lola.bib

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@techreport{white-tsvwg-nqb-00,
	number =	{draft-white-tsvwg-nqb-00},
	type =		{Internet-Draft},
	institution =	{Internet Engineering Task Force},
	publisher =	{Internet Engineering Task Force},
	note =		{Work in Progress},
	url =		{https://datatracker.ietf.org/doc/html/draft-white-tsvwg-nqb-00},
        author =	{Greg White},
	title =		{{Identifying and Handling Non Queue Building Flows in a Bottleneck Link}},
	pagetotal =	8,
	year =		2018,
	month =		oct,
	day =		22,
	abstract =	{This draft discusses the potential to improve quality of experience for broadband internet applications by distinguishing between flows that cause queuing latency and flows that don't.},
}

@techreport{fossati-tsvwg-lola-00,
	number =	{draft-fossati-tsvwg-lola-00},
	type =		{Internet-Draft},
	institution =	{Internet Engineering Task Force},
	publisher =	{Internet Engineering Task Force},
	note =		{Work in Progress},
	url =		{https://datatracker.ietf.org/doc/html/draft-fossati-tsvwg-lola-00},
        author =	{Thomas Fossati and Gorry Fairhurst and Pedro A. Aranda Gutierrez and Mirja Kühlewind},
	title =		{{A Loss-Latency Trade-off Signal for the Mobile Network}},
	pagetotal =	6,
	year =		2018,
	month =		dec,
	day =		16,
	abstract =	{This document proposes a marking scheme for tagging low-latency flows (for example: interactive voice and video, gaming, machine to machine applications) that is safe to use by the mobile network for matching such flows to suitable per-hop behaviors (EPS bearers defined by 3GPP) in its core and radio segments. The suggested scheme re-uses NQB, a DiffServ-based signalling scheme with compatible rate-delay trade-off semantics that has been recently introduced in the context of fixed access to allow differential treatment of non-queue building vs queue building flows.},
}

@techreport{ietf-tsvwg-l4s-arch-03,
	number =	{draft-ietf-tsvwg-l4s-arch-03},
	type =		{Internet-Draft},
	institution =	{Internet Engineering Task Force},
	publisher =	{Internet Engineering Task Force},
	note =		{Work in Progress},
	url =		{https://datatracker.ietf.org/doc/html/draft-ietf-tsvwg-l4s-arch-03},
        author =	{Bob Briscoe and Koen De Schepper and Marcelo Bagnulo},
	title =		{{Low Latency, Low Loss, Scalable Throughput (L4S) Internet Service: Architecture}},
	pagetotal =	32,
	year =		2018,
	month =		oct,
	day =		22,
	abstract =	{This document describes the L4S architecture for the provision of a new Internet service that could eventually replace best efforts for all traffic: Low Latency, Low Loss, Scalable throughput (L4S). It is becoming common for \_all\_ (or most) applications being run by a user at any one time to require low latency. However, the only solution the IETF can offer for ultra-low queuing delay is Diffserv, which only favours a minority of packets at the expense of others. In extensive testing the new L4S service keeps average queuing delay under a millisecond for \_all\_ applications even under very heavy load, without sacrificing utilization; and it keeps congestion loss to zero. It is becoming widely recognized that adding more access capacity gives diminishing returns, because latency is becoming the critical problem. Even with a high capacity broadband access, the reduced latency of L4S remarkably and consistently improves performance under load for applications such as interactive video, conversational video, voice, Web, gaming, instant messaging, remote desktop and cloud-based apps (even when all being used at once over the same access link). The insight is that the root cause of queuing delay is in TCP, not in the queue. By fixing the sending TCP (and other transports) queuing latency becomes so much better than today that operators will want to deploy the network part of L4S to enable new products and services. Further, the network part is simple to deploy - incrementally with zero-config. Both parts, sender and network, ensure coexistence with other legacy traffic. At the same time L4S solves the long-recognized problem with the future scalability of TCP throughput. This document describes the L4S architecture, briefly describing the different components and how the work together to provide the aforementioned enhanced Internet service.},
}

@inproceedings{claffy2015,
	title = {{Adding Enhanced Services to the Internet: Lessons from History}},
	author = {K.C. Claffy and David Clark},
	bookTitle = {Telecommunications Policy Research Conference (TPRC)},
	month = {Sep},
	year = {2015},
	publisher = {Elsevier},
	crossref = {TPRC-43},
	keywords = {policy   overview   congestion}
}

@InProceedings{PodlesnyG08,
	author = {Maxim Podlesny and Sergey Gorinsky},
	title = {Rd network services: differentiation through performance incentives},
	booktitle = {Proceedings of the {ACM} {SIGCOMM} 2008 Conference on Applications, Technologies, Architectures, and Protocols for Computer Communications, Seattle, WA, USA, August 17-22, 2008},
	year = {2008},
	pages = {255--266},
	doi = {10.1145/1402958.1402988},
	url = {http://doi.acm.org/10.1145/1402958.1402988},
	bibsource = {dblp computer science bibliography, https://dblp.org},
	biburl = {https://dblp.org/rec/bib/conf/sigcomm/PodlesnyG08},
	timestamp = {Tue, 26 Jan 2016 10:12:59 +0100},
}

@misc{jitter,
	author = {Elan Amir},
	title = {Unreliable transport},
	howpublished = {\url{http://nms.lcs.mit.edu/~hari/papers/CS294/paper/node5.html}},
	month = {may},
	year = {1996},
	OPTnote = {note},
	annote = {Last visit: 16 Dec 2018},
}

@techreport{ITU-G.144,
	type = {Recommendation},
	title = {{ITU-T G.144, One-way transmission time}},
	key = {ITU-T G.144},
	institution = {International Telecommunication Union},
	publisher = {International Telecommunication Union},
	url = {https://www.itu.int/rec/T-REC-G.114-200305-I},
	month = may,
	year = {2003},
}

@Misc{5tonic,
	title = {{5TONIC Web site}},
	author = {{IMDEA Networks Institute}},
	OPTmonth = {month},
	year = {2016},
	howpublished = {\url{https://www.5tonic.org}},
	OPTnote = {note},
	annote = {Last visit: 17 Sep 2018},
}

@TechReport{3GPP-TS-23.203,
	Title = {{Technical Specification Group Services and System Aspects;
	licy and charging control architecture (Release 14)}},
	Institution = {3rd Generation Partnership Project},
	Year = {2017},
	Month = jun,
	Type = {Technical Specification},
	Key = {3GPP TS 23.203},
	Publisher = {3rd Generation Partnership Project},
	Url = {https://portal.3gpp.org/desktopmodules/Specifications/SpecificationDetails.aspx?specificationId=810}
}

@techreport{rfc2475,
	author = {S. Blake and D. Black and M. Carlson and E. Davies and Z. Wang and W. Weiss},
	title = {{An Architecture for Differentiated Services}},
	howpublished = {RFC 2475},
	series={Request for Comments},
	number={2475},
	year = {1998},
	month = {December},
	publisher = {IETF},
	organization = {Internet Engineering Task Force},
	institution = {IETF Secretariat},
	url = {http://www.rfc-editor.org/rfc/rfc2475.txt},
}

@electronic{Martin-Geddes-2014,
	key = {Martin-Geddes-2014},
	title = {{Over-provisioning bandwidth doesn't solve QoE problems}},
	author = {{Martin Geddes}},
	month = jun,
	year = {2014},
	url = {http://www.martingeddes.com/over-provisioning-bandwidth-qoe},
	annote = {Last visit: 30 May 2018},
}

@techreport{you-tsvwg-latency-loss-tradeoff-00,
	number = {draft-you-tsvwg-latency-loss-tradeoff-00},
	type = {Internet-Draft},
	institution = {Internet Engineering Task Force},
	publisher = {Internet Engineering Task Force},
	note = {Work in Progress},
	url = {https://datatracker.ietf.org/doc/html/draft-you-tsvwg-latency-loss-tradeoff-00},
	author = {Jianjie You and Michael Welzl and Brian Trammell and Mirja Kühlewind and Kevin Smith},
	title =	{{Latency Loss Tradeoff PHB Group}},
	pagetotal = 12,
	year = 2016,
	month = mar,
	day = 13,
	abstract = {This document defines a PHB (Per-Hop Behavior) group called Latency Loss Tradeoff (LLT). The LLT group is intended to provide delivery of IP packets in two classes of services: a low-loss service (Lo service) and a low-latency service (La service). The LLT group enables an application to request treatment for either low-loss or low-latency at a congested network link.},
}
,
@techreport{ietf-quic-transport,
	number = {draft-ietf-quic-transport-11},
	type = {Internet-Draft},
	institution = {Internet Engineering Task Force},
	publisher = {Internet Engineering Task Force},
	note = {Work in Progress},
	url = {https://datatracker.ietf.org/doc/html/draft-ietf-quic-transport-11},
	author = {Jana Iyengar and Martin Thomson},
	title =	{{QUIC: A UDP-Based Multiplexed and Secure Transport}},
	pagetotal = 101,
	year = 2018,
	month = mar,
	day = 4,
	abstract = {This document defines the core of the QUIC transport protocol. This document describes connection establishment, packet format, multiplexing and reliability. Accompanying documents describe the cryptographic handshake and loss detection.},
}

@electronic{letsenc-stats,
	key = {letsenc-stats},
	title = {{Let's Encrypt Statistics}},
	author = {{Internet Security Research Group}},
	month = {January},
	year = {2016},
	url = {https://letsencrypt.org/stats},
	OPTnote = {note},
	annote = {Last visit: 30 May 2018},
}

@techreport{rfc2210,
	author = {J. Wroclawski},
	title = {{The Use of RSVP with IETF Integrated Services}},
	howpublished = {RFC 2210},
	series={Request for Comments},
	number={2210},
	year = {1997},
	month = {September},
	publisher = {IETF},
	organization = {Internet Engineering Task Force},
	institution = {IETF Secretariat},
	url = {http://www.rfc-editor.org/rfc/rfc2210.txt},
}

@techreport{rfc2212,
	author = {S. Shenker and C. Partridge and R. Guerin},
	title = {{Specification of Guaranteed Quality of Service}},
	howpublished = {RFC 2212},
	series={Request for Comments},
	number={2212},
	year = {1997},
	month = {September},
	publisher = {IETF},
	organization = {Internet Engineering Task Force},
	institution = {IETF Secretariat},
	url={http://www.rfc-editor.org/rfc/rfc2212.txt},
}

@techreport{rfc3260,
	author = {D. Grossman},
	title = {{New Terminology and Clarifications for Diffserv}},
	howpublished = {RFC 3260},
	series={Request for Comments},
	number = {3260},
	year = {2002},
	month = {April},
	publisher = {IETF},
	organization = {Internet Engineering Task Force},
	institution = {IETF Secretariat},
	url={http://www.rfc-editor.org/rfc/rfc3260.txt},
}

@techreport{rfc4594,
	author = {J. Babiarz and K. Chan and F. Baker},
	title = {{Configuration Guidelines for DiffServ Service Classes}},
	howpublished = {RFC 4594},
	series = {Request for Comments},
	number = {4594},
	year = {2006},
	month = {August},
	publisher = {IETF},
	organization = {Internet Engineering Task Force},
	institution = {IETF Secretariat},
	url={http://www.rfc-editor.org/rfc/rfc4594.txt},
}

@proceedings{TPRC-43,
	title = {{The 43rd Research Conference on Communication, Information and Internet Policy}},
	year = {2015},
	OPTeditor = {editor},
	OPTvolume = {volume},
	OPTseries = {series},
	OPTaddress = {address},
	OPTmonth = {month},
	organization = {TPRC},
	OPTpublisher = {publisher},
	OPTnote = {note},
	annote = {Last visit:  6 Dec 2018},
}

@article{aceto2017,
	author = {Aceto, Giuseppe and Ciuonzo, Domenico and Montieri, Antonio and Pescapè, Antonio},
	year = {2017},
	month = {11},
	pages = {},
	title = {Multi-Classification Approaches for Classifying Mobile App Traffic},
	volume = {103},
	booktitle = {Journal of Network and Computer Applications},
	journal = {Journal of Network and Computer Applications}
}

@article{mantar-diff-06,
	author = {Haci A. Mantar and Junseok Hwang and Ibrahim Taner Okumus and Steve Chapin},
	year = {2006},
	month = {01},
	OPTpages = {},
	title = {A Scalable Intra-Domain Resource Management Scheme for Diffserv Networks},
	volume = {15},
	booktitle = {Journal of High Speed Networks}
}

@Misc{qbone-isoc-99,
	key = {qbone-isoc-99},
	title =	{{Internet2 QBone: a testbed for differentiated services}},
	author = {Benjamin Teitelbaum and Rüdiger Geib},
	OPTmonth = {month},
	year = {1999},
	howpublished = {\url{https://www.isoc.org/inet99/proceedings/4f/4f_1.htm}},
	OPTnote = {note},
	annote = {Last visit: 30 Apr 2018},
}

@techreport{cisco-forecast,
	title = {Cisco Visual Networking Index: Global Mobile Data Traffic Forecast Update, 2016–2021},
	year = {2017},
	month = "February",
	day = "07",
	author = "Cisco",
	institution =	{Cisco Systems Inc.},
	url = "https://www.cisco.com/c/en/us/solutions/collateral/service-provider/visual-networking-index-vni/mobile-white-paper-c11-520862.pdf"
}

@electronic{ns3,
	key = ns3,
	author = {{ns-3 Consortium}},
	title = {{ns-3 Network Simulator}},
	url = {https://www.nsnam.org},
	Optmonth = {},
	year = {2011-2018},
	OPTnote = {note},
	annote = {Last visit: 22 Nov 2018},
}

@misc{osm-reference,
	author = {{ETSI OSM}},
	title = {{OSM: Reference VNF and NS Descriptors}},
	howpublished = {\url{https://osm.etsi.org/wikipub/index.php/Reference_VNF_and_NS_Descriptors}},
	OPTmonth = {month},
	year = {2017},
	OPTnote = {note},
	annote = {Last visit: 16 Dec 2018},
}