From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc7933.txt | 2243 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2243 insertions(+) create mode 100644 doc/rfc/rfc7933.txt (limited to 'doc/rfc/rfc7933.txt') diff --git a/doc/rfc/rfc7933.txt b/doc/rfc/rfc7933.txt new file mode 100644 index 0000000..9eb703a --- /dev/null +++ b/doc/rfc/rfc7933.txt @@ -0,0 +1,2243 @@ + + + + + + +Internet Research Task Force (IRTF) C. Westphal, Ed. +Request for Comments: 7933 Huawei +Category: Informational S. Lederer +ISSN: 2070-1721 D. Posch + C. Timmerer + Alpen-Adria University Klagenfurt + A. Azgin + W. Liu + Huawei + C. Mueller + BitMovin + A. Detti + University of Rome Tor Vergata + D. Corujo + Instituto de Telecomunicacoes Aveiro + J. Wang + City University of Hong Kong + M. Montpetit + MIT + N. Murray + Athlone Institute of Technology + August 2016 + + + Adaptive Video Streaming over Information-Centric Networking (ICN) + +Abstract + + This document considers the consequences of moving the underlying + network architecture from the current Internet to an Information- + Centric Networking (ICN) architecture on video distribution. As most + of the traffic in future networks is expected to be video, we + consider how to modify the existing video streaming mechanisms. + Several important topics related to video distribution over ICN are + presented. The wide range of scenarios covered includes the + following: evolving Dynamic Adaptive Streaming over HTTP (DASH) to + work over ICN and leverage the recent ISO/IEC Moving Picture Experts + Group (MPEG) standard, layering encoding over ICN, introducing + distinct requirements for video using Peer-to-Peer (P2P) mechanisms, + adapting the Peer-to-Peer Streaming Protocol (PPSP) for ICN, creating + more stringent requirements over ICN because of delay constraints + added by Internet Protocol Television (IPTV), and managing digital + rights in ICN. Finally, in addition to considering how existing + mechanisms would be impacted by ICN, this document lists some + research issues to design ICN-specific video streaming mechanisms. + + + + + + +Westphal, et al. Informational [Page 1] + +RFC 7933 ICN Video Streaming August 2016 + + +Status of This Memo + + This document is not an Internet Standards Track specification; it is + published for informational purposes. + + This document is a product of the Internet Research Task Force + (IRTF). The IRTF publishes the results of Internet-related research + and development activities. These results might not be suitable for + deployment. This RFC represents the consensus of the Information- + Centric Networking Research Group of the Internet Research Task Force + (IRTF). Documents approved for publication by the IRSG are not a + candidate for any level of Internet Standard; see Section 2 of + RFC 7841. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + http://www.rfc-editor.org/info/rfc7933. + +Copyright Notice + + Copyright (c) 2016 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (http://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. + +Table of Contents + + 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 4 + 2. Conventions Used in This Document . . . . . . . . . . . . . . 4 + 3. Use Case Scenarios for ICN and Video Streaming . . . . . . . 5 + 4. Video Download . . . . . . . . . . . . . . . . . . . . . . . 6 + 5. Video Streaming and ICN . . . . . . . . . . . . . . . . . . . 7 + 5.1. Introduction to Client-Driven Streaming and DASH . . . . 7 + 5.2. Layered Encoding . . . . . . . . . . . . . . . . . . . . 8 + 5.3. Interactions of Video Streaming with ICN . . . . . . . . 8 + 5.3.1. Interactions of DASH with ICN . . . . . . . . . . . . 8 + 5.3.2. Interaction of ICN with Layered Encoding . . . . . . 10 + 5.4. Possible Integration of Video Streaming and ICN + Architecture . . . . . . . . . . . . . . . . . . . . . . 11 + 5.4.1. DASH over CCN . . . . . . . . . . . . . . . . . . . . 11 + 5.4.2. Testbed, Open-Source Tools, and Dataset . . . . . . . 13 + + + + + +Westphal, et al. Informational [Page 2] + +RFC 7933 ICN Video Streaming August 2016 + + + 6. P2P Video Distribution and ICN . . . . . . . . . . . . . . . 14 + 6.1. Introduction to PPSP . . . . . . . . . . . . . . . . . . 14 + 6.2. PPSP over ICN: Deployment Concepts . . . . . . . . . . . 16 + 6.2.1. PPSP Short Background . . . . . . . . . . . . . . . . 16 + 6.2.2. From PPSP Messages to ICN Named-Data . . . . . . . . 16 + 6.2.3. Support of PPSP Interaction through a Pull-Based ICN + API . . . . . . . . . . . . . . . . . . . . . . . . . 17 + 6.2.4. Abstract Layering for PPSP over ICN . . . . . . . . . 18 + 6.2.5. PPSP Interaction with the ICN Routing Plane . . . . . 19 + 6.2.6. ICN Deployment for PPSP . . . . . . . . . . . . . . . 19 + 6.3. Impact of MPEG-DASH Coding Schemes . . . . . . . . . . . 20 + 7. IPTV and ICN . . . . . . . . . . . . . . . . . . . . . . . . 21 + 7.1. IPTV Challenges . . . . . . . . . . . . . . . . . . . . . 21 + 7.2. ICN Benefits for IPTV Delivery . . . . . . . . . . . . . 22 + 8. Digital Rights Management in ICN . . . . . . . . . . . . . . 24 + 8.1. Broadcast Encryption for DRM in ICN . . . . . . . . . . . 24 + 8.2. AAA-Based DRM for ICN Networks . . . . . . . . . . . . . 27 + 8.2.1. Overview . . . . . . . . . . . . . . . . . . . . . . 27 + 8.2.2. Implementation . . . . . . . . . . . . . . . . . . . 28 + 9. Future Steps for Video in ICN . . . . . . . . . . . . . . . . 28 + 9.1. Large-Scale Live Events . . . . . . . . . . . . . . . . . 29 + 9.2. Video Conferencing and Real-Time Communications . . . . . 29 + 9.3. Store-and-Forward Optimized Rate Adaptation . . . . . . 29 + 9.4. Heterogeneous Wireless Environment Dynamics . . . . . . 30 + 9.5. Network Coding for Video Distribution in ICN . . . . . . 32 + 9.6. Synchronization Issues for Video Distribution in ICN . . 32 + 10. Security Considerations . . . . . . . . . . . . . . . . . . 33 + 11. Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . 33 + 12. References . . . . . . . . . . . . . . . . . . . . . . . . . 34 + 12.1. Normative References . . . . . . . . . . . . . . . . . . 34 + 12.2. Informative References . . . . . . . . . . . . . . . . . 34 + Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . . . 38 + Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 39 + + + + + + + + + + + + + + + + + + +Westphal, et al. Informational [Page 3] + +RFC 7933 ICN Video Streaming August 2016 + + +1. Introduction + + The unprecedented growth of video traffic has triggered a rethinking + of how content is distributed, both in terms of the underlying + Internet architecture and in terms of the streaming mechanisms to + deliver video objects. + + In particular, the IRTF ICNRG research group has been chartered to + study new architectures centered upon information; the main + contributor to Internet traffic (and information dissemination) is + video, and this is expected to stay the same in the near future. If + ICN is expected to become prominent, it will have to support video + streaming efficiently. + + As such, it is necessary to discuss going in two separate directions: + + Can the current video streaming mechanisms be leveraged and + adapted to an ICN architecture? + + Can (and should) new, ICN-specific video streaming mechanisms be + designed to fully take advantage of the new abstractions exposed + by the ICN architecture? + + This document focuses on the first question in an attempt to define + the use cases for video streaming and some requirements. It also + focuses on a few scenarios (namely, Netflix-like video streaming, P2P + video sharing, and IPTV) and identifies how the existing protocols + can be adapted to an ICN architecture. In doing so, it also + identifies the main issues with these protocols in this ICN context. + + In addition to this document, other works have considered specific + aspects of dynamic adaptive streaming in ICN [Lederer13b] + [Lederer13a] [Grandl13] [Detti12]. This document is informed by + these works, as well as others. + + In this document, we give a brief overview of the existing solutions + for the selected scenarios. We then examine the interactions of such + existing mechanisms with the ICN architecture and list some of the + interactions any video streaming mechanism will have to consider. + Finally, we identify some areas for future research. + +2. Conventions Used in This Document + + In examples, "C:" and "S:" indicate lines sent by the client and + server, respectively. + + + + + + +Westphal, et al. Informational [Page 4] + +RFC 7933 ICN Video Streaming August 2016 + + +3. Use Case Scenarios for ICN and Video Streaming + + For ICN-specific descriptions, we refer to the other research group + documents [RFC7476]. For our purpose, we assume here that "ICN" + refers to an architecture where content is retrieved by name and with + no binding of content to a specific network location. + + Both live and on-demand consumption of multimedia content come with + timing requirements for the delivery of the content. Additionally, + real-time use cases (such as audio-video conferencing [Jacobson09a], + game streaming, etc.) come with stricter timing requirements. Long + startup delays, buffering periods, poor video quality, etc., should + be avoided to achieve a better Quality of Experience (QoE) for the + consumer of the content. For a definition of QoE in the context of + video distribution, please refer to [LeCallet13]. The working + definition is as follows: + + Quality of Experience (QoE) is the degree of delight or annoyance + of the user of an application or service. It results from the + fulfillment of his or her expectations with respect to the utility + and/or enjoyment of the application or service in the light of the + user's personality and current state. + + Of course, these requirements are heavily influenced by routing + decisions and caching, which are central parts of ICN and that have + to be considered when streaming video in such infrastructures. + + Due to this range of requirements, we find it useful to narrow the + focus to four scenarios (more can be included later): + + o a video download architecture similar to that of Apple iTunes, + where the whole file is being downloaded to the client and can be + replayed there multiple times; + + o a video streaming architecture for playing back movies, which is + relevant for the naming and caching aspects of ICN as well as the + interaction with the rate adaptation mechanism necessary to + deliver the best QoE to the end user; + + o a P2P architecture for sharing videos, which introduces more + stringent routing requirements in terms of locating copies of the + content as the location of the peers evolves and peers join and + leave the swarm they use to exchange video chunks (for P2P + definitions and taxonomy, please refer to RFC 5694; and + + o IPTV, which introduces requirements for multicasting and adds + stronger delay constraints. + + + + +Westphal, et al. Informational [Page 5] + +RFC 7933 ICN Video Streaming August 2016 + + + Other scenarios, such as video conferencing and real-time video + communications, are not explicitly discussed in this document even + though they are in scope. Also, events of mass-media distribution, + such as a large crowd at a live event, add new requirements to be + included in later versions. + + The current state-of-the-art protocols in an IP context can be + modified for the ICN architecture. The remainder of this document is + organized as follows: Section 4 discusses video download; Section 5 + briefly describes DASH [ISO-DASH] and Layered Encoding (Modification + Detection Code (MDC), Scalable Video Coding (SVC)); Section 6 focuses + on P2P and PPSP; Section 7 highlights the requirements of IPTV; + Section 8 describes the issues of DRM; and Section 9 lists some + research issues to be solved for ICN-specific video delivery + mechanisms. + + Video-conferencing and real-time-video communications will be + described in further detail in future works. Mass distribution of + content at live, large-scale events (stadiums, concert halls, etc.) + for which there is no clearly adopted existing protocol is another + topic for further research. + +4. Video Download + + Video download, namely the fetching of a video file from a server or + a cache down to the user's local storage, is a natural application of + ICN. It should be supported natively without requiring any specific + considerations. + + This is supported now by a host of protocols (say, Secure Copy (SCP), + FTP, or over HTTP), which would need to be replaced by new ICN- + specific protocols to retrieve content in ICNs. + + However, current mechanisms are built atop existing transport + protocols. Some ICN proposals (Context-Centric Network (CCN) or + Named Data Networking (NDN), for instance) attempt to leverage the + work done upon these transport protocols. One proposal is to use the + TCP congestion window (and the associated Adaptive Increase, + Multiplicative Decrease (AIMD)) to decide how many object requests + ("Interests" in CCN/NDN terminology) should be in flight at any point + in time. + + It should be noted that ICN intrinsically supports different + transport mechanisms, which could achieve better performance than + TCP, as they subsume TCP into a special case. For instance, one + could imagine a link-by-link transport coupled with caching. This is + enabled by the ICN architecture and would facilitate the point-to- + point download of video files. + + + +Westphal, et al. Informational [Page 6] + +RFC 7933 ICN Video Streaming August 2016 + + +5. Video Streaming and ICN + +5.1. Introduction to Client-Driven Streaming and DASH + + Media streaming over HTTP and, in a further consequence, streaming + over the TCP, has become omnipresent in today's Internet. Content + providers such as Netflix, Hulu, and Vudu do not deploy their own + streaming equipment: they use the existing Internet infrastructure as + it is and simply deploy their own services Over The Top (OTT). This + streaming approach works surprisingly well without any particular + support from the underlying network due to the use of efficient video + compression, Content Delivery Networks (CDNs), and adaptive video + players. Earlier video streaming research mostly recommended use of + the User Datagram Protocol (UDP) combined with the Real-time + Transport Protocol (RTP). It assumed it would not be possible to + transfer multimedia data smoothly with TCP, because of its throughput + variations and large retransmission delays. This point of view has + significantly evolved today. HTTP streaming, and especially its most + simple form known as progressive download, has become very popular + over the past few years because it has some major benefits compared + to RTP streaming. As a consequence of the consistent use of HTTP for + this streaming method, the existing Internet infrastructure + consisting of proxies, caches, and CDNs could be used. Originally, + this architecture was designed to support best-effort delivery of + files and not real-time transport of multimedia data. Nevertheless, + real-time streaming based on HTTP could also take advantage of this + architecture, in comparison to RTP, which could not leverage any of + the aforementioned components. Another benefit that results from the + use of HTTP is that the media stream could easily pass firewalls or + Network Address Translation (NAT) gateways, which was definitely a + key for the success of HTTP streaming. However, HTTP streaming is + not the holy grail of streaming as it also introduces some drawbacks + compared to RTP. Nevertheless, in an ICN-based video streaming + architecture these aspects also have to be considered. + + The basic concept of DASH [ISO-DASH] is to use segments of media + content, which can be encoded at different resolutions, bit rates, + etc., as so-called representations. These segments are served by + conventional HTTP web servers and can be addressed via HTTP GET + requests from the client. As a consequence, the streaming system is + pull-based and the entire streaming logic is located on the client, + which makes it scalable and allows for adaptation of the media stream + to the client's capabilities. + + In addition to this, the content can be distributed using + conventional CDNs and their HTTP infrastructure, which also scales + very well. In order to specify the relationship between the + contents' media segments and the associated bit rate, resolution, and + + + +Westphal, et al. Informational [Page 7] + +RFC 7933 ICN Video Streaming August 2016 + + + timeline, the Media Presentation Description (MPD) is used, which is + an XML document. The MPD refers to the available media segments + using HTTP URLs, which can be used by the client for retrieving them. + +5.2. Layered Encoding + + Another approach for video streaming consists in using layered + encoding. Namely, scalable video coding formats the video stream + into different layers: a base layer that can be decoded to provide + the lowest bit rate for the specific stream and enhancement layers + that can be transmitted separately if network conditions allow. The + higher layers offer higher resolutions and enhancement of the video + quality, while the layered approach allows for adaptation to the + network conditions. This is used in an MPEG-4 scalable profile or + H.263+. H264SVC is available but not much deployed. JPEG2000 has a + wavelet transform approach for layered encoding but has not been + deployed much either. It is not clear if the layered approach is + fine-grained enough for rate control. + +5.3. Interactions of Video Streaming with ICN + +5.3.1. Interactions of DASH with ICN + + Video streaming (DASH in particular) has been designed with a goal + that is aligned with that of most ICN proposals: it is a client-based + mechanism that requests items (in this case, chunks of a video + stream) by name. + + ICN and MPEG-DASH [ISO-DASH] have several elements in common: + + o the client-initiated pull approach; + + o the content being dealt with in pieces (or chunks); + + o the support of efficient replication and distribution of content + pieces within the network; + + o the scalable, session-free nature of the exchange between the + client and the server at the streaming layer: the client is free + to request any chunk from any location; and + + o the support for potentially multiple source locations. + + For the last point, DASH may list multiple source URLs in a manifest, + and ICN is agnostic to the location of a copy it is receiving. We do + not imply that current video streaming mechanisms attempt to draw the + + + + + +Westphal, et al. Informational [Page 8] + +RFC 7933 ICN Video Streaming August 2016 + + + content from multiple sources concurrently. This is a potential + benefit of ICN but is not considered in the current approaches + mentioned in this document. + + As ICN is a promising candidate for the Future Internet (FI) + architecture, it is useful to investigate its suitability in + combination with multimedia streaming standards like MPEG-DASH. In + this context, the purpose of this section is to present the usage of + ICN instead of HTTP in MPEG-DASH. + + However, there are some issues that arise from using a dynamic rate + adaptation mechanism in an ICN architecture (note that some of the + issues are related to caching and are not necessarily unique to ICN): + + o Naming of the data in DASH does not necessarily follow the ICN + convention of any of the ICN proposals. Several chunks of the + same video stream might currently go by different names that, for + instance, do not share a common prefix. There is a need to + harmonize the naming of the chunks in DASH with the naming + conventions of the ICN. The naming convention of using a + filename/time/encoding format could, for instance, be made + compatible with the convention of CCN. + + o While chunks can be retrieved from any server, the rate adaptation + mechanism attempts to estimate the available network bandwidth so + as to select the proper playback rate and keep its playback buffer + at the proper level. Therefore, there is a need to either include + some location semantics in the data chunks so as to properly + assess the throughput to a specific location or to design a + different mechanism to evaluate the available network bandwidth. + + o The typical issue of access control and accounting happens in this + context, where chunks can be cached in the network outside of the + administrative control of the content publisher. It might be a + requirement from the owner of the video stream that access to + these data chunks needs to be accounted/billed/monitored. + + o Dynamic streaming multiplies the representations of a given video + stream, therefore diminishing the effectiveness of caching: + namely, to get a hit for a chunk in the cache, it has to be for + the same format and encoding values. Alternatively, to get the + same hit rate as a stream using a single encoding, the cache size + must be scaled up to include all the possible representations. + + o Caching introduces oscillatory dynamics as it may modify the + estimation of the available bandwidth between the end user and the + repository from which it is getting the chunks. For instance, if + an edge cache holds a low resolution representation near the user, + + + +Westphal, et al. Informational [Page 9] + +RFC 7933 ICN Video Streaming August 2016 + + + the user getting these low resolution chunks will observe a good + performance and will then request higher resolution chunks. If + those are hosted on a server with poor performance, then the + client would have to switch back to the low representation. This + oscillation may be detrimental to the perceived QoE of the user. + + o The ICN transport mechanism needs to be compatible to some extent + with DASH. To take a CCN example, the rate at which interests are + issued should be such that the chunks received in return arrive + fast enough and with the proper encoding to keep the playback + buffer above some threshold. + + o The usage of multiple network interfaces is possible in ICN, + enabling a seamless handover between them. For the combination + with DASH, an intelligent strategy that should focus on traffic + load-balancing between the available links may be necessary. This + would increase the effective media throughput of DASH by + leveraging the combined available bandwidth of all links; however, + it could potentially lead to high variations of the media + throughput. + + o DASH does not define how the MPD is retrieved; hence, this is + compatible with CCN. However, the current profiles defined within + MPEG-DASH require the MPD to contain HTTP URLs (including HTTP and + HTTPS URI schemes) to identify segments. To enable a more + integrated approach as described in this document, an additional + profile for DASH over CCN has to be defined, enabling ICN/CCN- + based URIs to identify and request the media segments. + + We describe in Section 5.4 a potential implementation of a dynamic + adaptive video stream over ICN, based upon DASH and CCN + [Jacobson09b]. + +5.3.2. Interaction of ICN with Layered Encoding + + Issues of interest to an ICN architecture in the context of layered + video streaming include: + + o Caching of the multiple layers. The caching priority should go to + the base layer and to defining caching policy in order to decide + when to cache enhancement layers; + + o Synchronization of multiple content streams, as the multiple + layers may come from different sources in the network (for + instance, the base layer might be cached locally while the + enhancement layers may be stored in the origin server). Video and + audio-video streams must be synchronized, and this includes both + intra-layer synchronization (for the layers of the same video or + + + +Westphal, et al. Informational [Page 10] + +RFC 7933 ICN Video Streaming August 2016 + + + audio stream) and inter-stream synchronization (see Section 9 for + other synchronization aspects to be included in the "Future Steps + for Video in ICN"); and + + o Naming of the different layers: when the client requests an + object, the request can be satisfied with the base layer alone, + aggregated with enhancement layers. Should one request be + sufficient to provide different streams? In a CCN architecture, + for instance, this would violate a "one Interest, one Data packet" + principle and the client would need to specify each layer it would + like to receive. In a Pub/Sub architecture, the Rendezvous Point + would have to make a decision as to which layers (or which pointer + to which layer's location) to return. + +5.4. Possible Integration of Video Streaming and ICN Architecture + +5.4.1. DASH over CCN + + DASH is intended to enable adaptive streaming, i.e., each content + piece can be provided in different qualities, formats, languages, + etc., to cope with the diversity of today's networks and devices. As + this is an important requirement for Future Internet proposals like + CCN, the combination of those two technologies seems to be obvious. + Since those two proposals are located at different protocol layers -- + DASH at the application and CCN at the network layer -- they can be + combined very efficiently to leverage the advantages of both and + potentially eliminate existing disadvantages. As CCN is not based on + classical host-to-host connections, it is possible to consume content + from different origin nodes as well as over different network links + in parallel, which can be seen as an intrinsic error resilience + feature with respect to the network. This is a useful feature of CCN + for adaptive multimedia streaming within mobile environments since + most mobile devices are equipped with multiple network links like 3G + and Wi-Fi. CCN offers this functionality out of the box, which is + beneficial when used for DASH-based services. In particular, it is + possible to enable adaptive video streaming handling both bandwidth + and network link changes. That is, CCN handles the network link + decision and DASH is implemented on top of CCN to adapt the video + stream to the available bandwidth. + + In principle, there are two options to integrate DASH and CCN: a + proxy service acting as a broker between HTTP and CCN as proposed in + [Detti12], and the DASH client implementing a native CCN interface. + The former transforms an HTTP request to a corresponding Interest + packet as well as a Data packet back to an HTTP response, including + reliable transport as offered by TCP. This may be a good compromise + to implement CCN in a managed network and to support legacy devices. + Since such a proxy is already described in [Detti12], this document + + + +Westphal, et al. Informational [Page 11] + +RFC 7933 ICN Video Streaming August 2016 + + + focuses on a more integrated approach, aiming at fully exploiting the + potential of a CCN DASH client. That is, we describe a native CCN + interface within the DASH client, which adopts a CCN naming scheme + (CCN URIs) to denote segments in the MPD. In this architecture, only + the network access component on the client has to be modified and the + segment URIs within MPD have to be updated according to the CCN + naming scheme. + + Initially, the DASH client retrieves the MPD containing the CCN URIs + of the content representations including the media segments. The + naming scheme of the segments may reflect intrinsic features of CCN + like versioning and segmentation support. Such segmentation support + is already compulsory for multimedia streaming in CCN; thus, it can + also be leveraged for DASH-based streaming over CCN. The CCN + versioning can be adopted in a further step to signal different + representations of the DASH-based content, which enables an implicit + adaptation of the requested content to the clients' bandwidth + conditions. That is, the Interest packet already provides the + desired characteristics of a segment (such as bit rate, resolution, + etc.) within the content name (or potentially within parameters + defined as extra types in the packet formats). Additionally, if + bandwidth conditions of the corresponding interfaces or routing paths + allow so, DASH media segments could be aggregated automatically by + the CCN nodes, which reduces the amount of Interest packets needed to + request the content. However, such approaches need further research, + specifically in terms of additional intelligence and processing power + needed at the CCN nodes. + + After requesting the MPD, the DASH client will start to request + particular segments. Therefore, CCN Interest packets are generated + by the CCN access component and forwarded to the available + interfaces. Within the CCN, these Interest packets leverage the + efficient interest aggregation for, e.g., popular content, as well as + the implicit multicast support. Finally, the Interest packets are + satisfied by the corresponding Data packets containing the video + segment data, which are stored on the origin server or any CCN node, + respectively. With an increasing popularity of the content, it will + be distributed across the network resulting in lower transmission + delays and reduced bandwidth requirements for origin servers and + content providers, respectively. + + With the extensive usage of in-network caching, new drawbacks are + introduced since the streaming logic is located at the client, i.e., + clients are not aware of each other and the network infrastructure + and cache states. Furthermore, negative effects are introduced when + multiple clients compete in a bottleneck and when caching influences + this bandwidth competition. As mentioned above, the clients request + individual portions of the content based on available bandwidth, + + + +Westphal, et al. Informational [Page 12] + +RFC 7933 ICN Video Streaming August 2016 + + + which is calculated using throughput estimations. This uncontrolled + distribution of the content influences the adaptation process of + adaptive streaming clients. The impact of this falsified throughput + estimation could be tremendous and leads to a wrong adaptation + decision that may impact the QoE at the client, as shown in + [Mueller12]. In ICN, the client does not have the knowledge from + which source the requested content is actually served or how many + origin servers of the content are available, as this is transparent + and depends on the name-based routing. This introduces the challenge + that the adaptation logic of the adaptive streaming client is not + aware of the event when the ICN routing decides to switch to a + different origin server or content is coming through a different + link/interface. As most algorithms implementing the adaption logic + use bandwidth measurements and related heuristics, the adaptation + decisions are no longer valid when changing origin servers (or + links), and these decisions potentially cause playback interruptions + and, consequently, stalling. Additionally, ICN supports the usage of + multiple interfaces. A seamless handover between these interfaces + (and different sources for the content) comes together with changes + in performance, e.g., due to switching between fixed and wireless, + 3G/4G and Wi-Fi networks, different types of servers (say with/ + without Shared Secret Data (SSD) or hardware acceleration), etc. + + Considering these characteristics of ICN, adaptation algorithms + merely based on bandwidth measurements are not appropriate anymore, + as potentially each segment can be transferred from another ICN node + or interface, all with different bandwidth conditions. Thus, + adaptation algorithms taking into account these intrinsic + characteristics of ICN are preferred over algorithms based on mere + bandwidth measurements. + +5.4.2. Testbed, Open-Source Tools, and Dataset + + For the evaluations of DASH over CCN, a testbed with open-source + tools and datasets is provided in [ITEC-DASH]. In particular, it + provides two client-player implementations, (i) a libdash extension + for DASH over CCN and (ii) a VLC plugin implementing DASH over CCN. + For both implementations, the CCNx implementation has been used as a + basis. + + The general architecture of libdash is organized in modules so that + the library implements a MPD parser and an extensible connection + manager. The library provides object-oriented interfaces for these + modules to access the MPD and the downloadable segments. These + components are extended to support DASH over CCN and are located in a + separate development branch of the GitHub project available at + . libdash comes together with + a fully featured DASH player with a QT-based front end, demonstrating + + + +Westphal, et al. Informational [Page 13] + +RFC 7933 ICN Video Streaming August 2016 + + + the usage of libdash and providing a scientific evaluation platform. + As an alternative, patches for the DASH plugin of the VLC player are + provided. These patches can be applied to the latest source code + checkout of VLC resulting in a DASH-over-CCN-enabled VLC player. + + Finally, a DASH-over-CCN dataset is provided in the form of a CCNx + repository. It includes 15 different quality representation of the + well-known Big Buck Bunny Movie, ranging from 100 kbps to 4500 kbps. + The content is split into segments of two seconds and is described by + an associated MPD using the presented naming scheme in Section 5.1. + This repository can be downloaded from [ITEC-DASH] and is also + provided by a publicly accessible CCNx node. Associated routing + commands for the CCNx namespaces of the content are provided via + scripts coming together with the dataset and can be used as a public + testbed. + +6. P2P Video Distribution and ICN + + Peer-to-Peer distribution is another form of distributing content -- + and video in particular -- that ICNs need to support. We see now how + an existing protocol such as PPSP can be modified to work in an ICN + environment. + +6.1. Introduction to PPSP + + P2P Video Streaming (P2PVS) is a popular approach to redistribute + live media over the Internet. The proposed P2PVS solutions can be + roughly classified in two classes: + + o Push/Tree-based + + o Pull/Mesh-based + + The Push/Tree-based solution creates an overlay network among Peers + that has a tree shape [Castro03]. Using a progressive encoding + (e.g., Multiple Description Coding or H.264 Scalable Video Coding), + multiple trees could be set up to support video rate adaptation. On + each tree, an enhancement stream is sent. The higher the number of + received streams, the higher the video quality. A peer controls the + video rate by either fetching or not fetching the streams delivered + over the distribution trees. + + The Pull/Mesh-based solution is inspired by the BitTorrent file + sharing mechanism. A tracker collects information about the state of + the swarm (i.e., the set of participating peers). A peer forms a + mesh overlay network with a subset of peers and exchanges data with + them. A peer announces what data items it disposes and requests + missing data items that are announced by connected peers. In case of + + + +Westphal, et al. Informational [Page 14] + +RFC 7933 ICN Video Streaming August 2016 + + + live streaming, the involved data set includes only a recent window + of data items published by the source. Also, in this case, the use + of a progressive encoding can be exploited for video rate adaptation. + + Pull/Mesh-based P2PVS solutions are the more promising candidate for + the ICN deployment, since most of ICN approach provides a pull-based + API [Jacobson09b] [Detti11] [Chai11] [NETINF]. In addition, + Pull/Mesh-based P2PVS are more robust than the Push/Tree-based one + [Magharei07], and the PPSP working group [IETF-PPSP] is also + proposing a Pull/Mesh-based solution. + + +------------------------------------------------+ + | | + | +--------------------------------+ | + | | Tracker | | + | +--------------------------------+ | + | | ^ ^ | + |Tracker | | Tracker |Tracker | + |Protocol| | Protocol |Protocol | + | | | | | + | V | | | + | +---------+ Peer +---------+ | + | | Peer |<----------->| Peer | | + | +---------+ Protocol +---------+ | + | | ^ | + | | |Peer | + | | |Protocol | + | V | | + | +---------------+ | + | | Peer | | + | +---------------+ | + | | + +------------------------------------------------+ + + Figure 1: PPSP System Architecture [RFC6972] + + Figure 1 reports the PPSP architecture presented in [RFC6972]. PEERs + announce and share video chunks and a TRACKER maintains a list of + PEERs participating in a specific audio-video channel or in the + distribution of a streaming file. The TRACKER functionality may be + centralized in a server or distributed over the PEERs. PPSP + standardizes the peer and Tracker Protocols, which can run directly + over UDP or TCP. + + This document discusses some preliminary concepts about the + deployment of PPSP on top of an ICN that exposes a pull-based API, + meanwhile considering the impact of MPEG-DASH streaming format. + + + + +Westphal, et al. Informational [Page 15] + +RFC 7933 ICN Video Streaming August 2016 + + +6.2. PPSP over ICN: Deployment Concepts + +6.2.1. PPSP Short Background + + The Peer-to-Peer Streaming Peer Protocol (PPSPP) is defined in + [Bakker15] and the Peer-to-Peer Streaming Tracker Protocol (PPSP-TP) + is defined in [RFC7846]. + + Some of the operations carried out by the Tracker Protocol are the + following: when a peer wishes to join the streaming session, it + contacts the tracker (CONNECT message), obtains a PEER_ID and a list + of PEER_IDs (and IP addresses) of other peers that are participating + to the SWARM and that the tracker has singled out for the requesting + peer (this may be a subset of the all peers of the SWARM); in + addition to this join operation, a peer may contact the tracker to + request to renew the list of participating peers (FIND message), to + periodically update its status to the tracker (STAT_REPORT message), + and so on. + + Some of the operations carried out by the Peer Protocol include the + following: using the list of peers delivered by the tracker, a peer + establishes a session with them (HANDSHAKE message); a peer + periodically announces to neighboring peers which chunks it has + available for download (HAVE message); using these announcements, a + peer requests missing chunks from neighboring peers (REQUEST + messages), which will be sent back to them (DATA message). + +6.2.2. From PPSP Messages to ICN Named-Data + + An ICN provides users with data items exposed by names. The bundle + name and data item is usually referred as "named-data", "named- + content", etc. To transfer PPSP messages through an ICN, the + messages should be wrapped as named-data items and receivers should + request them by name. + + A PPSP entity receives messages from peers and/or a tracker. Some + operations require gathering the messages generated by another + specific host (peer or tracker). For instance, if Peer A wishes to + gain information about video chunks available from Peer B, the former + shall fetch the PPSP HAVE messages specifically generated by the + latter. We refer to these kinds of named-data as "located-named- + data" since they should be gathered from a specific location (e.g., + Peer B). + + For other PPSP operations, such as fetching a DATA message (i.e., a + video chunk), as long as a peer receives the requested content, it + doesn't matter which endpoint generated the data. We refer to this + information with the generic term "named-data". + + + +Westphal, et al. Informational [Page 16] + +RFC 7933 ICN Video Streaming August 2016 + + + The naming scheme differentiates named-data and located-named-data + items. In the case of named-data, the naming scheme only includes a + content identifier (e.g., the name of the video chunk) without any + prefix identifying who provides the content. For instance, a DATA + message containing the video chunk "#1" may be named as + "ccnx:/swarmID/chunk/chunkID", where swarmID is a unique identifier + of the streaming session, "chunk" is a keyword, and chunkID is the + chunk identifier (e.g., an integer number). + + In case of located-named-data, the naming scheme includes a location- + prefix, which uniquely identifies the host generating the data item. + This prefix may be the PEER_ID in case the host was a peer or a + tracker identifier in case the host was the tracker. For instance, a + HAVE message generated by a Peer B may be named as + "ccnx:/swarmID/peer/PEER_ID/HAVE", where "peer" is a keyword, + PEER_ID_B is the identifier of Peer B, and HAVE is a keyword. + +6.2.3. Support of PPSP Interaction through a Pull-Based ICN API + + The PPSP procedures are based both on pull and push interactions. + For instance, the distribution of chunks availability can be + classified as a push-based operation since a peer sends "unsolicited" + information (HAVE message) to neighboring peers. Conversely, the + procedure used to receive video chunks can be classified as pull- + based since it is supported by a request/response interaction (i.e., + REQUEST, DATA messages). + + As we said, we refer to an ICN architecture that provides a pull- + based API. Accordingly, the mapping of PPSP pull-based procedure is + quite simple. For instance, using the CCN architecture + [Jacobson09b], a PPSP DATA message may be carried by a CCN DATA + message and a REQUEST message can be transferred by a CCN Interest. + + Conversely, the support of push-based PPSP operations may be more + difficult. We need an adaptation functionality that carries out a + push-based operation using the underlying pull-based service + primitives. For instance, a possible approach is to use the request/ + response (i.e., Interest/Data) four-way handshakes proposed in + [Jacobson09a]. Another possibility is that receivers periodically + send out request messages of the named-data that neighbors will push + and, when available, the sender inserts the pushed data within a + response message. + + + + + + + + + +Westphal, et al. Informational [Page 17] + +RFC 7933 ICN Video Streaming August 2016 + + +6.2.4. Abstract Layering for PPSP over ICN + + +-----------------------------------+ + | Application | + +-----------------------------------+ + | PPSP (TCP/IP) | + +-----------------------------------+ + | ICN - PPSP Adaptation Layer (AL) | + +-----------------------------------+ + | ICN Architecture | + +-----------------------------------+ + + Figure 2: Mediator Approach + + Figure 2 provides a possible abstract layering for PPSP over ICN. + The Adaptation Layer acts as a mediator (proxy) between legacy PPSP + entities based on TCP/IP and the ICN architecture. In fact, the role + the mediator is to use ICN to transfer PPSP legacy messages. + + This approach makes it possible to merely reuse TCP/IP P2P + applications whose software includes also PPSP functionality. This + "all-in-one" development approach may be rather common since the PPSP + application interface is not going to be specified. Moreover, if the + operating system will provide libraries that expose a PPSP API, these + will be initially based on an underlying TCP/IP API. Also, in this + case, the mediator approach would make it possible to easily reuse + both the PPSP libraries and the Application on top of an ICN. + + +-----------------------------------+ + | Application | + +-----------------------------------+ + | ICN-PPSP | + +-----------------------------------+ + | ICN Architecture | + +-----------------------------------+ + + Figure 3: Clean-Slate Approach + + Figure 3 sketches a clean-slate layering approach in which the + application directly includes or interacts with a PPSP version based + on ICN. It's likely such a PPSP_ICN integration could yield a + simpler development also because it does not require implementing a + TCP/IP to ICN translation as in the Mediator approach. However, the + clean-slate approach requires developing the application (in case of + embedded PPSP functionality) or the PPSP library from scratch without + exploiting what might already exist for TCP/IP. + + + + + +Westphal, et al. Informational [Page 18] + +RFC 7933 ICN Video Streaming August 2016 + + + Overall, the Mediator approach may be considered the first step of a + migration path towards ICN-native PPSP applications. + +6.2.5. PPSP Interaction with the ICN Routing Plane + + Upon the ICN API, a user (peer) requests content and the ICN sends it + back. The content is gathered by the ICN from any source, which + could be the closest peer that disposes of the named-data item, an + in-network cache, etc. Actually, "where" to gather the content is + controlled by an underlying ICN routing plane, which sets up the ICN + forwarding tables (e.g., CCN FIB [Jacobson09b]). + + A cross-layer interaction between the ICN routing plane and the PPSP + may be required to support a PPSP session. Indeed, ICN shall forward + request messages (e.g., CCN Interest) towards the proper peer that + can handle them. Depending on the layering approach, this cross- + layer interaction is controlled either by the Adaptation Layer or by + the ICN-PPSP. For example, if a Peer A receives a HAVE message + indicating that Peer B disposes of the video chunk named + "ccnx:/swarmID/chunk/chunkID", then the former should insert in its + ICN forwarding table an entry for the prefix "ccnx:/swarmID/chunk/ + chunkID" whose next hop locator (e.g., IP address) is the network + address of Peer B [Detti13]. + +6.2.6. ICN Deployment for PPSP + + The ICN functionality that supports a PPSP session may be "isolated" + or "integrated" with one from a public ICN. + + In the isolated case, a PPSP session is supported by an instance of + an ICN (e.g., deployed on top of an IP) whose functionalities operate + only on the limited set of nodes participating to the swarm, i.e., + peers and the tracker. This approach resembles the one followed by a + current P2P application, which usually forms an overlay network among + peers of a P2P application; intermediate public IP routers do not + carry out P2P functionalities. + + In the integrated case, the nodes of a public ICN may be involved in + the forwarding and in-network caching procedures. In doing so, the + swarm may benefit from the presence of in-network caches, thus + limiting uplink traffic on peers and inter-domain traffic, too. + These are distinctive advantages of using PPSP over a public ICN + rather than over TCP/IP. In addition, such advantages aren't likely + manifested in the case of isolated deployment. + + However, the possible interaction between the PPSP and the routing + layer of a public ICN may be dramatic, both in terms of explosion of + the forwarding tables and in terms of security. These issues + + + +Westphal, et al. Informational [Page 19] + +RFC 7933 ICN Video Streaming August 2016 + + + specifically take place for those ICN architectures for which the + name resolution (i.e., name to next hop) occurs en route, like the + CCN architecture. + + For instance, using the CCN architecture, to fetch a named-data item + offered by a Peer A the on-path public ICN entities have to route the + request messages towards the Peer A. This implies that the ICN + forwarding tables of public ICN nodes may contain many entries, e.g., + one entry per video chunk, and these entries are difficult to be + aggregated since peers may have available only sparse parts of a big + content, whose names have a same prefix (e.g., "ccnx:/swarmID"). + Another possibility is to wrap all PPSP messages into a located- + named-data. In this case, the forwarding tables should contain + "only" the PEER_ID prefixes (e.g., "ccnx:/swarmID/peer/PEER_ID"), + thus scaling down the number of entries from number of chunks to + number of peers. However, in this case, the ICN mechanisms recognize + the same video chunk offered by different peers as different content, + thus losing caching and multicasting ICN benefits. In any case, + routing entries should be updated either on the basis of the + availability of named-data items on peers or on the presence of + peers, and these events in a P2P session are rapidly changing and + possibly hampering the convergence of the routing plane. Finally, + since peers have an impact on the ICN forwarding table of public + nodes, this may open obvious security issues. + +6.3. Impact of MPEG-DASH Coding Schemes + + The introduction of video rate adaptation may significantly decrease + the effectiveness of P2P cooperation and of in-network caching, + depending of the kind of the video coding used by the MPEG-DASH + stream. + + In case of an MPEG-DASH streaming with MPEG AVC encoding, the same + video chunk is independently encoded at different rates and the + encoding output is a different file for each rate. For instance, in + case of a video encoded at three different rates, R1, R2, and R3; for + each segment S, we have three distinct files: S.R1, S.R2, and S.R3. + These files are independent of each other. To fetch a segment coded + at R2 kbps, a peer shall request the specific file S.R2. Receiver- + driven algorithms, implemented by the video client, usually handle + the estimation of the best coding rate. + + The independence among files associated with different encoding rates + and the heterogeneity of peer bandwidths may dramatically reduce the + interaction among peers, the effectiveness of in-network caching (in + case of integrated deployment), and consequently, the ability of PPSP + to offload the video server (i.e., a seeder peer). Indeed, a Peer A + may select a coding rate (e.g., R1) different from the one selected + + + +Westphal, et al. Informational [Page 20] + +RFC 7933 ICN Video Streaming August 2016 + + + by a Peer B (e.g., R2), and this prevents the former from fetching + video chunks from the latter since Peer B only has chunks available + that are coded at a rate different from the ones needed by Peer A. + To overcome this issue, a common distributed rate selection algorithm + could force peers to select the same coding rate [Detti13]; + nevertheless, this approach may be not feasible in the case of many + peers. + + The use of an SVC encoding (Annex G extension of the H.264/MPEG-4 + Advanced Video Coding (AVC) video compression standard) should make + rate adaptation possible while neither reducing peer collaborations + nor the in-network caching effectiveness. For a single video chunk, + an SVC encoder produces different files for the different rates + (roughly "layers"), and these files are progressively related to each + other. Starting from a base layer that provides the minimum rate + encoding, the next rates are encoded as an "enhancement layer" of the + previous one. For instance, in case the video is coded with three + rates, R1 (base layer), R2 (enhancement layer n.1), and R3 + (enhancement layer n.2), then for each DASH segment, we have three + files: S.R1, S.R2, and S.R3. The file S.R1 is the segment coded at + the minimum rate (base layer). The file S.R2 enhances S.R1, so S.R1 + and S.R2 can be combined to obtain a segment coded at rate R2. To + get a segment coded at rate R2, a peer shall fetch both S.R1 and + S.R2. This progressive dependence among files that encode the same + segment at different rates makes peer cooperation possible, also in + case peers player have autonomously selected different coding rates. + For instance, if Peer A has selected the rate R1, the downloaded + files S.R1 are useful also for a Peer B that has selected the rate + R2, and vice versa. + +7. IPTV and ICN + +7.1. IPTV Challenges + + IPTV refers to the delivery of quality content broadcast over the + Internet and is typically associated with strict quality + requirements, i.e., with a perceived latency of less than 500 ms and + a packet loss rate that is multiple orders lower than the current + loss rates experienced in the most commonly used access networks (see + [ATIS-IIF]). We can summarize the major challenges for the delivery + of IPTV service as follows. + + + + + + + + + + +Westphal, et al. Informational [Page 21] + +RFC 7933 ICN Video Streaming August 2016 + + + Channel change latency represents a major concern for the IPTV + service. Perceived latency during channel change should be less than + 500 ms. To achieve this objective over the IP infrastructure, we + have multiple choices: + + i receive fast unicast streams from a dedicated server (most + effective but not resource efficient); + + ii connect to other peers in the network (efficiency depends on + peer support, effective and resource efficient, if also + supported with a dedicated server); and + + iii connect to multiple multicast sessions at once (effective but + not resource efficient and depends on the accuracy of the + prediction model used to track user activity). + + The second major challenge is the error recovery. Typical IPTV + service requirements dictate the mean time between artifacts to be + approximately 2 hours (see [ATIS-IIF]). This suggests the perceived + loss rate to be less than or equal to 10^-7. Current IP-based + solutions rely on the following proactive and reactive recovery + techniques: (i) joining the Forward Error Correction (FEC) multicast + stream corresponding to the perceived packet loss rate (not + efficient, as the recovery strength is chosen based on worst-case + loss scenarios); (ii) making unicast recovery requests to dedicated + servers (requires active support from the service provider); (iii) + probing peers to acquire repair packets (finding matching peers and + enabling their cooperation is another challenge). + +7.2. ICN Benefits for IPTV Delivery + + ICN presents significant advantages for the delivery of IPTV traffic. + For instance, ICN inherently supports multicast and allows for quick + recovery from packet losses (with the help of in-network caching). + Similarly, peer support is also provided in the shape of in-network + caches that typically act as the middleman between two peers, + therefore enabling earlier access to IPTV content. + + However, despite these advantages, delivery of IPTV service over ICNs + brings forth new challenges. We can list some of these challenges as + follows: + + o Messaging overhead: ICN is a pull-based architecture and relies on + a unique balance between requests and responses. A user needs to + make a request for each Data packet. In the case of IPTV, with + rates up to (and likely to be) above 15 Mbps, we observe + significant traffic upstream to bring those streams. As the + number of streams increases (including the same session at + + + +Westphal, et al. Informational [Page 22] + +RFC 7933 ICN Video Streaming August 2016 + + + different quality levels and other formats), so does the burden on + the routers. Even if the majority of requests are aggregated at + the core, routers close to the edge (where we observe the biggest + divergence in user requests) will experience a significant + increase in overhead to process these requests. The same is true + at the user side, as the uplink usage multiplies in the number of + sessions a user requests (for instance, to minimize the impact of + bandwidth fluctuations). + + o Cache control: As the IPTV content expires at a rapid rate (with a + likely expiry threshold of 1 s), we need solutions to effectively + flush out such content to also prevent degradation impact on other + cached content, with the help of intelligently chosen naming + conventions. However, to allow for fast recovery and optimize + access time to sessions (from current or new users), the timing of + such expirations needs to be adaptive to network load and user + demand. However, we also need to support quick access to earlier + content, whenever needed; for instance, when the user accesses the + rewind feature (note that in-network caches will not be of + significant help in such scenarios due to the overhead required to + maintain such content). + + o Access accuracy: To receive the up-to-date session data, users + need to be aware of such information at the time of their request. + Unlike IP multicast, since the users join a session indirectly, + session information is critical to minimize buffering delays and + reduce the startup latency. Without such information, and without + any active cooperation from the intermediate routers, stale data + can seriously undermine the efficiency of content delivery. + Furthermore, finding a cache does not necessarily equate to + joining a session, as the look-ahead latency for the initial + content access point may have a shorter lifetime than originally + intended. For instance, if the user that has initiated the + indirect multicast leaves the session early, the requests from the + remaining users need to experience an additional latency of one + RTT as they travel towards the content source. If the startup + latency is chosen depending on the closeness to the intermediate + router, going to the content source in-session can lead to + undesired pauses. + + It should be noted that IPTV includes more than just multicast. Many + implementations include "trick plays" (fast forward, pause, rewind) + that often transform a multicast session into multiple unicast + sessions. In this context, ICN is beneficial, as the caching offers + an implicit multicast but without tight synchronization constraints + in between two different users. One user may rewind and start + playing forward again, thus drawing from a nearby cache of the + + + + +Westphal, et al. Informational [Page 23] + +RFC 7933 ICN Video Streaming August 2016 + + + content recently viewed by another user (whereas in a strict + multicast session, the opportunity of one user lagging off behind + would be more difficult to implement). + +8. Digital Rights Management in ICN + + This section discusses the need for DRM functionalities for + multimedia streaming over ICN. It focuses on two possible + approaches: modifying Authentication, Authorization, and Accounting + (AAA) to support DRM in ICN and using Broadcast Encryption. + + It is assumed that ICN will be used heavily for digital content + dissemination. It is vital to consider DRM for digital content + distribution. In today's Internet, there are two predominant classes + of business models for on-demand video streaming. The first model is + based on advertising revenues. Non-copyright protected (usually + User-Generated Content (UGC)) content is offered by large + infrastructure providers like Google (YouTube) at no charge. The + infrastructure is financed by spliced advertisements into the + content. In this context, DRM considerations may not be required, + since producers of UGC may only strive for the maximum possible + dissemination. Some producers of UGC are mainly interested in + sharing content with their families, friends, colleges, or others and + have no intention making a profit. However, the second class of + business model requires DRM, because these entities are primarily + profit oriented. For example, large on-demand streaming platforms + (e.g., Netflix) establish business models based on subscriptions. + Consumers may have to pay a monthly fee in order to get access to + copyright-protected content like TV series, movies, or music. This + model may be ad supported and free to the content consumer, like + YouTube Channels or Spotify, but the creator of the content expects + some remuneration for his work. From the perspective of the service + providers and the copyright owners, only clients that pay the fee + (explicitly or implicitly through ad placement) should be able to + access and consume the content. Anyway, the challenge is to find an + efficient and scalable way of access control to digital content, + which is distributed in ICNs. + +8.1. Broadcast Encryption for DRM in ICN + + This section discusses Broadcast Encryption (BE) as a suitable basis + for DRM functionalities in conformance to the ICN communication + paradigm (network-inherent caching, considered the advantage of BE, + will be highlighted). + + In ICN, Data packets can be cached inherently in the network, and any + network participant can request a copy of these packets. This makes + it very difficult to implement an access control for content that is + + + +Westphal, et al. Informational [Page 24] + +RFC 7933 ICN Video Streaming August 2016 + + + distributed via ICN. A naive approach is to encrypt the transmitted + data for each consumer with a distinct key. This prohibits everyone + other than the intended consumers from decrypting and consuming the + data. However, this approach is not suitable for ICN's communication + paradigm, since it would reduce the benefits gained from the inherent + network caching. Even if multiple consumers request the same + content, the requested data for each consumer would differ using this + approach. A better, but still insufficient, idea is to use a single + key for all consumers. This does not destruct the benefits of ICN's + caching ability. The drawback is that if one of the consumers + illegally distributes the key, the system is broken; any entity in + the network can access the data. Changing the key after such an + event is useless since the provider has no possibility to identify + the illegal distributor. Therefore, this person cannot be stopped + from distributing the new key again. In addition to this issue, + other challenges have to be considered. Subscriptions expire after a + certain time, and then it has to be ensured that these consumers + cannot access the content anymore. For a provider that serves + millions of daily consumers (e.g., Netflix), there could be a + significant number of expiring subscriptions per day. Publishing a + new key every time a subscription expires would require an unsuitable + amount of computational power just to re-encrypt the collection of + audio-visual content. + + A possible approach to solve these challenges is BE [Fiat94] as + proposed in [Posch13]. From this point on, this section will focus + only on BE as an enabler for DRM functionality in the use case of ICN + video streaming. This subsection continues with the explanation of + how BE works and shows how BE can be used to implement an access + control scheme in the context of content distribution in ICN. + + BE actually carries a misleading name. One might expect a concrete + encryption scheme. However, it belongs to the family of key + management schemes. These schemes are responsible for the + generation, exchange, storage, and replacement of cryptographic keys. + The most interesting characteristics of BE schemes are: + + o BE schemes typically use a global trusted entity called the + Licensing Agent (LA), which is responsible for spreading a set of + pre-generated secrets among all participants. Each participant + gets a distinct subset of secrets assigned from the LA. + + o The participants can agree on a common session key, which is + chosen by the LA. The LA broadcasts an encrypted message that + includes the key. Participants with a valid set of secrets can + derive the session key from this message. + + + + + +Westphal, et al. Informational [Page 25] + +RFC 7933 ICN Video Streaming August 2016 + + + o The number of participants in the system can change dynamically. + Entities may join or leave the communication group at any time. + If a new entity joins, the LA passes on a valid set of secrets to + that entity. If an entity leaves (or is forced to leave) the LA + revokes the entity's subset of keys, which means that it cannot + derive the correct session key anymore when the LA distributes a + new key. + + o Traitors (entities that reveal their secrets) can be traced and + excluded from ongoing communication. The algorithms and + preconditions to identify a traitor vary between concrete BE + schemes. + + This listing already illustrates why BE is suitable to control the + access to data that is distributed via an ICN. BE enables the usage + of a single session key for confidential data transmission between a + dynamically changing subset or network participants. ICN caches can + be utilized since the data is encrypted only with a single key known + by all legitimate clients. Furthermore, traitors can be identified + and removed from the system. The issue of re-encryption still exists + because the LA will eventually update the session key when a + participant should be excluded. However, this disadvantage can be + relaxed in some way if the following points are considered: + + o The updates of the session key can be delayed until a set of + compromised secrets has been gathered. Note that secrets may + become compromised because of two reasons: first, a traitor could + have illegally revealed the secret; second, the subscription of an + entity expired. Delayed revocation temporarily enables some + illegitimate entities to consume content. However, this should + not be a severe problem in home entertainment scenarios. Updating + the session key in regular (not too short) intervals is a good + trade- off. The longer the interval lasts, the less computational + resources are required for content re-encryption and the better + the cache utilization in the ICN will be. To evict old data from + ICN caches that have been encrypted with the prior session key, + the publisher could indicate a lifetime for transmitted packets. + + o Content should be re-encrypted dynamically at request time. This + has the benefit that untapped content is not re-encrypted if the + content is not requested during two session key update; therefore, + no resources are wasted. Furthermore, if the updates are + triggered in non-peak times, the maximum amount of resources + needed at one point in time can be lowered effectively since in + peak times generally more diverse content is requested. + + + + + + +Westphal, et al. Informational [Page 26] + +RFC 7933 ICN Video Streaming August 2016 + + + o Since the amount of required computational resources may vary + strongly from time to time, it would be beneficial for any + streaming provider to use cloud-based services to be able to + dynamically adapt the required resources to the current needs. In + regard to a lack of computation time or bandwidth, the cloud + service could be used to scale up to overcome shortages. + + Figure 4 shows the potential usage of BE in a multimedia delivery + framework that builds upon ICN infrastructure and uses the concept of + dynamic adaptive streaming, e.g., DASH. BE would be implemented on + the top to have an efficient and scalable way of access control to + the multimedia content. + + +--------Multimedia Delivery Framework--------+ + | | + | Technologies Properties | + | +----------------+ +----------------+ | + | | Broadcast |<--->| Controlled | | + | | Encryption | | Access | | + | +----------------+ +----------------+ | + | |Dynamic Adaptive|<--->| Multimedia | | + | | Streaming | | Adaptation | | + | +----------------+ +----------------+ | + | | ICN |<--->| Cacheable | | + | | Infrastructure | | Data Chunks | | + | +----------------+ +----------------+ | + +---------------------------------------------+ + + Figure 4: A Potential Multimedia Framework Using BE + +8.2. AAA-Based DRM for ICN Networks + +8.2.1. Overview + + Recently, a novel approach to DRM has emerged to link DRM to usual + network management operations, hence linking DRM to AAA services. + ICN provides the abstraction of an architecture where content is + requested by name and could be served from anywhere. In DRM, the + content provider (the origin of the content) allows the destination + (the end-user account) to use the content. The content provider and + content storage/cache are at two different entities in ITU Carrier + Code (ICC); for traditional DRM, only source and destination count + and not the intermediate storage. The proposed solution allows the + provider of the caching to be involved in the DRM policies using + well-known AAA mechanisms. It is important to note that this + solution is compatible with the proposal of the BE, proposed earlier + in this document. The BE proposes a technology, as this solution is + more operational. + + + +Westphal, et al. Informational [Page 27] + +RFC 7933 ICN Video Streaming August 2016 + + +8.2.2. Implementation + + With the proposed AAA-based DRM, when content is requested by name + from a specific destination, the request could link back to both the + content provider and the caching provider via traditional AAA + mechanisms and trigger the appropriate DRM policy independently from + where the content is stored. In this approach, the caching, DRM, and + AAA remain independent entities but can work together through ICN + mechanisms. The proposed solution enables extending the traditional + DRM done by the content provider to jointly being done by content + provider and network/caching provider. + + The solution is based on the concept of a "token". The content + provider authenticates the end user and issues an encrypted token to + authenticate the named-content ID or IDs that the user can access. + The token will be shared with the network provider and used as the + interface to the AAA protocols. At this point, all content access is + under the control of the network provider and the ICN. The + controllers and switches can manage the content requests and handle + mobility. The content can be accessed from anywhere as long as the + token remains valid or the content is available in the network. In + such a scheme, the content provider does not need to be contacted + every time a named-content is requested. This reduces the load of + the content provider network and creates a DRM mechanism that is much + more appropriate for the distributed caching and Peer-to-Peer storage + characteristic of ICN networks. In particular, the content requested + by name can be served from anywhere under the only condition that the + storage/cache can verify that the token is valid for content access. + + The solution is also fully customizable to both content and network + provider's needs as the tokens can be issued based on user accounts, + location, and hardware (Media Access Control (MAC) address, for + example) linking it naturally to legacy authentication mechanisms. + In addition, since both content and network providers are involved in + DRM policies, pollution attacks and other illegal requests for the + content can be more easily detected. The proposed AAA-based DRM is + currently under full development. + +9. Future Steps for Video in ICN + + The explosion of online video services, along with their increased + consumption by mobile wireless terminals, further exacerbates the + challenges of ICN mechanisms that leverage Video Adaptation. The + following sections present a series of research items derived from + these challenges, further introducing next steps for the subject. + + + + + + +Westphal, et al. Informational [Page 28] + +RFC 7933 ICN Video Streaming August 2016 + + +9.1. Large-Scale Live Events + + Distributing content, and video in particular, using local + communications in large-scale events such as sporting events in a + stadium, a concert, or a large demonstration, is an active area of + investigation and a potential use case where ICN would provide + significant benefits. + + Such use cases involve locating content that is generated on the fly + and requires discovery mechanisms in addition to sharing mechanisms. + The scalability of the distribution becomes important as well. + +9.2. Video Conferencing and Real-Time Communications + + Current protocols for video conferencing have been designed, and this + document takes input from them to identify the key research issues. + Real-time communications add timing constraints (both in terms of + delay and in terms of synchronization) to the scenario discussed + above. + + An Access Router (AR) and a Virtual Router (VR), and immersive + multimedia experiences in general, are clearly an area of further + investigation, as they involve combining multiple streams of data + from multiple users into a coherent whole. This raises issues of + multisource, multidestination multimedia streams that ICN may be + equipped to deal with in a more natural manner than IP, which is + inherently unicast. + +9.3. Store-and-Forward Optimized Rate Adaptation + + One of the benefits of ICN is to allow the network to insert caching + in the middle of the data transfer. This can be used to reduce the + overall bandwidth demands over the network by caching content for + future reuse, but it provides more opportunities for optimizing video + streams. + + Consider, for instance, the following scenario: a client is connected + via an ICN network to a server. Let's say the client is connected + wirelessly to a node that has a caching capability, which is + connected through a WAN to the server. Further, assume that the + capacity of each of the links (both the wireless and the WAN logical + links) varies with time. + + If the rate adaptation is provided in an end-to-end manner, as in + current mechanisms like DASH, then the maximal rate that can be + supported at the client is that of the minimal bandwidth on each + link. + + + + +Westphal, et al. Informational [Page 29] + +RFC 7933 ICN Video Streaming August 2016 + + + If, for instance, during Time Period 1 the wireless capacity is 1 and + the wired capacity is 2 and during Time Period 2 the wireless + capacity is 2 (due to some hotspot) and the wired capacity is 1 (due + to some congestion in the network), then the best end-to-end rate + that can be achieved is 1 during each period. + + However, if the cache is used during Time Period 1 to pre-fetch 2 + units of data, then during Time Period 2 there is 1 unit of data at + the cache and another unit of data that can be streamed from the + server; therefore, the rate that can be achieved is 2 units of data. + In this case, the average bandwidth rises from 1 to 1.5 over the two + periods. + + This straw-man example illustrates a) the benefit of ICN for + increasing the throughput of the network and b) the need for the + special rate adaptation mechanisms to be designed to take advantage + of this gain. End-to-end rate adaptation cannot take advantage of + the cache availability. The authors of [Rainer16] showed that + buffer-based adaptation mechanisms can be one approach to tackle this + challenge. As buffer-based adaptation does not estimate the + available bandwidth resources (but solely considers the video buffer + fill state), measured bandwidth fluctuations caused by cache hits are + not existent. Therefore, they cannot negatively impact the + adaptation decisions (e.g., frequent representation switching). + +9.4. Heterogeneous Wireless Environment Dynamics + + With the ever-growing increase in online services being accessed by + mobile devices, operators have been deploying different overlapping + wireless access networking technologies. In this way, in the same + area, user terminals are within range of different cellular, Wi-Fi, + or even Worldwide Interoperability for Microwave Access (WiMAX) + networks. Moreover, with the advent of the Internet of Things (e.g., + surveillance cameras feeding video footage), this list can be further + complemented with more-specific short-range technologies, such as + Bluetooth or ZigBee. + + In order to leverage from this plethora of connectivity + opportunities, user terminals are coming equipped with different + wireless access interfaces, providing them with extended connectivity + opportunities. In this way, such devices become able to select the + type of access that best suits them according to different criteria, + such as available bandwidth, battery consumption, access to different + link conditions according to the user profile, or even access to + different content. Ultimately, these aspects contribute to the QoE + perceived by the end user, which is of utmost importance when it + comes to video content. + + + + +Westphal, et al. Informational [Page 30] + +RFC 7933 ICN Video Streaming August 2016 + + + However, the fact that these users are mobile and using wireless + technologies also provides a very dynamic setting where the current + optimal link conditions at a specific moment might not last or be + maintained while the user moves. These aspects have been amply + analyzed in recently finished projects such as FP7 MEDIEVAL + [MEDIEVAL], where link events reporting on wireless conditions and + available alternative connection points were combined with video + requirements and traffic optimization mechanisms towards the + production of a joint network and mobile terminal mobility management + decision. Concretely, in [Fu13], link information about the + deterioration of the wireless signal was sent towards a mobility + management controller in the network. This input was combined with + information about the user profile, as well as of the current video + service requirements, and used to trigger the decrease or increase of + scalable video layers (adjusting the video to the ongoing link + conditions). Incrementally, the video could also be adjusted when a + new, better connectivity opportunity presents itself. + + In this way, regarding Video Adaptation, ICN mechanisms can leverage + from their intrinsic multiple source support capability and go beyond + the monitoring of the status of the current link, thus exploiting the + availability of different connectivity possibilities (e.g., different + "interfaces"). Moreover, information obtained from the mobile + terminal's point of view of its network link, as well as information + from the network itself (i.e., load, policies, and others), can + generate scenarios where such information is combined in a joint + optimization procedure allowing the content to be forward to users + using the best available connectivity option (e.g., exploiting + management capabilities supported by ICN intrinsic mechanisms as in + [Corujo12]). + + In fact, ICN base mechanisms can further be exploited in enabling new + deployment scenarios such as preparing the network for mass requests + from users attending a large multimedia event (i.e., concert, + sports), allowing video to be adapted according to content, user and + network requirements, and operation capabilities in a dynamic way. + + Enabling such scenarios requires further research, with the main + points highlighted as follows: + + o how to develop a generic video services (and obviously content) + interface allowing the definition and mapping of their + requirements (and characteristics) into the current capabilities + of the network; + + o how to define a scalable mechanism allowing either the video + application at the terminal or some kind of network management + entity, to adapt the video content in a dynamic way; + + + +Westphal, et al. Informational [Page 31] + +RFC 7933 ICN Video Streaming August 2016 + + + o how to develop the previous research items using intrinsic ICN + mechanisms (i.e., naming and strategy layers); + + o how to leverage intelligent pre-caching of content to prevent + stalls and poor quality phases, which lead to a worse QoE for the + user: this includes, in particular, the usage in mobile + environments, which are characterized by severe bandwidth changes + as well as connection outages, as shown in [Crabtree13]; and + + o how to take advantage of the multipath opportunities over the + heterogeneous wireless interfaces. + +9.5. Network Coding for Video Distribution in ICN + + An interesting research area for combining heterogeneous sources is + to use network coding [Montpetit13b]. Network coding allows for + asynchronous combining of multiple sources by having each of them + send information that is not duplicated by the other but that can be + combined to retrieve the video stream. + + However, this creates issues in ICN in terms of defining the proper + rate adaptation for the video stream, securing the encoded data, + caching the encoded data, timeliness of the encoded data, overhead of + the network coding operations both in network resources and in added + buffering delay, etc. + + Network coding has shown promise in reducing buffering events in + unicast, multicast, and P2P settings. [Medard12] considers + strategies using network coding to enhance QoE for multimedia + communications. Network coding can be applied to multiple streams, + but also within a single stream as an equivalent of a composable + erasure code. Clearly, there is a need for further investigation of + network coding in ICN, potentially as a topic of activity in the + research group. + +9.6. Synchronization Issues for Video Distribution in ICN + + ICN decouples the fetching of video chunks from their locations. + This means an audio chunk may be received from one network element + (cache/storage/server), a video chunk may be received from another, + while yet another chunk (say, the next one, or another layer from the + same video stream) may come from a third element. This introduces + disparity in the retrieval times and locations of the different + elements of a video stream that need to be played at the same (or + almost same) time. Synchronization of such delivery and playback may + require specific synchronization tools for video delivery in ICN. + + + + + +Westphal, et al. Informational [Page 32] + +RFC 7933 ICN Video Streaming August 2016 + + + Other aspects involve synchronizing: + + o within a single stream, for instance, the consecutive chunks of a + single stream or the multiple layers of a layered scheme when + sources and transport layers may be different. + + o re-ordering the packets of a stream distributed over multiple + sources at the video client, or ensuring that multiple chunks + coming from multiple sources arrive within an acceptable time + window; + + o multiple streams, such as the audio and video components of a + video stream, which can be received from independent sources; and + + o multiple streams from multiple sources to multiple destinations, + such as mass distribution of live events. For instance, for live + video streams or video conferencing, some level of synchronization + is required so that people watching the stream view the same + events at the same time. + + Some of these issues were addressed in [Montpetit13a] in the context + of social video consumption. Network coding, with traffic + engineering, is considered as a potential solution for + synchronization issues. Other approaches could be considered that + are specific to ICN as well. + + Traffic engineering in ICN [Su14] [Chanda13] may be required to + provide proper synchronization of multiple streams. + +10. Security Considerations + + This is informational. There are no specific security considerations + outside of those mentioned in the text. + +11. Conclusions + + This document proposes adaptive video streaming for ICN, identified + potential problems, and presents the combination of CCN with DASH as + a solution. As both concepts, DASH and CCN, maintain several + elements in common, like, e.g., the content in different versions + being dealt with in segments, combination of both technologies seems + useful. Thus, adaptive streaming over CCN can leverage advantages + such as, e.g., efficient caching and intrinsic multicast support of + CCN, routing based on named-data URIs, intrinsic multilink and + multisource support, etc. + + + + + + +Westphal, et al. Informational [Page 33] + +RFC 7933 ICN Video Streaming August 2016 + + + In this context, the usage of CCN with DASH in mobile environments + comes together with advantages compared to today's solutions, + especially for devices equipped with multiple network interfaces. + The retrieval of data over multiple links in parallel is a useful + feature, specifically for adaptive multimedia streaming since it + offers the possibility to dynamically switch between the available + links depending on their bandwidth capabilities, which are + transparent to the actual DASH client. + +12. References + +12.1. Normative References + + [Rainer16] Rainer, B., Posch, D., and H. Hellwagner, "Investigating + the Performance of Pull-based Dynamic Adaptive Streaming + in NDN", IEEE Journal on Selected Areas in Communications + (J-SAC): Special Issue on Video Distribution over Future + Internet, Volume 34, Number 8, + DOI 10.1109/JSAC.2016.2577365, August 2016. + + [RFC6972] Zhang, Y. and N. Zong, "Problem Statement and Requirements + of the Peer-to-Peer Streaming Protocol (PPSP)", RFC 6972, + DOI 10.17487/RFC6972, July 2013, + . + +12.2. Informative References + + [ATIS-IIF] "ATIS: IIF, IPTV Interoperability Forum", 2015, + . + + [Bakker15] Bakker, A., Petrocco, R., and V. Grishchenko, "Peer-to- + Peer Streaming Peer Protocol (PPSPP)", RFC 7574, + DOI 10.17487/RFC7574, July 2015, + . + + [Castro03] Castro, M., Druschel, P., Kermarrec, A., Nandi, A., and A. + Rowstron, "SplitStream: High-Bandwidth Multicast in + Cooperative Environments", Proceedings of the 19th ACM + Symposium on Operating Systems Principles (SOSP '03), + DOI 10.1145/945445.945474, October 2003. + + [Chai11] Chai, W., Wang, N., Psaras, I., Pavlou, G., Wang, C., + de Blas, G., Ramon-Salguero, F., Liang, L., Spirou, S., + Blefari-Melazzi, N., Beben, A., and E. Hadjioannou, + "CURLING: Content-Ubiquitous Resolution and Delivery + Infrastructure for Next Generation Services", IEEE + Communications Magazine, Volume 49, Issue 3, + DOI 10.1109/MCOM.2011.5723808, March 2011. + + + +Westphal, et al. Informational [Page 34] + +RFC 7933 ICN Video Streaming August 2016 + + + [Chanda13] Chanda, A., Westphal, C., and D. Raychaudhuri, "Content + Based Traffic Engineering in Software Defined Information + Centric Networks", 2013 IEEE Conference on Computer + Communications Workshops (INFOCOM WKSHPS), + DOI 10.1109/INFCOMW.2013.6970717, April 2013. + + [Corujo12] Corujo, D., Vidal, I., Garcia-Reinoso, J., and R. Aguiar, + "A Named Data Networking Flexible Framework for Management + Communications", IEEE Communications Magazine, Volume 50, + Issue 12, DOI 10.1109/MCOM.2012.6384449, December 2012. + + [Crabtree13] + Crabtree, B., Stevens, T., Allan, B., Lederer, S., Posch, + D., Mueller, C., and C. Timmerer, "Video Adaptation in + Limited/Zero Network Coverage", CCNxCon 2013, Palo Alto + Research Center (PARC), September 2013. + + [Detti11] Detti, A., Blefari-Melazzi, N., Salsano, S., and M. + Pomposini, "CONET: A Content Centric Inter-Networking + Architecture", Proceedings of the ACM SIGCOMM Workshop on + Information-Centric Networking, + DOI 10.1145/2018584.2018598, August 2011. + + [Detti12] Detti, A., Pomposini, M., Blefari-Melazzi, N., Salsano, + S., and A. Bragagnini, "Offloading cellular networks with + Information-Centric Networking: the case of video + streaming", 2013 IEEE 14th International Symposium on A + World of Wireless, Mobile and Multimedia Networks + (WoWMoM), DOI 10.1109/WoWMoM.2012.6263734, June 2012. + + [Detti13] Detti, A., Ricci, B., and N. Blefari-Melazzi, "Peer-To- + Peer Live Adaptive Video Streaming for Information Centric + Cellular Networks", 2013 IEEE 24th Annual International + Symposium on Personal, Indoor, and Mobile Radio + Communications (PIMRC), DOI 10.1109/PIMRC.2013.6666771, + September 2013. + + [Fiat94] Fiat, A. and M. Naor, "Broadcast Encryption", Advances in + Cryptology - CRYPTO '93 Proceedings, Lecture Notes in + Computer Science, Volume 773, pp. 480-491, 1994. + + [Fu13] Fu, B., Kunzmann, G., Wetterwald, M., Corujo, D., and R. + Costa, "QoE-aware traffic management for mobile video + delivery", 2013 IEEE International Conference on + Communications Workshops (ICC), + DOI 10.1109/ICCW.2013.6649314, June 2013. + + + + + +Westphal, et al. Informational [Page 35] + +RFC 7933 ICN Video Streaming August 2016 + + + [Grandl13] Grandl, R., Su, K., and C. Westphal, "On the Interaction + of Adaptive Video Streaming with Content-Centric + Networks", 2013 IEEE International Conference on + Multimedia and Expo (ICME), DOI 10.1109/ICME.2013.6607500, + July 2013. + + [IETF-PPSP] + IETF, "Peer to Peer Streaming Protocol (ppsp)", + . + + [ISO-DASH] ISO, "Information technology -- Dynamic adaptive streaming + over HTTP (DASH) -- Part 1: Media presentation description + and segment formats", ISO/IEC 23009-1:2014, May 2014. + + [ITEC-DASH] + "ITEC - Dynamic Adaptive Streaming over HTTP", DASH + Research at the Institute of Information + Technology, Multimedia Communication Group, Alpen-Adria + Universitaet Klagenfurt, . + + [Jacobson09a] + Jacobson, V., Smetters, D., Briggs, N., Plass, M., + Stewart, P., Thornton, J., and R. Braynard, "VoCCN: Voice- + over Content-Centric Networks", Proceedings of the 2009 + Workshop on Re-architecting the Internet, + DOI 10.1145/1658978.1658980, December 2009. + + [Jacobson09b] + Jacobson, V., Smetters, D., Thornton, J., Plass, M., + Briggs, N., and R. Braynard, "Networking Named Content", + Proceedings of the 5th International Conference on + Emerging Networking Experiments and Technologies (CoNEXT), + DOI 10.1145/1658939.1658941, December 2009. + + [LeCallet13] + Le Callet, P., Moeller, S., and A. Perkis, "Qualinet White + Paper on Definitions of Quality of Experience", European + Network on Quality of Experience in Multimedia Systems and + Services, COST Action IC 1003, Version 1.2, March 2013. + + [Lederer13a] + Lederer, S., Liu, Y., Geurts, J., Point, J., Lederer, S., + Mueller, C., Rainer, B., Timmerer, C., and H. Hellwagner, + "Dynamic Adaptive Streaming over CCN: A Caching and + Overhead Analysis", 2013 IEEE International Conference on + Communication (ICC), DOI 10.1109/ICC.2013.6655116, June + 2013. + + + + +Westphal, et al. Informational [Page 36] + +RFC 7933 ICN Video Streaming August 2016 + + + [Lederer13b] + Lederer, S., Mueller, C., Rainer, B., Timmerer, C., and H. + Hellwagner, "An Experimental Analysis of Dynamic Adaptive + Streaming over HTTP in Content Centric Networks", 2013 + IEEE International Conference on Multimedia and Expo + (ICME), DOI 10.1109/ICME.2013.6607500, July 2013. + + [Magharei07] + Magharei, N., Rejaie, R., and Y. Guo, "Mesh or Multiple- + Tree: A Comparative Study of Live P2P Streaming + Approaches", IEEE INFOCOM 2007 - 26th IEEE International + Conference on Computer Communications, + DOI 10.1109/INFCOM.2007.168, May 2007. + + [Medard12] Medard, M., Kim, M., Parandeh-Gheibi, M., Zeng, W., and M. + Montpetit, "Quality of Experience for Multimedia + Communications: Network Coding Strategies", Laboratory of + Electronics, Massachusetts Institute of Technology, March + 2012. + + [MEDIEVAL] "MEDIEVAL: MultiMEDia transport for mobIlE Video + AppLications", 2010, . + + [Montpetit13a] + Montpetit, M., Holtzman, H., Chakrabarti, K., and M. + Matijasevic, "Social video consumption: Synchronized + viewing experiences across devices and networks", 2013 + IEEE International Conference on Communications Workshops + (ICC), pp. 286-290, DOI 10.1109/ICCW.2013.6649245, 2013. + + [Montpetit13b] + Montpetit, M., Westphal, C., and D. Trossen, "Network + Coding Meets Information-Centric Networking: An + Architectural Case for Information Dispersion Through + Native Network Coding", Proceedings of the 1st ACM + Workshop on Emerging Name-Oriented Mobile Networking + Design-Architecture, Algorithms, and Applications, + DOI 10.1145/2248361.2248370, June 2013. + + [Mueller12] + Mueller, C., Lederer, S., and C. Timmerer, "A Proxy Effect + Analysis and Fair Adaptation Algorithm for Multiple + Competing Dynamic Adaptive Streaming over HTTP Clients", + 2012 IEEE Visual Communications and Image Processing + (VCIP), DOI 10.1109/VCIP.2012.6410799, November 2012. + + [NETINF] "NetInf: Network of Information", . + + + + +Westphal, et al. Informational [Page 37] + +RFC 7933 ICN Video Streaming August 2016 + + + [Posch13] Posch, D., Hellwagner, H., and P. Schartner, "On-Demand + Video Streaming based on Dynamic Adaptive Encrypted + Content Chunks", Proceedings of the 8th International + Workshop on Secure Network Protocols (NPSec '13), + DOI 10.1109/ICNP.2013.6733673, October 2013. + + [RFC7476] Pentikousis, K., Ed., Ohlman, B., Corujo, D., Boggia, G., + Tyson, G., Davies, E., Molinaro, A., and S. Eum, + "Information-Centric Networking: Baseline Scenarios", + RFC 7476, DOI 10.17487/RFC7476, March 2015, + . + + [RFC7846] Cruz, R., Nunes, M., Xia, J., Huang, R., Ed., Taveira, J., + and D. Lingli, "Peer-to-Peer Streaming Tracker Protocol + (PPSTP)", RFC 7846, DOI 10.17487/RFC7846, May 2016, + . + + [Su14] Su, K. and C. Westphal, "On the Benefit of Information + Centric Networks for Traffic Engineering", 2014 IEEE + International Conference on Communications (ICC), + DOI 10.1109/ICC.2014.6883810, June 2014. + +Acknowledgments + + This work was supported in part by the European Community in the + context of the SocialSensor (FP7-ICT-287975) project and partly + performed in the Lakeside Labs research cluster at AAU. SocialSensor + receives research funding from the European Community's Seventh + Framework Programme. The work for this document was also partially + performed in the context of the FP7/NICT EU-JAPAN GreenICN project, + . Apart from this, the European Commission + has no responsibility for the content of this document. The + information in this document is provided as is and no guarantee or + warranty is given that the information is fit for any particular + purpose. The user, thereof, uses the information at its sole risk + and liability. + + + + + + + + + + + + + + + +Westphal, et al. Informational [Page 38] + +RFC 7933 ICN Video Streaming August 2016 + + +Authors' Addresses + + Cedric Westphal (editor) + Huawei + + Email: Cedric.Westphal@huawei.com + + + Stefan Lederer + Alpen-Adria University Klagenfurt + + Email: stefan.lederer@itec.aau.at + + + Daniel Posch + Alpen-Adria University Klagenfurt + + Email: daniel.posch@itec.aau.at + + + Christian Timmerer + Alpen-Adria University Klagenfurt + + Email: christian.timmerer@itec.aau.at + + + Aytac Azgin + Huawei + + Email: aytac.azgin@huawei.com + + + Will (Shucheng) Liu + Huawei + + Email: liushucheng@huawei.com + + + Christopher Mueller + BitMovin + + Email: christopher.mueller@bitmovin.net + + + Andrea Detti + University of Rome Tor Vergata + + Email: andrea.detti@uniroma2.it + + + +Westphal, et al. Informational [Page 39] + +RFC 7933 ICN Video Streaming August 2016 + + + Daniel Corujo + Instituto de Telecomunicacoes Aveiro + + Email: dcorujo@av.it.pt + + + Jianping Wang + City University of Hong Kong + + Email: jianwang@cityu.edu.hk + + + Marie-Jose Montpetit + MIT + + Email: marie@mjmontpetit.com + + + Niall Murray + Athlone Institute of Technology + + Email: nmurray@research.ait.ie + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Westphal, et al. Informational [Page 40] + -- cgit v1.2.3