MPEG news: a report from the 133rd meeting (virtual)

The original blog post can be found at the Bitmovin Techblog and has been modified/updated to focus on and highlight research aspects. Additionally, this version of the blog post will also be posted at ACM SIGMM Records.

MPEG News Archive

MPEG Systems File Format Subgroup wins Technology & Engineering Emmy® Award

The 133rd MPEG meeting was once again held as an online meeting, and this time, kicked off with great news, that MPEG is one of the organizations honored as a 72nd Annual Technology & Engineering Emmy® Awards Recipient, specifically the MPEG Systems File Format Subgroup and its ISO Base Media File Format (ISOBMFF) et al.

The official press release can be found here and comprises the following items:

• 6th Emmy® Award for MPEG Technology: MPEG Systems File Format Subgroup wins Technology & Engineering Emmy® Award
• Essential Video Coding (EVC) verification test finalized
• MPEG issues a Call for Evidence on Video Coding for Machines
• Neural Network Compression for Multimedia Applications – MPEG calls for technologies for incremental coding of neural networks
• MPEG Systems reaches the first milestone for supporting Versatile Video Coding (VVC) and Essential Video Coding (EVC) in the Common Media Application Format (CMAF)
• MPEG Systems continuously enhances Dynamic Adaptive Streaming over HTTP (DASH)
• MPEG Systems reached the first milestone to carry event messages in tracks of the ISO Base Media File Format

In this report, I’d like to focus on ISOBMFF, EVC, CMAF, and DASH.

MPEG Systems File Format Subgroup wins Technology & Engineering Emmy® Award

MPEG is pleased to report that the File Format subgroup of MPEG Systems is being recognized this year by the National Academy for Television Arts and Sciences (NATAS) with a Technology & Engineering Emmy® for their 20 years of work on the ISO Base Media File Format (ISOBMFF). This format was first standardized in 1999 as part of the MPEG-4 Systems specification and is now in its 6th edition as ISO/IEC 14496-12. It has been used and adopted by many other specifications, e.g.:

• MP4 and 3GP file formats;
• Carriage of NAL unit structured video in the ISO Base Media File Format, which provides support for AVC, HEVC, VVC, EVC, and probably soon LCEVC;
• MPEG-21 file format;
• Dynamic Adaptive Streaming over HTTP (DASH) and Common Media Application Format (CMAF);
• High-Efficiency Image Format (HEIF);
• Timed text and other visual overlays in ISOBMFF;
• Common encryption format;
• Carriage of timed metadata metrics of media;
• Derived visual tracks;
• Event message track format;
• Carriage of uncompressed video;
• Omnidirectional Media Format (OMAF);
• Carriage of visual volumetric video-based coding data;
• Carriage of geometry-based point cloud compression data;
• … to be continued!

This is MPEG’s fourth Technology & Engineering Emmy® Award (after MPEG-1 and MPEG-2 together with JPEG in 1996, Advanced Video Coding (AVC) in 2008, and MPEG-2 Transport Stream in 2013) and sixth overall Emmy® Award, including the Primetime Engineering Emmy® Awards for Advanced Video Coding (AVC) High Profile in 2008 and High-Efficiency Video Coding (HEVC) in 2017, respectively.

Essential Video Coding (EVC) verification test finalized

At the 133rd MPEG meeting, a verification testing assessment of the Essential Video Coding (EVC) standard was completed. The first part of the EVC verification test using high dynamic range (HDR) and wide color gamut (WCG) was completed at the 132nd MPEG meeting. A subjective quality evaluation was conducted comparing the EVC Main profile to the HEVC Main 10 profile and the EVC Baseline profile to AVC High 10 profile, respectively:

• Analysis of the subjective test results showed that the average bitrate savings for EVC Main profile are approximately 40% compared to HEVC Main 10 profile, using UHD and HD SDR content encoded in both random access and low delay configurations.
• The average bitrate savings for the EVC Baseline profile compared to the AVC High 10 profile is approximately 40% using UHD SDR content encoded in the random-access configuration and approximately 35% using HD SDR content encoded in the low delay configuration.
• Verification test results using HDR content had shown average bitrate savings for EVC Main profile of approximately 35% compared to HEVC Main 10 profile.

By providing significantly improved compression efficiency compared to HEVC and earlier video coding standards while encouraging the timely publication of licensing terms, the MPEG-5 EVC standard is expected to meet the market needs of emerging delivery protocols and networks, such as 5G, enabling the delivery of high-quality video services to an ever-growing audience.

In addition to verification tests, EVC, along with VVC and CMAF were subject to further improvements to their support systems.

Research aspects: as for every new video codec, its compression efficiency and computational complexity are important performance metrics. Additionally, the availability of (efficient) open-source implementations (i.e., x264, x265, soon x266, VVenC, aomenc, et al., etc.) are vital for its adoption in the (academic) research community.

MPEG Systems reaches the first milestone for supporting Versatile Video Coding (VVC) and Essential Video Coding (EVC) in the Common Media Application Format (CMAF)

At the 133rd MPEG meeting, MPEG Systems promoted Amendment 2 of the Common Media Application Format (CMAF) to Committee Draft Amendment (CDAM) status, the first major milestone in the ISO/IEC approval process. This amendment defines:

• constraints to (i) Versatile Video Coding (VVC) and (ii) Essential Video Coding (EVC) video elementary streams when carried in a CMAF video track;
• codec parameters to be used for CMAF switching sets with VVC and EVC tracks; and
• support of the newly introduced MPEG-H 3D Audio profile.

It is expected to reach its final milestone in early 2022. For research aspects related to CMAF, the reader is referred to the next section about DASH.

MPEG Systems continuously enhances Dynamic Adaptive Streaming over HTTP (DASH)

At the 133rd MPEG meeting, MPEG Systems promoted Part 8 of Dynamic Adaptive Streaming over HTTP (DASH), also referred to as “Session-based DASH,” to its final stage of standardization (i.e., Final Draft International Standard (FDIS)).

Historically, in DASH, every client uses the same Media Presentation Description (MPD), as it best serves the service's scalability. However, there have been increasing requests from the industry to enable customized manifests for enabling personalized services. MPEG Systems has standardized a solution to this problem without sacrificing scalability. Session-based DASH adds a mechanism to the MPD to refer to another document, called Session-based Description (SBD), allowing per-session information. The DASH client can use this information (i.e., variables and their values) provided in the SBD to derive the URLs for HTTP GET requests.

An updated overview of DASH standards/features can be found in the Figure below.

MPEG DASH Status as of January 2021.

Research aspects: CMAF is mostly like becoming the main segment format to be used in the context of HTTP adaptive streaming (HAS) and, thus, also DASH (hence also the name common media application format). Supporting a plethora of media coding formats will inevitably result in a multi-codec dilemma that needs to be addressed soon as there will be no flag day where everyone will switch to a new coding format. Thus, designing efficient bitrate ladders for multi-codec delivery will an interesting research aspect, which needs to include device/player support (i.e., some devices/player will support only a subset of available codecs), storage capacity/costs within the cloud as well as within the delivery network, and network distribution capacity/costs (i.e., CDN costs).

The 134th MPEG meeting will be again an online meeting in April 2021. Click here for more information about MPEG meetings and their developments.

MPEG news: a report from the 132nd meeting (virtual)

The original blog post can be found at the Bitmovin Techblog and has been modified/updated here to focus on and highlight research aspects. Additionally, this version of the blog post will be also posted at ACM SIGMM Records.

MPEG News Archive

The 132nd MPEG meeting was the first meeting with the new structure. That is, ISO/IEC JTC 1/SC 29/WG 11 -- the official name of MPEG under the ISO structure -- was disbanded after the 131st MPEG meeting and some of the subgroups of WG 11 (MPEG) have been elevated to independent MPEG Working Groups (WGs) and Advisory Groups (AGs) of SC 29 rather than subgroups of the former WG 11. Thus, the MPEG community is now an affiliated group of WGs and AGs that will continue meeting together according to previous MPEG meeting practices and will further advance the standardization activities of the MPEG work program.

The 132nd MPEG meeting was the first meeting with the new structure as follows (incl. Convenors and position within WG 11 structure):

• AG 2 MPEG Technical Coordination (Convenor: Prof. Jörn Ostermann; for overall MPEG work coordination and prev. known as the MPEG chairs meeting; it’s expected that one can also provide inputs to this AG without being a member of this AG)
• WG 2 MPEG Technical Requirements (Convenor Dr. Igor Curcio; former Requirements subgroup)
• WG 3 MPEG Systems (Convenor: Dr. Youngkwon Lim; former Systems subgroup)
• WG 4 MPEG Video Coding (Convenor: Prof. Lu Yu; former Video subgroup)
• WG 5 MPEG Joint Video Coding Team(s) with ITU-T SG 16 (Convenor: Prof. Jens-Rainer Ohm; former JVET)
• WG 6 MPEG Audio Coding (Convenor: Dr. Schuyler Quackenbush; former Audio subgroup)
• WG 7 MPEG Coding of 3D Graphics (Convenor: Prof. Marius Preda, former 3DG subgroup)
• WG 8 MPEG Genome Coding (Convenor: Prof. Marco Mattaveli; newly established WG)
• AG 3 MPEG Liaison and Communication (Convenor: Prof. Kyuheon Kim; (former Communications subgroup)
• AG 5 MPEG Visual Quality Assessment (Convenor: Prof. Mathias Wien; former Test subgroup).

The 132nd MPEG meeting was held as an online meeting and more than 300 participants continued to work efficiently on standards for the future needs of the industry. As a group, MPEG started to explore new application areas that will benefit from standardized compression technology in the future. A new web site has been created and can be found at http://mpeg.org/.

The official press release can be found here and comprises the following items:

• Versatile Video Coding (VVC) Ultra-HD Verification Test Completed and Conformance and Reference Software Standards Reach their First Milestone
• MPEG Completes Geometry-based Point Cloud Compression (G-PCC) Standard
• MPEG Evaluates Extensions and Improvements to MPEG-G and Announces a Call for Evidence on New Advanced Genomics Features and Technologies
• MPEG Issues Draft Call for Proposals on the Coded Representation of Haptics
• MPEG Evaluates Responses to MPEG IPR Smart Contracts CfP
• MPEG Completes Standard on Harmonization of DASH and CMAF
• MPEG Completes 2nd Edition of the Omnidirectional Media Format (OMAF)
• MPEG Completes the Low Complexity Enhancement Video Coding (LCEVC) Standard

In this report, I’d like to focus on VVC, G-PCC, DASH/CMAF, OMAF, and LCEVC.

Versatile Video Coding (VVC) Ultra-HD Verification Test Completed and Conformance & Reference Software Standards Reach their First Milestone

MPEG completed a verification testing assessment of the recently ratified Versatile Video Coding (VVC) standard for ultra-high definition (UHD) content with standard dynamic range, as may be used in newer streaming and broadcast television applications. The verification test was performed using rigorous subjective quality assessment methods and showed that VVC provides a compelling gain over its predecessor -- the High Efficiency Video Coding (HEVC) standard produced in 2013. In particular, the verification test was performed using the VVC reference software implementation (VTM) and the recently released open-source encoder implementation of VVC (VVenC):

• Using its reference software implementation (VTM), VVC showed bit rate savings of roughly 45% over HEVC for comparable subjective video quality.
• Using VVenC, additional bit rate savings of more than 10% relative to VTM were observed, which at the same time runs significantly faster than the reference software implementation.

Additionally, the standardization work for both conformance testing and reference software for the VVC standard reached its first major milestone, i.e., progressing to the Committee Draft ballot in the ISO/IEC approval process. The conformance testing standard (ISO/IEC 23090-15) will ensure interoperability among the diverse applications that use the VVC standard, and the reference software standard (ISO/IEC 23090-16) will provide an illustration of the capabilities of VVC and a valuable example showing how the standard can be implemented. The reference software will further facilitate the adoption of the standard by being available for use as the basis of product implementations.

Research aspects: as for every new video codec, its compression efficiency and computational complexity are important performance metrics. While the reference software (VTM) provides a valid reference in terms of compression efficiency it is not optimized for runtime. VVenC seems to provide already a significant improvement and with x266 another open source implementation will be available soon. Together with AOMedia's AV1 (including its possible successor AV2) we are looking forward to a lively future in the area of video codecs.

MPEG Completes Geometry-based Point Cloud Compression Standard

MPEG promoted its ISO/IEC 23090-9 Geometry-based Point Cloud Compression (G-PCC) standard to the Final Draft International Standard (FDIS) stage. G-PCC addresses lossless and lossy coding of time-varying 3D point clouds with associated attributes such as color and material properties. This technology is particularly suitable for sparse point clouds. ISO/IEC 23090-5 Video-based Point Cloud Compression (V-PCC), which reached the FDIS stage in July 2020, addresses the same problem but for dense point clouds, by projecting the (typically dense) 3D point clouds onto planes, and then processing the resulting sequences of 2D images using video compression techniques. The generalized approach of G-PCC, where the 3D geometry is directly coded to exploit any redundancy in the point cloud itself, is complementary to V-PCC and particularly useful for sparse point clouds representing large environments.

Point clouds are typically represented by extremely large amounts of data, which is a significant barrier to mass-market applications. However, the relative ease of capturing and rendering spatial information compared to other volumetric video representations makes point clouds increasingly popular for displaying immersive volumetric data. The current draft reference software implementation of a lossless, intra-frame G‐PCC encoder provides a compression ratio of up to 10:1 and lossy coding of acceptable quality for a variety of applications with a ratio of up to 35:1.

By providing high immersion at currently available bit rates, the G‐PCC standard will enable various applications such as 3D mapping, indoor navigation, autonomous driving, advanced augmented reality (AR) with environmental mapping, and cultural heritage.

Research aspects: the main research focus related to G-PCC and V-PCC is currently on compression efficiency but one should not dismiss its delivery aspects including its dynamic, adaptive streaming. A recent paper on this topic has been published in the IEEE Communications Magazine and is entitled "From Capturing to Rendering: Volumetric Media Delivery With Six Degrees of Freedom".

MPEG Finalizes the Harmonization of DASH and CMAF

MPEG successfully completed the harmonization of Dynamic Adaptive Streaming over HTTP (DASH) with Common Media Application Format (CMAF) featuring a DASH profile for the use with CMAF (as part of the 1st Amendment of ISO/IEC 23009-1:2019 4th edition).

CMAF and DASH segments are both based on the ISO Base Media File Format (ISOBMFF), which per se enables smooth integration of both technologies. Most importantly, this DASH profile defines (a) a normative mapping of CMAF structures to DASH structures and (b) how to use Media Presentation Description (MPD) as a manifest format.

Additional tools added to this amendment include

• DASH events and timed metadata track timing and processing models with in-band event streams,
• a method for specifying the resynchronization points of segments when the segments have internal structures that allow container-level resynchronization,
• an MPD patch framework that allows the transmission of partial MPD information as opposed to the complete MPD using the XML patch framework as defined in IETF RFC 5261, and
• content protection enhancements for efficient signaling.

It is expected that the 5th edition of the MPEG DASH standard (ISO/IEC 23009-1) containing this change will be issued at the 133rd MPEG meeting in January 2021. An overview of DASH standards/features can be found in the Figure below.

Research aspects: one of the features enabled by CMAF is low latency streaming that is actively researched within the multimedia systems community (e.g., here). The main research focus has been related to the ABR logic while its impact on the network is not yet fully understood and requires strong collaboration among stakeholders along the delivery path including ingest, encoding, packaging, (encryption), content delivery network (CDN), and consumption. A holistic view on ABR is needed to enable innovation and the next step towards the future generation of streaming technologies (https://athena.itec.aau.at/). 

MPEG Completes 2nd Edition of the Omnidirectional Media Format

MPEG completed the standardization of the 2nd edition of the Omnidirectional MediA Format (OMAF) by promoting ISO/IEC 23009-2 to Final Draft International Standard (FDIS) status including the following features:

• “Late binding” technologies to deliver and present only that part of the content that adapts to the dynamically changing users' viewpoint. To enable an efficient implementation of such a feature, this edition of the specification introduces the concept of bitstream rewriting, in which a compliant bitstream is dynamically generated that, by combining the received portions of the bitstream, covers only the users' viewport on the client.
• Extension of OMAF beyond 360-degree video. This edition introduces the concept of viewpoints, which can be considered as user-switchable camera positions for viewing content or as temporally contiguous parts of a storyline to provide multiple choices for the storyline a user can follow.
• Enhances the use of video, image, or timed text overlays on top of omnidirectional visual background video or images related to a sphere or a viewport.

Research aspects: standards usually define formats to enable interoperability but various informative aspects are left open for industry competition and subject to research and development. The same holds for OMAF and its 2nd edition enables researchers and developers to work towards efficient viewport-adaptive implementations focusing on the users' viewport.

MPEG Completes the Low Complexity Enhancement Video Coding Standard

MPEG is pleased to announce the completion of the new ISO/IEC 23094-2 standard, i.e., Low Complexity Enhancement Video Coding (MPEG-5 Part 2 LCEVC), which has been promoted to Final Draft International Standard (FDIS) at the 132nd MPEG meeting.

• LCEVC adds an enhancement data stream that can appreciably improve the resolution and visual quality of reconstructed video with an effective compression efficiency of limited complexity by building on top of existing and future video codecs.
• LCEVC can be used to complement devices originally designed only for decoding the base layer bitstream, by using firmware, operating system, or browser support. It is designed to be compatible with existing video workflows (e.g., CDNs, metadata management, DRM/CA) and network protocols (e.g., HLS, DASH, CMAF) to facilitate the rapid deployment of enhanced video services.
• LCEVC can be used to deliver higher video quality in limited bandwidth scenarios, especially when the available bit rate is low for high-resolution video delivery and decoding complexity is a challenge. Typical use cases include mobile streaming and social media, and services that benefit from high-density/low-power transcoding.

Research aspects: LCEVC provides a kind of scalable video coding by combining hardware- and software-based decoders that allows for a certain flexibility as part of regular software life cycle updates. However, LCEVC has been never compared to Scalable Video Coding (SVC) and Scalable High Efficiency Video Coding (SHVC) which could be an interesting aspect for future work.

The 133rd MPEG meeting will be again an online meeting in January 2021.

Click here for more information about MPEG meetings and their developments.

MPEG news: a report from the 131st meeting (virtual)

The original blog post can be found at the Bitmovin Techblog and has been modified/updated here to focus on and highlight research aspects. Additionally, this version of the blog post will be also posted at ACM SIGMM Records.

MPEG News Archive

The 131st MPEG meeting concluded on July 3, 2020, online, again but with a press release comprising an impressive list of news items which is led by

MPEG Announces VVC – the Versatile Video Coding Standard

Just in the middle of the SC29 (i.e., MPEG’s parent body within ISO) restructuring process, MPEG successfully ratified -- jointly with ITU-T’s VCEG within JVET -- its next-generation video codec among other interesting results from the 131st MPEG meeting:

Standards progressing to final approval ballot (FDIS)

• MPEG Announces VVC – the Versatile Video Coding Standard
• Point Cloud Compression – MPEG promotes a Video-based Point Cloud Compression Technology to the FDIS stage
• MPEG-H 3D Audio – MPEG promotes Baseline Profile for 3D Audio to the final stage

Call for Proposals

• Call for Proposals on Technologies for MPEG-21 Contracts to Smart Contracts Conversion
• MPEG issues a Call for Proposals on extension and improvements to ISO/IEC 23092 standard series

Standards progressing to the first milestone of the ISO standard development process

• Widening support for storage and delivery of MPEG-5 EVC
• Multi-Image Application Format adds support of HDR
• Carriage of Geometry-based Point Cloud Data progresses to Committee Draft
• MPEG Immersive Video (MIV) progresses to Committee Draft
• Neural Network Compression for Multimedia Applications – MPEG progresses to Committee Draft
• MPEG issues Committee Draft of Conformance and Reference Software for Essential Video Coding (EVC)

The corresponding press release of the 131st MPEG meeting can be found here: https://mpeg-standards.com/meetings/mpeg-131/. This report focused on video coding featuring VVC as well as PCC and systems aspects (i.e., file format, DASH).

MPEG Announces VVC – the Versatile Video Coding Standard

MPEG is pleased to announce the completion of the new Versatile Video Coding (VVC) standard at its 131st meeting. The document has been progressed to its final approval ballot as ISO/IEC 23090-3 and will also be known as H.266 in the ITU-T.

VVC Architecture (from IEEE ICME 2020 tutorial of Mathias Wien and Benjamin Bross)

VVC is the latest in a series of very successful standards for video coding that have been jointly developed with ITU-T, and it is the direct successor to the well-known and widely used High Efficiency Video Coding (HEVC) and Advanced Video Coding (AVC) standards (see architecture in the figure above). VVC provides a major benefit in compression over HEVC. Plans are underway to conduct a verification test with formal subjective testing to confirm that VVC achieves an estimated 50% bit rate reduction versus HEVC for equal subjective video quality. Test results have already demonstrated that VVC typically provides about a 40%-bit rate reduction for 4K/UHD video sequences in tests using objective metrics (i.e., PSNR, VMAF, MS-SSIM). Application areas especially targeted for the use of VVC include

• ultra-high definition 4K and 8K video,
• video with a high dynamic range and wide colour gamut, and
• video for immersive media applications such as 360° omnidirectional video.

Furthermore, VVC is designed for a wide variety of types of video such as camera captured, computer-generated, and mixed content for screen sharing, adaptive streaming, game streaming, video with scrolling text, etc. Conventional standard-definition and high-definition video content are also supported with similar gains in compression. In addition to improving coding efficiency, VVC also provides highly flexible syntax supporting such use cases as (i) subpicture bitstream extraction, (ii) bitstream merging, (iii) temporal sublayering, and (iv) layered coding scalability.

The current performance of VVC compared to HEVC-HM is shown in the figure below which confirms the statement above but also highlights the increased complexity. Please note that VTM9 is not optimized for speed but functionality (i.e., compression efficiency).

Performance of VVC, VTM9 vs. HM (taken from https://bit.ly/mpeg131).

MPEG also announces completion of ISO/IEC 23002-7 “Versatile supplemental enhancement information for coded video bitstreams” (VSEI), developed jointly with ITU-T as Rec. ITU-T H.274. The new VSEI standard specifies the syntax and semantics of video usability information (VUI) parameters and supplemental enhancement information (SEI) messages for use with coded video bitstreams. VSEI is especially intended for use with VVC, although it is drafted to be generic and flexible so that it may also be used with other types of coded video bitstreams. Once specified in VSEI, different video coding standards and systems-environment specifications can re-use the same SEI messages without the need for defining special-purpose data customized to the specific usage context.

At the same time, the Media Coding Industry Forum (MC-IF) announces a VVC patent pool fostering with an initial meeting on September 1, 2020. The aim of this meeting is to identify tasks and to propose a schedule for VVC pool fostering with the goal to select a pool facilitator/administrator by the end of 2020. MC-IF is not facilitating or administering a patent pool.

At the time of writing this blog post, it is probably too early to make an assessment of whether VVC will share the fate of HEVC or AVC (w.r.t. patent pooling). AVC is still the most widely used video codec but with AVC, HEVC, EVC, VVC, LCEVC, AV1, (AV2), and probably also AVS3 -- did I miss anything? -- the competition and pressure are certainly increasing.

Research aspects: from a research perspective, reduction of time-complexity (for a variety of use cases) while maintaining quality and bitrate at acceptable levels is probably the most relevant aspect. Improvements in individual building blocks of VVC by using artificial neural networks (ANNs) are another area of interest but also end-to-end aspects of video coding using ANNs will probably pave the roads towards the/a next generation of video codec(s). Utilizing VVC and its features for HTTP adaptive streaming (HAS) is probably most interesting for me but maybe also for others...

MPEG promotes a Video-based Point Cloud Compression Technology to the FDIS stage

At its 131st meeting, MPEG promoted its Video-based Point Cloud Compression (V-PCC) standard to the Final Draft International Standard (FDIS) stage. V-PCC addresses lossless and lossy coding of 3D point clouds with associated attributes such as colors and reflectance. Point clouds are typically represented by extremely large amounts of data, which is a significant barrier for mass-market applications. However, the relative ease to capture and render spatial information as point clouds compared to other volumetric video representations makes point clouds increasingly popular to present immersive volumetric data. With the current V-PCC encoder implementation providing compression in the range of 100:1 to 300:1, a dynamic point cloud of one million points could be encoded at 8 Mbit/s with good perceptual quality. Real-time decoding and rendering of V-PCC bitstreams have also been demonstrated on current mobile hardware.

The V-PCC standard leverages video compression technologies and the video ecosystem in general (hardware acceleration, transmission services, and infrastructure) while enabling new kinds of applications. The V-PCC standard contains several profiles that leverage existing AVC and HEVC implementations, which may make them suitable to run on existing and emerging platforms. The standard is also extensible to upcoming video specifications such as Versatile Video Coding (VVC) and Essential Video Coding (EVC).

The V-PCC standard is based on Visual Volumetric Video-based Coding (V3C), which is expected to be re-used by other MPEG-I volumetric codecs under development. MPEG is also developing a standard for the carriage of V-PCC and V3C data (ISO/IEC 23090-10) which has been promoted to DIS status at the 130th MPEG meeting.

By providing high-level immersiveness at currently available bandwidths, the V-PCC standard is expected to enable several types of applications and services such as six Degrees of Freedom (6 DoF) immersive media, virtual reality (VR) / augmented reality (AR), immersive real-time communication and cultural heritage.

Research aspects: as V-PCC is video-based, we can probably state similar research aspects as for video codecs such as improving efficiency both for encoding and rendering as well as reduction of time complexity. During the development of V-PCC mainly HEVC (and AVC) has/have been used but it is definitely interesting to use also VVC for PCC. Finally, the dynamic adaptive streaming of V-PCC data is still in its infancy despite some articles published here and there.

MPEG Systems related News

Finally, I’d like to share news related to MPEG systems and the carriage of video data as depicted in the figure below. In particular, the carriage of VVC (and also EVC) has been now enabled in MPEG-2 Systems (specifically within the transport stream) and in the various file formats (specifically within the NAL file format). The latter is used also in CMAF and DASH which makes VVC (and also EVC) ready for HTTP adaptive streaming (HAS).

Carriage of Video in MPEG Systems Standards (taken from https://bit.ly/mpeg131).

What about DASH and CMAF?

CMAF maintains a so-called "technologies under consideration" document which contains -- among other things -- a proposed VVC CMAF profile. Additionally, there are two exploration activities related to CMAF, i.e., (i) multi-stream support and (ii) storage, archiving, and content management for CMAF files.

DASH works on potential improvement for the first amendment to ISO/IEC 23009-1 4th edition related to CMAF support, events processing model, and other extensions. Additionally, there’s a working draft for a second amendment to ISO/IEC 23009-1 4th edition enabling bandwidth change signaling track and other enhancements. Furthermore, ISO/IEC 23009-8 (Session-based DASH operations) has been advanced to Draft International Standard (see also my last report).

An overview of the current status of MPEG-DASH can be found in the figure below.

The next meeting will be again an online meeting in October 2020.

Finally, MPEG organized a Webinar presenting results from the 131st MPEG meeting. The slides and video recordings are available here: https://bit.ly/mpeg131.

Click here for more information about MPEG meetings and their developments.

MPEG news: a report from the 129th meeting, Brussels, Belgium

The original blog post can be found at the Bitmovin Techblog and has been modified/updated here to focus on and highlight research aspects. Additionally, this version of the blog post will be also posted at ACM SIGMM Records.

MPEG News Archive

The 129th MPEG meeting concluded on January 17, 2020 in Brussels, Belgium with the following topics:

• Coded representation of immersive media – WG11 promotes Network-Based Media Processing (NBMP) to the final stage
• Coded representation of immersive media – Publication of the Technical Report on Architectures for Immersive Media
• Genomic information representation – WG11 receives answers to the joint call for proposals on genomic annotations in conjunction with ISO TC 276/WG 5
• Open font format – WG11 promotes Amendment of Open Font Format to the final stage
• High efficiency coding and media delivery in heterogeneous environments – WG11 progresses Baseline Profile for MPEG-H 3D Audio
• Multimedia content description interface – Conformance and Reference Software for Compact Descriptors for Video Analysis promoted to the final stage

Additional Important Activities at the 129th WG 11 (MPEG) meeting

The 129th WG 11 (MPEG) meeting was attended by more than 500 experts from 25 countries working on important activities including (i) a scene description for MPEG media, (ii) the integration of Video-based Point Cloud Compression (V-PCC) and Immersive Video (MIV), (iii) Video Coding for Machines (VCM), and (iv) a draft call for proposals for MPEG-I Audio among others.

The corresponding press release of the 129th MPEG meeting can be found here: https://mpeg.chiariglione.org/meetings/129. This report focused on network-based media processing (NBMP), architectures of immersive media, compact descriptors for video analysis (CDVA), and an update about adaptive streaming formats (i.e., DASH and CMAF).

MPEG picture at friday plenary; © Rob Koenen (Tiledmedia).

Coded representation of immersive media – WG11 promotes Network-Based Media Processing (NBMP) to the final stage

At its 129th meeting, MPEG promoted ISO/IEC 23090-8, Network-Based Media Processing (NBMP), to Final Draft International Standard (FDIS). The FDIS stage is the final vote before a document is officially adopted as an International Standard (IS). During the FDIS vote, publications and national bodies are only allowed to place a Yes/No vote and are no longer able to make any technical changes. However, project editors are able to fix typos and make other necessary editorial improvements.

What is NBMP? The NBMP standard defines a framework that allows content and service providers to describe, deploy, and control media processing for their content in the cloud by using libraries of pre-built 3rd party functions. The framework includes an abstraction layer to be deployed on top of existing commercial cloud platforms and is designed to be able to be integrated with 5G core and edge computing. The NBMP workflow manager is another essential part of the framework enabling the composition of multiple media processing tasks to process incoming media and metadata from a media source and to produce processed media streams and metadata that are ready for distribution to media sinks.

Why NBMP? With the increasing complexity and sophistication of media services and the incurred media processing, offloading complex media processing operations to the cloud/network is becoming critically important in order to keep receiver hardware simple and power consumption low.

Research aspects: NBMP reminds me a bit about what has been done in the past in MPEG-21, specifically Digital Item Adaptation (DIA) and Digital Item Processing (DIP). The main difference is that MPEG now targets APIs rather than pure metadata formats, which is a step forward in the right direction as APIs can be implemented and used right away. NBMP will be particularly interesting in the context of new networking approaches including, but not limited to, software-defined networking (SDN), information-centric networking (ICN), mobile edge computing (MEC), fog computing, and related aspects in the context of 5G.

Coded representation of immersive media – Publication of the Technical Report on Architectures for Immersive Media

At its 129th meeting, WG11 (MPEG) published an updated version of its technical report on architectures for immersive media. This technical report, which is the first part of the ISO/IEC 23090 (MPEG-I) suite of standards, introduces the different phases of MPEG-I standardization and gives an overview of the parts of the MPEG-I suite. It also documents use cases and defines architectural views on the compression and coded representation of elements of immersive experiences. Furthermore, it describes the coded representation of immersive media and the delivery of a full, individualized immersive media experience. MPEG-I enables scalable and efficient individual delivery as well as mass distribution while adjusting to the rendering capabilities of consumption devices. Finally, this technical report breaks down the elements that contribute to a fully immersive media experience and assigns quality requirements as well as quality and design objectives for those elements.

Research aspects: This technical report provides a kind of reference architecture for immersive media, which may help identify research areas and research questions to be addressed in this context.

Multimedia content description interface – Conformance and Reference Software for Compact Descriptors for Video Analysis promoted to the final stage

Managing and organizing the quickly increasing volume of video content is a challenge for many industry sectors, such as media and entertainment or surveillance. One example task is scalable instance search, i.e., finding content containing a specific object instance or location in a very large video database. This requires video descriptors that can be efficiently extracted, stored, and matched. Standardization enables extracting interoperable descriptors on different devices and using software from different providers so that only the compact descriptors instead of the much larger source videos can be exchanged for matching or querying. ISO/IEC 15938-15:2019 – the MPEG Compact Descriptors for Video Analysis (CDVA) standard – defines such descriptors. CDVA includes highly efficient descriptor components using features resulting from a Deep Neural Network (DNN) and uses predictive coding over video segments. The standard is being adopted by the industry. At its 129th meeting, WG11 (MPEG) has finalized the conformance guidelines and reference software. The software provides the functionality to extract, match, and index CDVA descriptors. For easy deployment, the reference software is also provided as Docker containers.

Research aspects: The availability of reference software helps to conduct reproducible research (i.e., reference software is typically publicly available for free) and the Docker container even further contributes to this aspect.

DASH and CMAF

The 4th edition of DASH has already been published and is available as ISO/IEC 23009-1:2019. Similar to previous iterations, MPEG’s goal was to make the newest edition of DASH publicly available for free, with the goal of industry-wide adoption and adaptation. During the most recent MPEG meeting, we worked towards implementing the first amendment which will include additional (i) CMAF support and (ii) event processing models with minor updates; these amendments are currently in draft and will be finalized at the 130th MPEG meeting in Alpbach, Austria. An overview of all DASH standards and updates are depicted in the figure below:

ISO/IEC 23009-8 or “session-based DASH operations” is the newest variation of MPEG-DASH. The goal of this part of DASH is to allow customization during certain times of a DASH session while maintaining the underlying media presentation description (MPD) for all other sessions. Thus, MPDs should be cacheable within content distribution networks (CDNs) while additional information should be customizable on a per session basis within a newly added session-based description (SBD). It is understood that the SBD should have an efficient representation to avoid file size issues and it should not duplicate information typically found in the MPD.

The 2nd edition of the CMAF standard (ISO/IEC 23000-19) will be available soon (currently under FDIS ballot) and MPEG is currently reviewing additional tools in the so-called ‘technologies under considerations’ document. Therefore, amendments were drafted for additional HEVC media profiles and exploration activities on the storage and archiving of CMAF contents.

The next meeting will bring MPEG back to Austria (for the 4th time) and will be hosted in Alpbach, Tyrol. For more information about the upcoming 130th MPEG meeting click here.

Click here for more information about MPEG meetings and their developments

MPEG news: a report from the 128th meeting, Geneva, Switzerland

The original blog post can be found at the Bitmovin Techblog and has been modified/updated here to focus on and highlight research aspects. Additionally, this version of the blog post will be also posted at ACM SIGMM Records.

MPEG News Archive

The 128th MPEG meeting concluded on October 11, 2019 in Geneva, Switzerland with the following topics:

• Low Complexity Enhancement Video Coding (LCEVC) Promoted to Committee Draft
• 2nd Edition of Omnidirectional Media Format (OMAF) has reached the first milestone
• Genomic Information Representation – Part 4 Reference Software and Part 5 Conformance Promoted to Draft International Standard

The corresponding press release of the 128th MPEG meeting can be found here: https://mpeg.chiariglione.org/meetings/128.

In this report we will focus on video coding aspects (i.e., LCEVC) and immersive media applications (i.e., OMAF). At the end, we will provide an update related to adaptive streaming (i.e., DASH and CMAF).

Low Complexity Enhancement Video Coding

Low Complexity Enhancement Video Coding (LCEVC) has been promoted to committee draft (CD) which is the first milestone in the ISO/IEC standardization process. LCEVC is part two of MPEG-5 or ISO/IEC 23094-2 if you prefer the always easy-to-remember ISO codes. We introduced MPEG-5 already in previous posts and LCEVC is about a standardized video coding solution that leverages other video codecs in a manner that improves video compression efficiency while maintaining or lowering the overall encoding and decoding complexity.

The LCEVC standard uses a lightweight video codec to add up to two layers of encoded residuals. The aim of these layers is correcting artefacts produced by the base video codec and adding detail and sharpness for the final output video.

The target of this standard comprises software or hardware codecs with extra processing capabilities, e.g., mobile devices, set top boxes (STBs), and personal computer based decoders. Additional benefits are the reduction in implementation complexity or a corresponding expansion in spatial resolution.

LCEVC is based on existing codecs which allows for backwards-compatibility with existing deployments. Supporting LCEVC enables “softwareized” video coding allowing for release and deployment options known from software-based solutions which are well understood by software companies and, thus, opens new opportunities in improving and optimizing video-based services and applications.

Research aspects: in video coding, research efforts are mainly related to coding efficiency and complexity (as usual). However, as MPEG-5 basically adds a software layer on top of what is typically implemented in hardware, all kind of aspects related to software engineering could become an active area of research.

Omnidirectional Media Format

The scope of the Omnidirectional Media Format (OMAF) is about 360° video, images, audio and associated timed text and specifies (i) a coordinate system, (ii) projection and rectangular region-wise packing methods, (iii) storage of omnidirectional media and the associated metadata using ISOBMFF, (iv) encapsulation, signaling and streaming of omnidirectional media in DASH and MMT, and (v) media profiles and presentation profiles.

At this meeting, the second edition of OMAF (ISO/IEC 23090-2) has been promoted to committee draft (CD) which includes

• support of improved overlay of graphics or textual data on top of video,
• efficient signaling of videos structured in multiple sub parts,
• enabling more than one viewpoint, and
• new profiles supporting dynamic bitstream generation according to the viewport.

As for the first edition, OMAF includes encapsulation and signaling in ISOBMFF as well as streaming of omnidirectional media (DASH and MMT). It will reach its final milestone by the end of 2020.

360° video is certainly a vital use case towards a fully immersive media experience. Devices to capture and consume such content are becoming increasingly available and will probably contribute to the dissemination of this type of content. However, it is also understood that the complexity increases significantly, specifically with respect to large-scale, scalable deployments due to increased content volume/complexity, timing constraints (latency), and quality of experience issues.

Research aspects: understanding the increased complexity of 360° video or immersive media in general is certainly an important aspect to be addressed towards enabling applications and services in this domain. We may even start thinking that 360° video actually works (e.g., it's possible to capture, upload to YouTube and consume it on many devices) but the devil is in the detail in order to handle this complexity in an efficient way to enable seamless and high quality of experience.

DASH and CMAF

The 4th edition of DASH (ISO/IEC 23009-1) will be published soon and MPEG is currently working towards a first amendment which will be about (i) CMAF support and (ii) event processing model. An overview of all DASH standards is depicted in the figure below, notably part one of MPEG-DASH referred to as media presentation description and segment formats.

The 2nd edition of the CMAF standard (ISO/IEC 23000-19) will become available very soon and MPEG is currently reviewing additional tools in the so-called technologies under considerations document as well as conducting various explorations. A working draft for additional media profiles is also under preparation.

Research aspects: with CMAF, low-latency supported is added to DASH-like applications and services. However, the implementation specifics are actually not defined in the standard and subject to competition (e.g., here). Interestingly, the Bitmovin video developer reports from both 2018 and 2019 highlight the need for low-latency solutions in this domain.

At the ACM Multimedia Conference 2019 in Nice, France I gave a tutorial entitled “A Journey towards Fully Immersive Media Access” which includes updates related to DASH and CMAF. The slides are available here.

Outlook 2020

Finally, let me try giving an outlook for 2020, not so much content-wise but events planned for 2020 that are highly relevant for this column:

• MPEG129, Jan 13-17, 2020, Brussels, Belgium
• DCC 2020, Mar 24-27, 2020, Snowbird, UT, USA
• MPEG130, Apr 20-24, 2020, Alpbach, Austria
• NAB 2020, Apr 08-22, Las Vegas, NV, USA
• MIPR 2020, Apr 09-10, Shenzhen, Guangdong, China
• ICASSP 2020, May 4-8, 2020, Barcelona, Spain
• QoMEX 2020, May 26-28, 2020, Athlone, Ireland
• MMSys 2020, Jun 8-11, 2020, Istanbul, Turkey
• IMX 2020, June 17-19, 2020, Barcelona, Spain
• IVMSP 2020, June 23-26, 2020, Nafplio, Greece
• MPEG131, Jun 29 - Jul 3, 2020, Geneva, Switzerland
• NetSoft, QoE Mgmt Workshop, Jun 29 - Jul 3, 2020, Ghent, Belgium
• ICME 2020, Jul 6-10, London, UK
• ATHENA summer school, Jul 13-17, Klagenfurt, Austria

... and many more!

MPEG news: a report from the 127th meeting, Gothenburg, Sweden

The original blog post can be found at the Bitmovin Techblog and has been modified/updated here to focus on and highlight research aspects. Additionally, this version of the blog post will be also posted at ACM SIGMM Records.

MPEG News Archive

Plenary of the 127th MPEG Meeting in Gothenburg, Sweden.

The 126th MPEG meeting concluded on March 29, 2019 in Geneva, Switzerland with the following topics:

• Versatile Video Coding (VVC) enters formal approval stage, experts predict 35-60% improvement over HEVC
• Essential Video Coding (EVC) promoted to Committee Draft
• Common Media Application Format (CMAF) 2nd edition promoted to Final Draft International Standard
• Dynamic Adaptive Streaming over HTTP (DASH) 4th edition promoted to Final Draft International Standard
• Carriage of Point Cloud Data Progresses to Committee Draft
• JPEG XS carriage in MPEG-2 TS promoted to Final Draft Amendment of ISO/IEC 13818-1 7th edition
• Genomic information representation – WG11 issues a joint call for proposals on genomic annotations in conjunction with ISO TC 276/WG 5
• ISO/IEC 23005 (MPEG-V) 4th Edition – WG11 promotes the Fourth edition of two parts of “Media Context and Control” to the Final Draft International Standard (FDIS) stage

The corresponding press release of the 127th MPEG meeting can be found here: https://mpeg.chiariglione.org/meetings/127

Versatile Video Coding (VVC)

The Moving Picture Experts Group (MPEG) is pleased to announce that Versatile Video Coding (VVC) progresses to Committee Draft, experts predict 35-60% improvement over HEVC.

The development of the next major generation of video coding standard has achieved excellent progress, such that MPEG has approved the Committee Draft (CD, i.e., the text for formal balloting in the ISO/IEC approval process).

The new VVC standard will be applicable to a very broad range of applications and it will also provide additional functionalities. VVC will provide a substantial improvement in coding efficiency relative to existing standards. The improvement in coding efficiency is expected to be quite substantial – e.g., in the range of 35–60% bit rate reduction relative to HEVC although it has not yet been formally measured. Relative to HEVC means for equivalent subjective video quality at picture resolutions such as 1080p HD or 4K or 8K UHD, either for standard dynamic range video or high dynamic range and wide color gamut content for levels of quality appropriate for use in consumer distribution services. The focus during the development of the standard has primarily been on 10-bit 4:2:0 content, and 4:4:4 chroma format will also be supported.

The VVC standard is being developed in the Joint Video Experts Team (JVET), a group established jointly by MPEG and the Video Coding Experts Group (VCEG) of ITU-T Study Group 16. In addition to a text specification, the project also includes the development of reference software, a conformance testing suite, and a new standard ISO/IEC 23002-7 specifying supplemental enhancement information messages for coded video bitstreams. The approval process for ISO/IEC 23002-7 has also begun, with the issuance of a CD consideration ballot.

Research aspects: VVC represents the next generation video codec to be deployed in 2020+ and basically the same research aspects apply as for previous generations, i.e., coding efficiency, performance/complexity, and objective/subjective evaluation. Luckily, JVET documents are freely available including the actual standard (committee draft), software (and its description), and common test conditions. Thus, researcher utilizing these resources are able to conduct reproducible research when contributing their findings and code improvements back to the community at large. 

Essential Video Coding (EVC)

MPEG-5 Essential Video Coding (EVC) promoted to Committee Draft

Interestingly, at the same meeting as VVC, MPEG promoted MPEG-5 Essential Video Coding (EVC) to Committee Draft (CD). The goal of MPEG-5 EVC is to provide a standardized video coding solution to address business needs in some use cases, such as video streaming, where existing ISO video coding standards have not been as widely adopted as might be expected from their purely technical characteristics.

The MPEG-5 EVC standards includes a baseline profile that contains only technologies that are over 20 years old or are otherwise expected to be royalty-free. Additionally, a main profile adds a small number of additional tools, each providing significant performance gain. All main profile tools are capable of being individually switched off or individually switched over to a corresponding baseline tool. Organizations making proposals for the main profile have agreed to publish applicable licensing terms within two years of FDIS stage, either individually or as part of a patent pool.

Research aspects: Similar research aspects can be described for EVC and from a software engineering perspective it could be also interesting to further investigate this switching mechanism of individual tools or/and fall back option to baseline tools. Naturally, a comparison with next generation codecs such as VVC is interesting per se. The licensing aspects itself are probably interesting for other disciplines but that is another story...

Common Media Application Format (CMAF)

MPEG ratified the 2nd edition of the Common Media Application Format (CMAF)

The Common Media Application Format (CMAF) enables efficient encoding, storage, and delivery of digital media content (incl. audio, video, subtitles among others), which is key to scaling operations to support the rapid growth of video streaming over the internet. The CMAF standard is the result of widespread industry adoption of an application of MPEG technologies for adaptive video streaming over the Internet, and widespread industry participation in the MPEG process to standardize best practices within CMAF.

The 2nd edition of CMAF adds support for a number of specifications that were a result of significant industry interest. Those include

• Advanced Audio Coding (AAC) multi-channel;
• MPEG-H 3D Audio;
• MPEG-D Unified Speech and Audio Coding (USAC);
• Scalable High Efficiency Video Coding (SHVC);
• IMSC 1.1 (Timed Text Markup Language Profiles for Internet Media Subtitles and Captions); and
• additional HEVC video CMAF profiles and brands.

This edition also introduces CMAF supplemental data handling as well as new structural brands for CMAF that reflects the common practice of the significant deployment of CMAF in industry. Companies adopting CMAF technology will find the specifications introduced in the 2nd Edition particularly useful for further adoption and proliferation of CMAF in the market.

Research aspects: see below (DASH).

Dynamic Adaptive Streaming over HTTP (DASH)

MPEG approves the 4th edition of Dynamic Adaptive Streaming over HTTP (DASH)

The 4th edition of MPEG-DASH comprises the following features:

service description that is intended by the service provider on how the service is expected to be consumed;

• a method to indicate the times corresponding to the production of associated media;
• a mechanism to signal DASH profiles and features, employed codec and format profiles; and
• supported protection schemes present in the Media Presentation Description (MPD).

It is expected that this edition will be published later this year. 

Research aspects: CMAF 2nd and DASH 4th edition come along with a rich feature set enabling a plethora of use cases. The underlying principles are still the same and research issues arise from updated application and service requirements with respect to content complexity, time aspects (mainly delay/latency), and quality of experience (QoE). The DASH-IF awards the excellence in DASH award at the ACM Multimedia Systems conference and an overview about its academic efforts can be found here. For example, see here our recent research on bandwidth prediction in low-latency chunked streaming. Additionally, our tutorial at ACM Multimedia 2019 about a journey towards fully immersive media access reviews state of the art in this area and how it could be extended enabling 6DoF HAS services through point cloud compression.

Carriage of Point Cloud Data

MPEG progresses the Carriage of Point Cloud Data to Committee Draft

At its 127th meeting, MPEG has promoted the carriage of point cloud data to the Committee Draft stage, the first milestone of ISO standard development process. This standard is the first one introducing the support of volumetric media in the industry-famous ISO base media file format family of standards.

This standard supports the carriage of point cloud data comprising individually encoded video bitstreams within multiple file format tracks in order to support the intrinsic nature of the video-based point cloud compression (V-PCC). Additionally, it also allows the carriage of point cloud data in one file format track for applications requiring multiplexed content (i.e., the video bitstream of multiple components is interleaved into one bitstream).

This standard is expected to support efficient access and delivery of some portions of a point cloud object considering that in many cases that entire point cloud object may not be visible by the user depending on the viewing direction or location of the point cloud object relative to other objects. It is currently expected that the standard will reach its final milestone by the end of 2020.

Research aspects: MPEG's Point Cloud Compression (PCC) comes in two flavors, video- and geometric-based but still requires to be packaged into file and delivery formats. MPEG's choice here is the ISO base media file format and the efficient carriage of point cloud data is characterized by both functionality (i.e., enabling the required used cases) and performance (such as low overhead).

MPEG 2 Systems/Transport Stream

JPEG XS carriage in MPEG-2 TS promoted to Final Draft Amendment of ISO/IEC 13818-1 7th edition

At its 127th meeting, WG11 (MPEG) has extended ISO/IEC 13818-1 (MPEG-2 Systems) – in collaboration with WG1 (JPEG) – to support ISO/IEC 21122 (JPEG XS) in order to support industries using still image compression technologies for broadcasting infrastructures. The specification defines a JPEG XS elementary stream header and specifies how the JPEG XS video access unit (specified in ISO/IEC 21122-1) is put into a Packetized Elementary Stream (PES). Additionally, the specification also defines how the System Target Decoder (STD) model can be extended to support JPEG XS video elementary streams.

Genomic information representation

WG11 issues a joint call for proposals on genomic annotations in conjunction with ISO TC 276/WG 5

The introduction of high-throughput DNA sequencing has led to the generation of large quantities of genomic sequencing data that have to be stored, transferred and analyzed. So far WG 11 (MPEG) and ISO TC 276/WG 5 have addressed the representation, compression and transport of genome sequencing data by developing the ISO/IEC 23092 standard series also known as MPEG-G. They provide a file and transport format, compression technology, metadata specifications, protection support, and standard APIs for the access of sequencing data in the native compressed format.

An important element in the effective usage of sequencing data is the association of the data with the results of the analysis and annotations that are generated by processing pipelines and analysts. At the moment such association happens as a separate step, standard and effective ways of linking data and meta information derived from sequencing data are not available.

At its 127th meeting, MPEG and ISO TC 276/WG 5 issued a joint Call for Proposals (CfP) addressing the solution of such problem. The call seeks submissions of technologies that can provide efficient representation and compression solutions for the processing of genomic annotation data.

Companies and organizations are invited to submit proposals in response to this call. Responses are expected to be submitted by the 8th January 2020 and will be evaluated during the 129th WG 11 (MPEG) meeting. Detailed information, including how to respond to the call for proposals, the requirements that have to be considered, and the test data to be used, is reported in the documents N18648, N18647, and N18649 available at the 127th meeting website (http://mpeg.chiariglione.org/meetings/127). For any further question about the call, test conditions, required software or test sequences please contact: Joern Ostermann, MPEG Requirements Group Chair (ostermann@tnt.uni-hannover.de) or Martin Golebiewski, Convenor ISO TC 276/WG 5 (martin.golebiewski@h-its.org).

ISO/IEC 23005 (MPEG-V) 4th Edition

WG11 promotes the Fourth edition of two parts of “Media Context and Control” to the Final Draft International Standard (FDIS) stage

At its 127th meeting, WG11 (MPEG) promoted the 4th edition of two parts of ISO/IEC 23005 (MPEG-V; Media Context and Control) standards to the Final Draft International Standard (FDIS). The new edition of ISO/IEC 23005-1 (architecture) enables ten new use cases, which can be grouped into four categories: 3D printing, olfactory information in virtual worlds, virtual panoramic vision in car, and adaptive sound handling. The new edition of ISO/IEC 23005-7 (conformance and reference software) is updated to reflect the changes made by the introduction of new tools defined in other parts of ISO/IEC 23005. More information on MPEG-V and its parts 1-7 can be found at https://mpeg.chiariglione.org/standards/mpeg-v.

Finally, the unofficial highlight of the 127th MPEG meeting we certainly found while scanning the scene in Gothenburg on Tuesday night...