Luigi IANNONE - Luigi is currently an Associate Professor at Telecom ParisTech (Paris), since May 2012. He was previously Senior Research Scientist at Deutsche Telekom Innovation Laboratories (TLabs, Berlin Germany); post-doc Researcher at Université catholique de Louvain (UCL - Belgium); and worked at the Université Pierre et Marie Curie (Paris VI – France), first as Ph.D. candidate and later as post-doc. His current research interests include intra- and inter- domain routing, future Internet architectures, as well as mobility, wireless networks, and wired/wireless convergence. He is currently serving on the editorial board of Elsevier Computer Networks Journal. Luigi Iannone is also co-chair of the LISP Working Group at the IETF (Internet Engineering Task Force) and the main developer of the OpenLISP Project. Wenqin Shao – Wenqin SHAO is a PhD candidate at Telecom ParisTech. Meanwhile he is also a research engineer working for BORDER 6. He received an Engineering degree from Telecom ParisTech in 2013 and a Bachelor of Engineering in 2010 from Fudan University, Shanghai. He previously worked as solution manager and network architect separately for SFR and Wibox, both of which are French telecom operators. His current research interests cover internet routing and traffic engineering, and more generally enhanced solutions for operating network systems, so as to deliver ever-evolving services in a less constrained Internet. Abstract: “LISP (locator/Identifier Separation Protocol) brings a revolutionary model for routing in largescale networks. Its original aim is to help reducing the size of the routing tables and thus bringing better scalability to the Internet. Due to its inherent flexibility, there are today several scenarios and use-cases where LISP is experimented and deployed either to enable new features or to fix (or at least alleviate) issues with current models and protocols (e.g., VM mobility, IPv6 transition, traffic-engineering, etc.). These new and improved capabilities are experimented within two co-existing environments: the LISP Beta-Network (http://www.lisp4.net), where Cisco is a major contributor, and LISP-lab (http://www.lisplab. org), mainly built on the open-source OpenLISP Project (http://www.openlisp.org). Within this session, we propose to present a case study where LISP is used as a control-plane signaling protocol for traffic engineering over the Internet. It intends to showcase how the current Internet performance can be improved through coordinated traffic engineering via orchestrated source and destination Autonomous Systems routing decisions. Such an objective is achieved without touching or tweaking in any way the current BGP routing infrastructure. In the proposed deployment model LISP provides both control- and data- plane functions; with a full LISP stack on both ends, it can as well operate as an traffic engineering control-plane on top of the BGP routing infrastructure.