form of a string of data bits containing syntax elements followed by an RBSP stop bit and zero or more subsequent bits equal to 0. tile: independently decodable rectangular region of an atlas frame. visual volumetric video-based coding (V3C) atlas sub-bitstream: extracted sub-bitstream from the V3C bitstream containing whole or portion of an atlas bitstream. visual volumetric video-based coding (V3C) video sub-bitstream: extracted sub-bitstream from the V3C bitstream containing whole or portion of a video bitstream. visual volumetric video-based coding (V3C) component: atlas, occupancy, geometry, or attribute of a particular type that is associated with a V3C volumetric content representation. visual volumetric video-based coding (V3C) parameter set: syntax structure containing syntax elements that apply to zero or more entire CVSs and may be referred to by syntax elements found in the V3C unit header. volumetric frame: set of 3D points specified by their Cartesian coordinates and zero or more corresponding sets of attributes at a particular time instance.

Abbreviations ACL atlas coding layer AP aggregation packet AU aggregation unit CVS coded V3C sequence DON decoding order number IRAP intra random access point MTU maximum transmission unit NAL network abstraction layer NALU NAL unit RBSP raw byte sequence payload V3C visual volumetric video-based coding VPS V3C parameter set

Media format description

Overview of the V3C codec (informative) V3C encoding of a volumetric frame is achieved through a conversion of the volumetric frame from its 3D representation into multiple 2D representations and a generation of associated data documenting such conversions and transformations. The associated data, also known as the atlas data, provides information on how to reproject the 2D representations back into the 3D volumetric frame. 2D representations, known as V3C video components, of volumetric frame are encoded using conventional 2D video codecs. V3C video component may, for example, include occupancy, geometry, or attribute data. The occupancy data informs a V3C decoder which pixels in other V3C video components contribute to reconstructed 3D representation. The geometry data describes information on the position of the reconstructed voxels, while attribute data provides additional properties for the voxels, e.g., colour or material information. Atlas data, known as V3C atlas component, provides information to interpret V3C video components and enables the reconstruction from a 2D representation back into a 3D representation of volumetric frame. Atlas data is composed of a collection of patches. Each patch identifies a region in the V3C video components and provides information necessary to perform the appropriate inverse projection of the indicated region back into 3D space. The shape of the patch region is determined by a 2D bounding box associated with each patch as well as their coding order. The shape of these patches is also further refined based on occupancy data. To enable parallelization, random access, as well as a variety of other functionalities, an atlas frame can be divided into one or more rectangular partitions referred to as tiles. Tiles are not allowed to overlap and should be independently decodable. An atlas frame may contain regions that are not associated with any tile or patch. The binary form of V3C video components, i.e., video bitstream, and V3C atlas components, i.e., atlas bitstream, can be grouped and represented by a single V3C bitstream. The V3C bitstream is composed of a set of V3C units. Each V3C unit has a V3C unit header and a V3C unit payload. The V3C unit header describes the V3C unit type for the payload. V3C unit payload contains V3C video components, V3C atlas components or a V3C parameter set. V3C video components, i.e., occupancy, geometry, or attribute components, correspond to video data units (e.g., NAL units defined in ) that could be decoded by an appropriate video decoder. An example of V3C bitstream consisting of a V3C parameter set, atlas bitstream and three video component bitstreams (geometry, occupancy, attribute) is provided in .

Example of V3C bitstream

V3C parameter set (informative) This document specifies an encapsulation of V3C atlas data. Aspects related to signalling of V3C parameter set, defined in , are also considered. V3C parameter set is encapsulated in its own V3C unit, which allows decoupling the transmission of V3C parameter set from the V3C video and atlas components. The V3C parameter set can be transmitted by external means (e.g., as a result of the capability exchange) or through a (reliable or unreliable) control protocol. of this document specifies how a V3C parameter set can be signalled using the session description protocol. Generally, it is useful to signal V3C parameter set out-of-band, because it describes what overall resources are needed to decode and reconstruct the associated V3C bitstream. Signalling it dynamically as part of an RTP stream might result in undefined behaviour when receiver does not have the required capabilities to decode the received V3C video component sub-bitstreams or when reconstruction process relies on information that the receiver does not support.

V3C atlas and video components (informative)

General In the V3C bitstream the atlas component is identified by vuh_unit_type equal to V3C_AD, or V3C_CAD in case of common atlas data, in the V3C unit header. The V3C atlas component consists of atlas NAL units that define header and payload pairs, see . V3C video components are identified by vuh_unit_type equal to V3C_OVD, V3C_GVD, V3C_AVD, and V3C_PVD. V3C video components can be further differentiated by other values in the V3C unit header such as vuh_attribute_index, vuh_attribute_partition_index, vuh_map_index, and vuh_auxiliary_video_flag. By mapping the V3C parameter set information to vuh_attribute_index, a V3C decoder identifies which attribute a given V3C video component contains, e.g., colour. The information supplied by V3C unit header should be provided in one form or another to a V3C decoder, e.g., as part of SDP as described in this memo in . The four-byte V3C unit header syntax and semantics are copied below as defined in , but the syntax is subject to change. Implementations should always refer to the latest specification of . The syntax of four-byte V3C unit header is provided here for informative purposes only. The integers in the parentheses, e.g., unsigned int(5), indicate the number of bits used by the syntax element. vuh_unit_type indicates the V3C unit type for the V3C component as specified in . As a convenience, the mapping table from vuh_unit_type values to semantics is copied below in . V3C unit type semantics

vuh_unit_type	Identifier	V3C unit type	Description
0	V3C_VPS	V3C parameter set	V3C level parameters
1	V3C_AD	Atlas data	Atlas information
2	V3C_OVD	Occupancy video data	Occupancy information
3	V3C_GVD	Geometry video data	Geometry information
4	V3C_AVD	Attribute video data	Attribute information
5	V3C_PVD	Packed video data	Packing information
6	V3C_CAD	Common atlas data	Information that is common for atlases in a CVS. Specified in ISO/IEC 23090-12
7...31	V3C_RSVD	Reserved	-

vuh_v3c_parameter_set_id specifies the value of vps_v3c_parameter_set_id for the active V3C VPS. vuh_atlas_id specifies the ID of the atlas that corresponds to the current V3C unit. vuh_attribute_index indicates the index of the attribute data carried in the Attribute Video Data unit. vuh_attribute_partition_index indicates the index of the attribute dimension group carried in the attribute video data unit. vuh_map_index when present indicates the map index of the current geometry or attribute stream. When not present, the map index of the current geometry or attribute sub-bitstream is derived based on the type of the sub-bitstream. vuh_auxiliary_video_flag equal indicates if the associated geometry or attribute video data unit is a RAW and/or EOM coded points video only sub-bitstream.

Atlas NAL units Atlas NAL unit (nal_unit(NumBytesInNalUnit)) is a byte-aligned syntax structure defined by to carry atlas data. Atlas NAL unit always contains a 16-bit NAL unit header (nal_unit_header()), which indicates among other things the type of the NAL unit (nal_unit_type). The payload of a NAL unit refers to the NAL unit excluding the NAL unit header. The Atlas NAL unit syntax and semantics are copied here as defined in . nal_forbidden_zero_bit MUST be equal to 0. nal_unit_type indicates the type of the RBSP data structure contained in the NAL unit. nal_layer_id indicates the identifier of the layer to which an ACL NAL unit belongs or the identifier of a layer to which a non-ACL NAL unit applies. nal_temporal_id_plus1 minus 1 indicates a temporal identifier for the NAL unit. The value of nal_temporal_id_plus1 MUST NOT be equal to 0.

Systems and transport interfaces (informative) In addition to releasing specifications on V3C applications and , MPEG conducted further systems level work on file formats to encapsulate compressed V3C content. The seventh edition of the ISOBMFF specification introduces a new media handler 'volv', intended to support volumetric visual media. It also specifies other structures to enable development of derived specifications detailing how various volumetric visual media may be stored in ISOBMFF. One of such derived specifications is , which defines how V3C content can be stored in a file and streamed over DASH. To a large extent ISO/IEC 23090-10 focuses on describing how ISOBMFF boxes and syntax elements may be used to store volumetric media, but in some cases new boxes and syntax elements are introduced to accommodate the fundamentally different type of new media. While the specification is not directly relevant for defining RTP payload format for V3C atlas data, it is a useful resource that may be considered especially when designing ingestion of encoded V3C content into RTP streaming pipelines.

V3C atlas RTP payload format

General This section describes details related to V3C atlas RTP payload format definitions. Aspects related to RTP header, RTP payload header and general payload structure are considered. RTP payload format(s) for video components is defined in their respective RTP payload format specifications depending on the video codec used.

RTP header The format of the RTP header is specified in and replicated below in for convenience. This payload format uses the fields of the header in a manner consistent with that specification.

RTP Header

The RTP header information to be set according to this RTP payload format is set as follows: Marker bit (M): 1 bit Set for the last packet of the access unit, carried in the current RTP stream. This is in line with the normal use of the M bit in video formats to allow an efficient playout buffer handling. Payload Type (PT): 7 bits The assignment of an RTP payload type for this new packet format is outside the scope of this document and will not be specified here. The assignment of a payload type MUST be performed either through the profile used or in a dynamic way. Sequence Number (SN): 16 bits Set and used in accordance with . Timestamp: 32 bits The RTP timestamp is set to the sampling timestamp of the content. A 90 kHz clock rate MUST be used. If the NAL unit has no timing properties of its own (e.g., parameter set and SEI NAL units), the RTP timestamp MUST be set to the RTP timestamp of the coded atlas of the access unit in which the NAL unit (according to Section 8.4.5.3 of ) is included. Receivers MUST use the RTP timestamp for the display process, even when the bitstream contains atlas frame timing SEI messages as specified in . Synchronization source (SSRC): 32 bits Used to identify the source of the RTP packets. By definition, a single SSRC is used for all parts of a single bitstream. The remaining RTP header fields are used as specified in .

RTP payload header The first two bytes of the payload of an RTP packet are referred to as the payload header. The payload header consists of the same fields (F, NUT, NLI, and TID) as the NAL unit header as shown in , irrespective of the type of the payload structure. For convenience, the structure of RTP payload header is described below in .

RTP Payload Header

F: the nal_forbidden_zero_bit as specified in MUST be equal to 0. NUT: the nal_unit_type as specified in defines the type of the RBSP data structure contained in the NAL unit payload. The NUT value could carry other meaning depending on the RTP packet type. NLI: the nal_layer_id as specified in defines the identifier of the layer to which an ACL NAL unit belongs or the identifier of a layer to which a non-ACL NAL unit applies. TID: the nal_temporal_id_plus1 minus 1 as specified in defines a temporal identifier for the NAL unit. The value of nal_temporal_id_plus1 MUST NOT be equal to 0.

Payload structures

General Three different types of RTP packet payload structures are specified. A receiver can identify the payload structure by the first two bytes of the RTP packet payload, which co-serves as the RTP payload header. These two bytes are always structured as a NAL unit header. The NAL unit type field indicates which structure is present in the payload. The three different payload structures are as follows:

• Single NAL Unit Packet: Contains a single NAL unit in the payload. This payload structure is specified in .
• Aggregation Packet: Contains multiple NAL units in a single RTP payload. This payload structure is specified in .
• Fragmentation Unit: Contains a subset of a single NAL unit. This payload structure is specified in .

NOTE: (informative) This memo does not limit the size of NAL units encapsulated in NAL unit packets and fragmentation units. does not restrict the maximum size of a NAL unit directly either. Instead, a NAL unit sample stream format may be used, which provides flexibility to signal NAL unit size up to UINT64_MAX bytes.

Single NAL unit packet Single NAL unit packet contains exactly one NAL unit, and consists of an RTP payload header and the following conditional fields: 16-bit DONL and 16-bit v3c-tile-id. The rest of the payload data contains the NAL unit payload data (excluding the NAL unit header). A single NAL unit packet MUST only contain atlas NAL units of the types defined in Table 4 of . The structure of the single NAL unit packet is shown below in .

Single NAL unit packet

The RTP payload header MUST be an exact copy of the NAL unit header of the contained NAL unit. A NAL unit stream composed by de-packetizing single NAL unit packets in RTP sequence number order MUST conform to the NAL unit decoding order, when DONL is not present. The DONL field, when present, specifies the value of the 16-bit decoding order number of the contained NAL unit. If sprop-max-don-diff is greater than 0 for any of the RTP streams, the DONL field MUST be present, and the variable DONL for the contained NAL unit is derived as equal to the value of the DONL field. Otherwise (sprop-max-don-diff is equal to 0 for all the RTP streams), the DONL field MUST NOT be present. The v3c-tile-id field, when present, specifies the 16-bit tile identifier for the NAL unit, as signalled in V3C atlas tile header defined in . If sprop-v3c-tile-id-pres is equal to 1 and RTP payload header NUT is in range 0-35, inclusive, the v3c-tile-id field MUST be present. Otherwise, the v3c-tile-id field MUST NOT be present. NOTE: (informative) Only values for NAL unit type (NUT) in range 0-35, inclusive, are allocated for atlas tile layer data in .

Aggregation packet Aggregation Packets (APs) enable the reduction of packetization overhead for small NAL units, such as most of the non-ACL NAL units, which are often only a few octets in size. Aggregation packets MAY be used to wrap multiple NAL units belonging to the same access unit in a single RTP payload. The first two bytes of an AP MUST contain the RTP payload header. The NAL unit type (NUT) for the NAL unit header contained in the RTP payload header MUST be equal to 56, which falls in the unspecified range of the NAL unit types defined in . An AP MAY contain a conditional v3c-tile-id field. An AP MUST contain two or more aggregation units. The structure of an AP is shown in .

Aggregation Packet (AP)

The fields in the payload header are set as follows. The F bit MUST be equal to 0 if the F bit of each aggregated NAL unit is equal to zero; otherwise, it MUST be equal to 1. The NUT field MUST be equal to 56. The value of NLI MUST be equal to the lowest value of NLI of all the aggregated NAL units. The value of TID MUST be the lowest value of TID of all the aggregated NAL units. All ACL NAL units in an aggregation packet have the same TID value since they belong to the same access unit. However, the packet MAY contain non-ACL NAL units for which the TID value in the NAL unit header MAY be different than the TID value of the ACL NAL units in the same AP. The v3c-tile-id field, when present, specifies the 16-bit tile identifier for all ACL NAL units in the AP. If sprop-v3c-tile-id-pres is equal to 1, the v3c-tile-id field MUST be present. Otherwise, the v3c-tile-id field MUST NOT be present. An AP MUST carry at least two aggregation units (AU) and can carry as many aggregation units as necessary. However, the total amount of data in an AP MUST fit into an IP packet, and the size SHOULD be chosen so that the resulting IP packet is smaller than the MTU size so to avoid IP layer fragmentation. The structure of the AU depends both on the presence of the decoding order number, the sequence order of the AU in the AP and the presence of v3c-tile-id field. The structure of an AU is shown in .

Aggregation Unit (AU)

If sprop-max-don-diff is greater than 0 for any of the RTP streams, an AU begins with the DOND / DONL field. The first AU in the AP contains DONL field, which specifies the 16-bit value of the decoding order number of the aggregated NAL unit. The variable DON for the aggregated NAL unit is derived as equal to the value of the DONL field. All subsequent AUs in the AP MUST contain an (8-bit) DOND field, which specifies the difference between the decoding order number values of the current aggregated NAL unit and the preceding aggregated NAL unit in the same AP. The variable DON for the aggregated NAL unit is derived as equal to the DON of the preceding aggregated NAL unit in the same AP plus the value of the DOND field plus 1 modulo 65536. When sprop-max-don-diff is equal to 0 for all the RTP streams, DOND / DONL fields MUST NOT be present in an aggregation unit. The aggregation units MUST be stored in the aggregation packet so that the decoding order of the containing NAL units is preserved. This means that the first aggregation unit in the aggregation packet SHOULD contain the NAL unit that SHOULD be decoded first. If sprop-v3c-tile-id-pres is equal to 2 and the AU NAL unit header type is in range 0-35, inclusive, the 16-bit v3c-tile-id field MUST be present in the aggregation unit after the conditional DOND/DONL field, otherwise v3c-tile-id field MUST NOT be present in the aggregation unit. The conditional fields of the aggregation unit are followed by a 16-bit NALU size field, which provides the size of the NAL unit (in bytes) in the aggregation unit. The remainder of the data in the aggregation unit SHOULD contain the NAL unit (including the unmodified NAL unit header).

Fragmentation unit Fragmentation Units (FUs) are introduced to enable fragmenting a single NAL unit into multiple RTP packets, possibly without co-operation or knowledge of the encoder. A fragment of a NAL unit consists of an integer number of consecutive octets of that NAL unit. Fragments of the same NAL unit MUST be sent in consecutive order with ascending RTP sequence numbers (with no other RTP packets within the same RTP stream being sent between the first and last fragment. When a NAL unit is fragmented and conveyed within FUs, it is referred to as a fragmented NAL unit. Aggregation packets MUST NOT be fragmented. FUs MUST NOT be nested; i.e., an FU MUST NOT contain a subset of another FU. The RTP header timestamp of an RTP packet carrying an FU is set to the NALU-time of the fragmented NAL unit. An FU consists of an RTP payload header with NUT equal to 57, an 8-bit FU header, a conditional 16-bit DONL field, a conditional 16-bit v3c-tile-id field, and an FU payload. The structure of an FU is illustrated below in .

Fragmentation Unit

The fields in the RTP payload header are set as follows. The NUT field MUST be equal to 57. The rest of the fields MUST be equal to the fragmented NAL unit. The FU header consists of an S bit, an E bit, and a 6-bit FUT field. The structure of FU header is illustrated below in .

Fragmentation unit header

When set to 1, the S bit indicates the start of a fragmented NAL unit, i.e., the first byte of the FU payload is also the first byte of the payload of the fragmented NAL unit. When the FU payload is not the start of the fragmented NAL unit payload, the S bit MUST be set to 0. When set to 1, the E bit indicates the end of a fragmented NAL unit, i.e., the last byte of the payload is also the last byte of the fragmented NAL unit. When the FU payload is not the last fragment of a fragmented NAL unit, the E bit MUST be set to 0. The field FUT MUST be equal to the nal_unit_type field of the fragmented NAL unit. A non-fragmented NAL unit MUST NOT be transmitted in one FU; i.e., the Start bit and End bit MUST NOT both be set to 1 in the same FU header. The DONL field, when present, specifies the value of the 16-bit decoding order number of the fragmented NAL unit. If sprop-max-don-diff is greater than 0 for any of the RTP streams, and the S bit is equal to 1, the DONL field MUST be present in the FU, and the variable DON for the fragmented NAL unit is derived as equal to the value of the DONL field. Otherwise (sprop-max-don-diff is equal to 0 for all the RTP streams, or the S bit is equal to 0), the DONL field MUST NOT be present in the FU. The v3c-tile-id field, when present, specifies the 16-bit tile identifier for the fragmented NAL unit. If sprop-v3c-tile-id-pres is equal to 1, FUT is in range 0-35, and the S bit is equal to 1, the v3c-tile-id field MUST be present after the conditional DONL field. Otherwise, the v3c-tile-id field MUST NOT be present. The FU payload consists of fragments of the payload of the fragmented NAL unit so that if the FU payloads of consecutive FUs, starting with an FU with the S bit equal to 1 and ending with an FU with the E bit equal to 1, are sequentially concatenated, the payload of the fragmented NAL unit can be reconstructed. The NAL unit header of the fragmented NAL unit is not included as such in the FU payload, but rather the information of the NAL unit header of the fragmented NAL unit is conveyed in F, NLI, and TID fields of the RTP payload headers of the FUs and the FUT field of the FU header. An FU payload MUST NOT be empty. If an FU is lost, the receiver SHOULD discard all following fragmentation units in transmission order corresponding to the same fragmented NAL unit, unless the decoder in the receiver is known to be prepared to gracefully handle incomplete NAL units.

Example of fragmentation unit (informative) This example illustrates how fragmentation unit may be used to divide one NAL unit into two RTP packets. The depicts the structure of the first packet with the first part of the fragmented NAL unit.

First packet of fragmented NAL unit

The visualizes the structure of the second packet with the rest of the fragmented NAL unit.

Second packet of fragmented NAL unit

Decoding order number For each atlas NAL unit, the variable AbsDon is derived, representing the decoding order number that is indicative of the NAL unit decoding order. Let NAL unit n be the n-th NAL unit in transmission order within an RTP stream. If sprop-max-don-diff is equal to 0 for all the RTP streams carrying the atlas bitstream, AbsDon[n], the value of AbsDon for NAL unit n, is derived as equal to n. Otherwise (sprop-max-don-diff is greater than 0 for any of the RTP streams), AbsDon[n] is derived as follows, where DON[n] is the value of the variable DON for NAL unit n: DON[n-1] and DON[n] - DON[n-1] < 32768) AbsDon[n] = AbsDon[n-1] + DON[n] - DON[n-1] If (DON[n] < DON[n-1] and DON[n-1] - DON[n] >= 32768) AbsDon[n] = AbsDon[n-1] + 65536 - DON[n-1] + DON[n] If (DON[n] > DON[n-1] and DON[n] - DON[n-1] >= 32768) AbsDon[n] = AbsDon[n-1] - (DON[n-1] + 65536 - DON[n]) If (DON[n] < DON[n-1] and DON[n-1] - DON[n] < 32768) AbsDon[n] = AbsDon[n-1] - (DON[n-1] - DON[n]) ]]> For any two NAL units m and n, the following applies:

• AbsDon[n] greater than AbsDon[m] indicates that NAL unit n follows NAL unit m in NAL unit decoding order.
• When AbsDon[n] is equal to AbsDon[m], the NAL unit decoding order of the two NAL units can be in either order.
• AbsDon[n] less than AbsDon[m] indicates that NAL unit n precedes NAL unit m in decoding order.

Packetization and de-packetization rules The following packetization rules apply for V3C atlas data:

• If sprop-max-don-diff is greater than 0 for any of the RTP streams, the transmission order of NAL units carried in the RTP stream MAY be different than the NAL unit decoding order and the NAL unit output order. Otherwise (sprop-max-don-diff is equal to 0 for all the RTP streams), the transmission order of NAL units carried in the RTP stream MUST be the same as the NAL unit decoding order.
• A NAL unit of a small size SHOULD be encapsulated in an aggregation packet together with one or more other NAL units in order to avoid the unnecessary packetization overhead for small NAL units. For example, non-ACL NAL units such as access unit delimiters, parameter sets, or SEI NAL units are typically small and can often be aggregated with ACL NAL units without violating MTU size constraints.
• Each non-ACL NAL unit SHOULD, when possible, from an MTU size perspective, be encapsulated in an aggregation packet together with its associated ACL NAL unit, as typically a non-ACL NAL unit would be meaningless without the associated ACL NAL unit being available.
• For carrying exactly one NAL unit in an RTP packet, a single NAL unit packet () MUST be used.

The general concept behind de-packetization is to get the NAL units out of the RTP packets in an RTP stream and all RTP streams the RTP stream depends on, if any, and pass them to the decoder in the NAL unit decoding order. The de-packetization process is implementation dependent. Therefore, the following de-packetization rules SHOULD be taken as an example.

• All normal RTP mechanisms related to buffer management apply. In particular, duplicated or outdated RTP packets (as indicated by the RTP sequence number and the RTP timestamp) are removed. To determine the exact time for decoding, factors such as a possible intentional delay to allow for proper inter-stream synchronization must be factored in.
• NAL units with NAL unit type values in the range of 0 to 55, inclusive, may be passed to the decoder. NAL-unit-like structures with NAL unit type values in the range of 56 to 63, inclusive, MUST NOT be passed to the decoder.
• When sprop-max-don-diff is equal to 0 for the received RTP stream, the NAL units carried in the RTP stream MAY be directly passed to the decoder in their transmission order, which is identical to their decoding order.
• When sprop-max-don-diff is greater than 0 for any of the received RTP streams, the received NAL units need to be arranged into decoding order before handing them over to the decoder.
• For further de-packetization examples, the reader is referred to Section 6 of .

Regarding the packetization of V3C video component data, the respective RTP video payload specification(s) define how packetization and de-packetization should be handled.

Payload format parameters This section specifies the optional parameters. A mapping of the parameters into the Session Description Protocol (SDP) is also provided for applications that use SDP. Equivalent parameters could be defined elsewhere for use with control protocols that do not use SDP.

Media type registration The receiver MUST ignore any parameter unspecified in this memo. Type name: application Subtype name: v3c Required parameters: N/A Optional parameters: sprop-v3c-unit-header, sprop-v3c-unit-type, sprop-v3c-vps-id, sprop-v3c-atlas-id, sprop-v3c-attr-idx, sprop-v3c-attr-part-idx, sprop-v3c-map-idx, sprop-v3c-aux-video-flag, sprop-v3c-parameter-set, sprop-v3c-tile-id, sprop-v3c-tile-id-pres, sprop-v3c-atlas-data, sprop-v3c-common-atlas-data, sprop-v3c-sei, v3c-ptl-level-idc, v3c-ptl-tier-flag, v3c-ptl-codec-idc, v3c-ptl-toolset-idc, v3c-ptl-rec-idc and sprop-max-don-diff. Encoding considerations: framed Security considerations: Please see . Interoperability considerations: N/A Published specification: "this memo" RFC-EDITOR: Please replace "this memo" with the published RFC number Applications that use this media type: Any application that relies on V3C-based media services over RTP Additional information: N/A Person & email address to contact for further information: Lauri Ilola (lauri.ilola@nokia.com) or Lukasz Kondrad (lukasz.kondrad@nokia.com) Intended usage: COMMON Restrictions on usage: This media type depends on RTP framing and, hence, is only defined for transfer via RTP . Transport within other framing protocols is not defined at this time. Author: See Authors' Addresses section of this memo Change controller: IETF avtcore@ietf.org Provisional registration? (standards tree only): No

Optional parameters definition provides bytes corresponding to a V3C unit header as defined in . The value contains base64 encoded representation of the 4 bytes of V3C unit header. sprop-v3c-unit-type provides a V3C unit type value corresponding to vuh_unit_type defined in , i.e., defines V3C sub-bitstream type. sprop-v3c-vps-id provides a value corresponding to vuh_v3c_parameter_set_id defined in . sprop-v3c-atlas-id provides a value corresponding to vuh_atlas_id defined in . sprop-v3c-attr-idx provides a value corresponding to vuh_attribute_index defined in . sprop-v3c-attr-part-idx provides a value corresponding to vuh_attribute_partition_index defined in . sprop-v3c-map-idx provides a value corresponding to vuh_map_index defined in . sprop-v3c-aux-video-flag provides a value corresponding to vuh_auxiliary_video_flag defined in . sprop-v3c-parameter-set provides V3C parameter set bytes as defined in . The value contains base64 encoded representation of the V3C parameter set bytes. sprop-v3c-tile-id indicates that the RTP stream contains only portion of the tiles in the atlas. sprop-v3c-tile-id is a comma-separated (',') list of integer values, which indicate the sprop-v3c-tile-ids that are present in the RTP stream. sprop-v3c-tile-id-pres indicates that the RTP packets contain v3c-tile-id field. sprop-v3c-atlas-data MAY be used to convey any atlas data NAL units of the V3C atlas sub bitstream for out-of-band transmission. The value is a comma-separated (',') list of encoded representations of the atlas NAL units as specified in . The NAL units SHOULD be encoded as base64 representations. sprop-v3c-common-atlas-data MAY be used to convey common atlas data NAL units of the V3C common atlas sub bitstream for out-of-band transmission. The value is a comma-separated (',') list of encoded representations of the common atlas NAL units (i.e., NAL_CASPS and NAL_CAF_IDR) as specified in . The NAL units SHOULD be encoded as base64 representations. sprop-v3c-sei MAY be used to convey SEI NAL units of V3C atlas and common atlas sub bitstreams for out-of-band transmission. The value is a comma-separated (',') list of encoded representations of SEI NAL units (i.e., NAL_PREFIX_NSEI and NAL_SUFFIX_NSEI, NAL_PREFIX_ESEI, NAL_SUFFIX_ESEI) as specified in . The SEI NAL units SHOULD be encoded as base64 representations. v3c-ptl-level-idc provides a value corresponding to ptl_level_idc defined in . v3c-ptl-tier-flag provides a value corresponding to ptl_tier_flag defined in . v3c-ptl-codec-idc provides a value corresponding to ptl_profile_codec_group_idc defined in . v3c-ptl-toolset-idc provides a value corresponding to ptl_profile_toolset_idc defined in . v3c-ptl-rec-idc provides a value corresponding to ptl_profile_reconstruction_idc defined in . If the transmission order of NAL units in the RTP stream(s) is the same as the decoding and NAL unit output order, this parameter must be equal to 0. Otherwise, if the decoding order of the NAL units of the RTP stream(s) is the same as the NAL unit transmission order but not the same as NAL unit output order, the value of this parameter MUST be equal to 1. Otherwise, this parameter specifies the maximum absolute difference between the decoding order number (i.e., AbsDon) values of any two NAL units naluA and naluB, where naluA follows naluB in decoding order and precedes naluB in transmission order. The value of sprop-max-don-diff MUST be an integer in the range of 0 to 32767, inclusive. When not present, the value of sprop-max-don-diff is inferred to be equal to 0.

Congestion control considerations Congestion control for RTP SHALL be used in accordance with RTP and with any applicable RTP profile, e.g., AVP . If a best-effort service is being used, users of this payload format MUST monitor packet loss to ensure that the packet loss rate is within an acceptable range. Packet loss is considered acceptable if a TCP flow across the same network path, and experiencing the same network conditions, would achieve an average throughput, measured on a reasonable timescale, that is not less than that of the RTP flow (see section 10 of ). This condition can be satisfied by implementing congestion-control mechanisms to adapt the transmission rate. A simple bitrate adaptation for congestion control can be achieved when real-time coding is used for V3C video components, where quality parameter can be adaptively tuned. Video coding specifications MAY define further adaptation techniques. An alternative method is to arrange for a receiver to leave the session if the loss rate is unacceptably high, for example using a Circuit Breaker that defines criteria for when one the RTP flow must stop sending RTP Packet Streams.

Session description protocol A new attribute "v3cfmtp" is defined for carrying V3C format media type parameters in the corresponding fields of the Session Description Protocol (SDP) . Grouping framework is used to indicate which media lines (video and application) in the SDP constitute a V3C representation.

V3C format parameters "v3cfmtp" attribute This memo defines a new attribute for SDP, intended to carry V3C specific media format parameters. Its functionality is similar to "a=fmtp", with the exception that it SHALL be used without the fmt-token and that it can be used also on a session level. The attribute allows to associate V3C specific media format parameters with any media line in SDP. Contact name: See Authors' Addresses section of this memo. Contact email address: See Authors' Addresses section of this memo. Attribute name: v3cfmtp Attribute value: v3cfmtp-value Attribute syntax: Attribute semantics: "v3cfmtp-value" is a byte-string, as defined in , which MUST contain at least one V3C specific media format parameter as a "parameter=value"-pair as defined in this memo. Multiple semicolon-separated V3C media "parameter=value"-pairs MAY be stored in the byte-string to be conveyed by SDP and given unchanged to the media tool that will use this format. White spaces in the byte-string SHALL be ignored. Usage level: session, media Charset dependent: no Purpose: This attribute allows parameters that are specific to a V3C format to be conveyed in a way that SDP does not have to understand them. It allows to associate V3C specific parameters with the session or with any media line. Parameters signalled as part of session level attribute take effect when conflicting parameters are signalled as media level attribute. O/A procedures: v3cfmtp attribute MAY be present both in offers and answers Mux Category: NORMAL Reference: "this memo" RFC-EDITOR: Please replace "this memo" with the published RFC number Example: First line describes session level usage of the attribute, signaling a V3C parameter set. Second line describes media level attribute, signaling V3C unit header and profile tier level flag for the associated media line.

Mapping of payload type parameters to SDP

For V3C atlas components

• The media name in the "m=" line of SDP MUST be application.
• The encoding name in the "a=rtpmap" line of SDP MUST be v3c
• The clock rate in the "a=rtpmap" line MUST be 90000.
• The OPTIONAL parameters sprop-v3c-atlas-data, sprop-v3c-common-atlas-data, sprop-v3c-sei, sprop-v3c-tile-id, sprop-v3c-tile-id-pres, when present, MUST be included in the "a=fmtp" line of SDP. This parameter is expressed as a media type string, in the form of a semicolon-separated list of parameter=value pairs.
• The OPTIONAL parameters sprop-v3c-unit-header, sprop-v3c-unit-type, sprop-v3c-vps-id, sprop-v3c-atlas-id, sprop-v3c-attr-idx, sprop-v3c-attr-part-idx, sprop-v3c-map-idx, sprop-v3c-aux-video-flag, sprop-max-don-diff, sprop-v3c-parameter-set, v3c-ptl-level-idc, v3c-ptl-tier-flag, v3c-ptl-codec-idc, v3c-ptl-toolset-idc, v3c-ptl-rec-idc, when present, MUST be included in the "a=v3cfmtp" line of SDP. This parameter is expressed as a media type string, in the form of a semicolon-separated list of parameter=value pairs.

The OPTIONAL parameters, when present in the V3C atlas component media line format parameters attribute, specify values that are valid for the coded V3C sequence until a new value is received in-band. Some OPTIONAL parameters, like sprop-v3c-parameter-set or sprop-v3c-unit-header, can't be carried in-band in the atlas stream and may thus be considered static for the session. The carriage of V3C payload format parameters in "a=fmtp" and "a=v3cfmtp" attributes is separated by logical context, where "a=fmtp" consists of atlas level media format parameters and "a=v3cfmtp" contains V3C level media format parameters. An example of media representation corresponding to atlas data component (V3C_AD), where static V3C parameter set and V3C unit header is carried out-of-band in SDP, is as follows:

For V3C video components

• The media name in the "m=" line of SDP MUST be video.
• The encoding name in the "a=rtpmap" line of SDP can be any video subtype, e.g., H.264, H.265, H.266 etc.
• The clock rate in the "a=rtpmap" line MUST be 90000.
• The OPTIONAL parameters sprop-v3c-unit-header, sprop-v3c-unit-type, sprop-v3c-vps-id, sprop-v3c-atlas-id, sprop-v3c-attr-idx, sprop-v3c-attr-part-idx, sprop-v3c-map-idx, sprop-v3c-aux-video-flag, sprop-max-don-diff, sprop-v3c-parameter-set, sprop-v3c-atlas-data, sprop-v3c-common-atlas-data, sprop-v3c-sei, sprop-v3c-tile-id, sprop-v3c-tile-id-pres, v3c-ptl-level-idc, v3c-ptl-tier-flag, v3c-ptl-codec-idc, v3c-ptl-toolset-idc, v3c-ptl-rec-idc, when present, MUST be included in the "a=v3cfmtp" line of SDP. This parameter is expressed as a media type string, in the form of a semicolon-separated list of parameter=value pairs.

The OPTIONAL parameters, when present in the video media line V3C format parameters ("v3cfmtp") attribute, specify values that are considered static for the session. An example of media representation corresponding to occupancy video component (V3C_OVD) in SDP is as follows: Below is an example of media representation corresponding to packed video component (V3C_PVD), where static V3C parameter set, atlas data and common atlas data are carried out-of-band in SDP. The values are considered static for the session, as they can't be signaled in-band in the video stream.

Grouping framework Different V3C components MAY be represented by their own respective RTP streams, whose payload formats are defined in the respective specifications. V3C atlas data RTP payload format is defined in this memo, whereas the video component RTP payload formats are defined for example in or . A grouping tool, as defined in , is extended to indicate which media lines constitute a V3C representation. Group attribute with V3C type is provided to allow application to identify "m" lines that belong to the same V3C bitstream. Grouping type V3C MUST be used with the group attribute. The tokens that follow are mapped to 'mid'-values of individual media lines in the SDP. ]]> The following example shows an SDP including four media lines, three describing V3C video components (PT:96=occupancy, PT:97=geometry, PT:98=attribute) and one V3C atlas component (PT:100). All the media lines are grouped under one V3C group. V3C parameter set is provided via session level V3C media format parameter attribute. The example below describes how content with two atlases can be signalled as separate streams. V3C parameter set is carried in a session level V3C media format parameter attribute and common atlas data are carried as part of the media level V3C media format parameter attribute corresponding to atlas zero. PT equal to 96, 97, 98 and 100 correspond to occupancy, geometry, and attribute video component as well as atlas data component for atlas zero. PT equal to 101, 102, 103 and 104 correspond to respective components for atlas one.

Offer and answer considerations

Unicast This section describes the negotiation of unicast streaming using the offer/answer model as described in . V3C coded content consists of an atlas bitstream and one or more video coded bitstreams, together known as V3C components. Atlas and video bitstreams are represented as separate media lines in the SDP. During the session negotiation the offerer lists all V3C components available and informs the answerer which media lines SHOULD be consumed together. The answerer CAN select V3C components as suggested by the offerer, or select a subset of the V3C components by setting the port to zero for the undesired media lines in the answer. This allows the answerer to consume a subset of the V3C components in scenarios where it is fully or partially ignorant of the V3C coding scheme. The following limitations and rules pertaining to the V3C atlas component media configuration apply:

• The parameters identifying the V3C atlas component media configuration is identified by v3c-ptl-level-idc, v3c-ptl-tier-flag, v3c-ptl-codec-idc, and v3c-ptl-toolset-idc. These media configuration parameters, except level-id, MUST be used symmetrically.
• Send only properties, identified by sprop-prefix, are considered declarative and SHOULD be omitted in the answers.

The answerer MUST structure its answer according to one of the following two options:

• maintain all configuration parameters with the values remaining the same as in the offer for the media format (payload type), with the exception that the value of v3c-ptl-level-idc is changeable as long as the highest level indicated by the answer is not higher than that indicated by the offer, or
• reject media line in which one or more of the parameter values are not supported by setting the port to zero in the answer.

The following limitations and rules pertaining to the V3C video component media configuration apply:

• The parameters identifying a video coded V3C component media configuration format are according to the respective RTP video payload specification.

The answerer MUST structure its answer according to one of the following two options:

• maintain all configuration parameters with the values remaining the same as in the offer for the media format (payload type), with the exceptions specified in the respective RTP video payload specification;
• reject the video coded V3C component media line completely when one or more of the parameter values are not supported by setting the port to zero in the answer.

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 . An example of an offer which only sends V3C content. The following example contains video components as three different versions (H.264, H.265, H.266). Further differences between the alternatives would be signaled as part of the media attribute parameters, as is the practice with regular video streams. An example of an answer that only receives V3C data with the selected versions. An example offer, which allows bundling different V3C components into one stream, based on . An example answer, which accepts bundling of different V3C components.

Multicast For bitstreams being delivered over multicast, the following rules apply:

• The atlas V3C component media configuration is identified by v3c-ptl-level-idc, v3c-ptl-tier-flag, v3c-ptl-codec-idc, and v3c-ptl-toolset-idc. These atlas format configuration parameters MUST be used symmetrically; that is, the answerer MUST either maintain all configuration parameters or reject the media line, including any associated video coded V3C component media lines. This implies that v3c-ptl-level-idc for offer/answer in multicast is not changeable.
• The video coded V3C component media configuration format is according the respective RTP video payload specification.
• To simplify the handling and matching of these configurations, the same RTP payload type number used in the offer MUST also be used in the answer.
• Parameter sets received MUST be associated with the originating source and MUST only be used in decoding the incoming bitstream from the same source.

Declarative SDP considerations When V3C content over RTP is offered with SDP in a declarative style, the parameters capable of indicating both bitstream properties as well as answerer capabilities are used to indicate only bitstream properties. For example, in this case, the parameters v3c-ptl-level-idc, v3c-ptl-tier-flag, v3c-ptl-codec-idc, v3c-ptl-toolset-idc and v3c-ptl-rec-idc declare the values used by the bitstream, not the capabilities for receiving bitstreams. An answerer of the SDP is required to support all parameters and values of the parameters provided; otherwise, the answerer MUST reject or not participate in the session. It falls on the creator of the session to use values that are expected to be supported by the receiving application.

IANA considerations This memo contains three considerations to IANA: new media type, new SDP attribute and new grouping type.

V3C media type registration A new media type will be registered with IANA; see .

V3C format parameters SDP attribute This document defines a new session and media level SDP attribute: "v3cfmtp". This attribute will be registered by IANA under attribute-field names (<attribute-name>) registry in Session Description Protocol (SDP). The "v3cfmtp" attribute is used to convey V3C specific media format parameters for any media line. Its format is defined in . Further semantics are provided in . Additional details for <attribute-name> Registry

Type	SDP Name	Usage Level	Mux Category	Reference
attribute	v3cfmtp	session, media	NORMAL	"this memo"

RFC-EDITOR: Please replace "this memo" with the published RFC number.

V3C grouping type extension Grouping is extended to establish relationships between substreams of a V3C representation. A new group type (V3C) for the group attribute will be registered as defined in . This document registers the semantics in with IANA in the "Semantics for the 'group' SDP Attribute" registry (under the "Session Description Protocol (SDP) Parameters" registry group): Additional semantics for V3C SDP group type

Semantics	Token	Mux Category	Reference
V3C grouping	V3C	NORMAL	"this memo"

RFC-EDITOR: Please replace "this memo" with the published RFC number.

Security considerations RTP packets using the payload format defined in this specification are subject to the security considerations discussed in the RTP specification , and in any applicable RTP profile such as RTP/AVP , RTP/AVPF , RTP/SAVP , or RTP/SAVPF . However, as "Securing the RTP Protocol Framework: Why RTP Does Not Mandate a Single Media Security Solution" discusses, it is not an RTP payload format's responsibility to discuss or mandate what solutions are used to meet the basic security goals like confidentiality, integrity, and source authenticity for RTP in general. This responsibility lies with anyone using RTP in an application. They can find guidance on available security mechanisms and important considerations in "Options for Securing RTP Sessions" . Applications SHOULD use one or more appropriate strong security mechanisms. The rest of this Security Considerations section discusses the security impacting properties of the payload format itself. This RTP payload format and its media decoder do not exhibit any significant non-uniformity in the receiver-side computational complexity for packet processing, and thus are unlikely to pose a denial-of-service threat due to the receipt of pathological data. Nor does the RTP payload format contain any active content. Components of a system using this media type SHALL NOT construct RTP payloads that contain executable content. The implementer of the RTP payload format SHALL guarantee that the received content is properly depacketized and fed to a V3C standard compliant decoder. What the receiver does with the decoded bitstream is unspecified.

References Normative References ISO/IEC ISO/IEC In many standards track documents several words are used to signify the requirements in the specification. These words are often capitalized. This document defines these words as they should be interpreted in IETF documents. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements. This document defines a mechanism by which two entities can make use of the Session Description Protocol (SDP) to arrive at a common view of a multimedia session between them. In the model, one participant offers the other a description of the desired session from their perspective, and the other participant answers with the desired session from their perspective. This offer/answer model is most useful in unicast sessions where information from both participants is needed for the complete view of the session. The offer/answer model is used by protocols like the Session Initiation Protocol (SIP). [STANDARDS-TRACK] This memorandum describes RTP, the real-time transport protocol. RTP provides end-to-end network transport functions suitable for applications transmitting real-time data, such as audio, video or simulation data, over multicast or unicast network services. RTP does not address resource reservation and does not guarantee quality-of- service for real-time services. The data transport is augmented by a control protocol (RTCP) to allow monitoring of the data delivery in a manner scalable to large multicast networks, and to provide minimal control and identification functionality. RTP and RTCP are designed to be independent of the underlying transport and network layers. The protocol supports the use of RTP-level translators and mixers. Most of the text in this memorandum is identical to RFC 1889 which it obsoletes. There are no changes in the packet formats on the wire, only changes to the rules and algorithms governing how the protocol is used. The biggest change is an enhancement to the scalable timer algorithm for calculating when to send RTCP packets in order to minimize transmission in excess of the intended rate when many participants join a session simultaneously. [STANDARDS-TRACK] This document describes the commonly used base 64, base 32, and base 16 encoding schemes. It also discusses the use of line-feeds in encoded data, use of padding in encoded data, use of non-alphabet characters in encoded data, use of different encoding alphabets, and canonical encodings. [STANDARDS-TRACK] In this specification, we define a framework to group "m" lines in the Session Description Protocol (SDP) for different purposes. This framework uses the "group" and "mid" SDP attributes, both of which are defined in this specification. Additionally, we specify how to use the framework for two different purposes: for lip synchronization and for receiving a media flow consisting of several media streams on different transport addresses. This document obsoletes RFC 3388. [STANDARDS-TRACK] The Real-time Transport Protocol (RTP) is widely used in telephony, video conferencing, and telepresence applications. Such applications are often run on best-effort UDP/IP networks. If congestion control is not implemented in these applications, then network congestion can lead to uncontrolled packet loss and a resulting deterioration of the user's multimedia experience. The congestion control algorithm acts as a safety measure by stopping RTP flows from using excessive resources and protecting the network from overload. At the time of this writing, however, while there are several proprietary solutions, there is no standard algorithm for congestion control of interactive RTP flows. This document does not propose a congestion control algorithm. It instead defines a minimal set of RTP circuit breakers: conditions under which an RTP sender needs to stop transmitting media data to protect the network from excessive congestion. It is expected that, in the absence of long-lived excessive congestion, RTP applications running on best-effort IP networks will be able to operate without triggering these circuit breakers. To avoid triggering the RTP circuit breaker, any Standards Track congestion control algorithms defined for RTP will need to operate within the envelope set by these RTP circuit breaker algorithms. RFC 2119 specifies common key words that may be used in protocol specifications. This document aims to reduce the ambiguity by clarifying that only UPPERCASE usage of the key words have the defined special meanings. This specification defines a new Session Description Protocol (SDP) Grouping Framework extension called 'BUNDLE'. The extension can be used with the SDP offer/answer mechanism to negotiate the usage of a single transport (5-tuple) for sending and receiving media described by multiple SDP media descriptions ("m=" sections). Such transport is referred to as a "BUNDLE transport", and the media is referred to as "bundled media". The "m=" sections that use the BUNDLE transport form a BUNDLE group. This specification defines a new RTP Control Protocol (RTCP) Source Description (SDES) item and a new RTP header extension. This specification updates RFCs 3264, 5888, and 7941. This specification obsoletes RFC 8843. This memo defines the Session Description Protocol (SDP). SDP is intended for describing multimedia sessions for the purposes of session announcement, session invitation, and other forms of multimedia session initiation. This document obsoletes RFC 4566. Informative References ISO/IEC ISO/IEC ISO/IEC ISO/IEC ISO/IEC This document describes a profile called "RTP/AVP" for the use of the real-time transport protocol (RTP), version 2, and the associated control protocol, RTCP, within audio and video multiparticipant conferences with minimal control. It provides interpretations of generic fields within the RTP specification suitable for audio and video conferences. In particular, this document defines a set of default mappings from payload type numbers to encodings. This document also describes how audio and video data may be carried within RTP. It defines a set of standard encodings and their names when used within RTP. The descriptions provide pointers to reference implementations and the detailed standards. This document is meant as an aid for implementors of audio, video and other real-time multimedia applications. This memorandum obsoletes RFC 1890. It is mostly backwards-compatible except for functions removed because two interoperable implementations were not found. The additions to RFC 1890 codify existing practice in the use of payload formats under this profile and include new payload formats defined since RFC 1890 was published. [STANDARDS-TRACK] This document describes the Secure Real-time Transport Protocol (SRTP), a profile of the Real-time Transport Protocol (RTP), which can provide confidentiality, message authentication, and replay protection to the RTP traffic and to the control traffic for RTP, the Real-time Transport Control Protocol (RTCP). [STANDARDS-TRACK] Real-time media streams that use RTP are, to some degree, resilient against packet losses. Receivers may use the base mechanisms of the Real-time Transport Control Protocol (RTCP) to report packet reception statistics and thus allow a sender to adapt its transmission behavior in the mid-term. This is the sole means for feedback and feedback-based error repair (besides a few codec-specific mechanisms). This document defines an extension to the Audio-visual Profile (AVP) that enables receivers to provide, statistically, more immediate feedback to the senders and thus allows for short-term adaptation and efficient feedback-based repair mechanisms to be implemented. This early feedback profile (AVPF) maintains the AVP bandwidth constraints for RTCP and preserves scalability to large groups. [STANDARDS-TRACK] An RTP profile (SAVP) for secure real-time communications and another profile (AVPF) to provide timely feedback from the receivers to a sender are defined in RFC 3711 and RFC 4585, respectively. This memo specifies the combination of both profiles to enable secure RTP communications with feedback. [STANDARDS-TRACK] This memo describes an RTP Payload format for the ITU-T Recommendation H.264 video codec and the technically identical ISO/IEC International Standard 14496-10 video codec, excluding the Scalable Video Coding (SVC) extension and the Multiview Video Coding extension, for which the RTP payload formats are defined elsewhere. The RTP payload format allows for packetization of one or more Network Abstraction Layer Units (NALUs), produced by an H.264 video encoder, in each RTP payload. The payload format has wide applicability, as it supports applications from simple low bitrate conversational usage, to Internet video streaming with interleaved transmission, to high bitrate video-on-demand. This memo obsoletes RFC 3984. Changes from RFC 3984 are summarized in Section 14. Issues on backward compatibility to RFC 3984 are discussed in Section 15. [STANDARDS-TRACK] 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. [STANDARDS-TRACK] The Real-time Transport Protocol (RTP) is used in a large number of different application domains and environments. This heterogeneity implies that different security mechanisms are needed to provide services such as confidentiality, integrity, and source authentication of RTP and RTP Control Protocol (RTCP) packets suitable for the various environments. The range of solutions makes it difficult for RTP-based application developers to pick the most suitable mechanism. This document provides an overview of a number of security solutions for RTP and gives guidance for developers on how to choose the appropriate security mechanism. This memo discusses the problem of securing real-time multimedia sessions. It also explains why the Real-time Transport Protocol (RTP) and the associated RTP Control Protocol (RTCP) do not mandate a single media security mechanism. This is relevant for designers and reviewers of future RTP extensions to ensure that appropriate security mechanisms are mandated and that any such mechanisms are specified in a manner that conforms with the RTP architecture. This memo describes an RTP payload format for the video coding standard ITU-T Recommendation H.265 and ISO/IEC International Standard 23008-2, both also known as High Efficiency Video Coding (HEVC) and developed by the Joint Collaborative Team on Video Coding (JCT-VC). 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 into multiple RTP packets. Furthermore, it supports transmission of an HEVC bitstream over a single stream as well as multiple RTP streams. When multiple RTP streams are used, a single transport or multiple transports may be utilized. The payload format has wide applicability in videoconferencing, Internet video streaming, and high-bitrate entertainment-quality video, among others.