136 | | ==== GENI for classes and GENI for the masses ==== |
137 | | '' This demo shows two educational offerings available on GENI: the GENI Classroom-as-a-Service on the wireless testbeds (GENI for classes), and the GENI MOOC which includes browser-based lab exercises in a Massive Open Online Class delivery format (GENI for the masses). '' |
138 | | |
139 | | Educators and those interested in engineering or computer science and engineering education at all levels. This demo showcases two educational offerings built on GENI and available for general use. The GENI Classroom-as-a-Service is a set of experiments designed to complement traditional courses on computer networks, wireless and mobile computing, or wireless communications. To date, it has been used by hundreds of students in over a dozen classes. We will also demo GENI MOOC, an experiment-based Massive Open Online Course (MOOC) on the subject of computer networks, with lab experiments that run on GENI resources. This course is aimed at beginners who want to learn about how the Internet works, students who want an introduction to some research topics in networking, and instructors who may use these browser-based experiments as in-class demonstrations or homework assignments. |
140 | | |
141 | | Posters: |
142 | | * [http://witestlab.poly.edu/~ffund/pubs/gec23-geni-classes.pdf Yet another virtual networking lab: GENI wireless Classroom-as-a-Service] (GENI for classes) |
143 | | * [http://witestlab.poly.edu/~ffund/pubs/gec23-geni-mooc.pdf GENI MOOC: Learning opportunities for the masses] (GENI for the masses) |
144 | | |
145 | | Participants: |
146 | | * Fraida Fund, ffund@nyu.edu, NYU Polytechnic School of Engineering |
147 | | |
148 | | {{{ |
149 | | #!html |
150 | | <h1 style="text-align: center; color: #FF7500"> |
151 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #FF7500;"></div> |
152 | | }}} |
| 136 | |
205 | | === Network and Service Providers === |
206 | | {{{ |
207 | | #!html |
208 | | <h1 style="text-align: center; color: #808080"> |
209 | | <div class="alignleft" style="width:100%;height:5;border-top:10px solid #808080;"></div> |
210 | | }}} |
211 | | |
212 | | ==== Prototype of a !ChoiceNet Economy Plane for the Future Internet Architecture ==== |
213 | | |
214 | | ''This demo shows a working prototype of complete end-to-end interaction of the !ChoiceNet entities within an economy plane.'' |
215 | | |
216 | | In this prototype we will demonstrate the !ChoiceNet message interactions between the three main entities which comprise a !ChoiceNet framework: Marketplace, multiple Providers, and Customers. This prototype offers consumers the opportunity to 'choose' from a variety of service offerings. Competition between providers encourage innovative and superior services, which ultimately benefits the customers. |
217 | | |
218 | | |
219 | | Participants: |
220 | | * Robinson Udechukwu, rnudechu@ncsu.edu, North Carolina State University |
221 | | * Rudra Dutta, rdutta@ncsu.edu, North Carolina State University |
222 | | * George Rouskas, rouskas@ncsu.edu, North Carolina State University |
223 | | * Shireesh Bhat, sbhat@ncsu.edu, North Carolina State University |
| 182 | |
| 183 | |
| 184 | ==== Dynamic Slices in ExoGENI: Modifying Slice Topology On Demand ==== |
| 185 | |
| 186 | This demo shows new ExoGENI features including dynamic slice modification. Functionality includes adding/removing compute nodes, storage nodes, and network links. |
| 187 | |
| 188 | Participants: |
| 189 | * Paul Ruth, pruth@renci.org, RENCI |
231 | | ==== Dynamic Slices in ExoGENI: Modifying Slice Topology On Demand ==== |
232 | | |
233 | | This demo shows new ExoGENI features including dynamic slice modification. Functionality includes adding/removing compute nodes, storage nodes, and network links. |
234 | | |
235 | | Participants: |
236 | | * Paul Ruth, pruth@renci.org, RENCI |
237 | | |
238 | | {{{ |
239 | | #!html |
240 | | <h1 style="text-align: center; color: #808080"> |
241 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #808080;"></div> |
242 | | }}} |
243 | | |
244 | | ==== Distributed Iceberg detection using !OpenFlow ==== |
245 | | |
246 | | ''Shakedown Experimentation on Scalable, Agile, Robust, and Secure Multi-Domain Software Defined Networks. Demo shows Software-Defined-Networking (SDN) based traffic measurements and inference paradigm for detecting global icebergs and distributed anomalies. '' |
247 | | |
248 | | Accurate and timely traffic matrix (TM) measurements provide essential inputs for today’s various network operations. In this demo, we evaluate our traffic measurement paradigm in an OpenFlow-based networks with multiple SDN switches. Our framework will collaboratively use the distributed measurement resources and employ iSTAMP on multiple OpenFlow switches to detect distributed iceberg. |
249 | | |
250 | | Participants: |
251 | | * gaustin909@gmail.com University of California at Davis |
252 | | * albcastro@ucdavis.edu, University of California at Davis |
253 | | |
254 | | {{{ |
255 | | #!html |
256 | | <h1 style="text-align: center; color: #808080"> |
257 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #808080;"></div> |
258 | | }}} |
259 | | |
260 | | ==== !ToMaTo on !CloudLab ==== |
261 | | |
262 | | ''This demo shows the !ToMaTo network testbed running on !CloudLab infrastructure. '' |
263 | | |
264 | | The !ToMaTo ( http://tomato-lab.org/) is a network testbed which enables researchers to run their experiment on a specifically designed virtual networking topologies. The !ToMaTo consists of a backend which controls multiple !ToMaTo hosts and a front-end which allows users to edit and manage their experiment from their browser. |
265 | | |
266 | | !ToMaTo hosts provide virtualization technology and a complete toolset for more advanced experiments. The hosts run !ToMaTo software package on existing operating system but installing the software needs bare metal machines and cannot be run in a virtualized environment. |
267 | | |
268 | | Therefore, !CloudLab which provides bare metal machines is suitable for running and scaling !ToMaTo hosts infrastructure. The demo will show how !ToMaTo hosts are provisioned on demand and runs on !CloudLab infrastructure. |
269 | | |
270 | | Participants: |
271 | | * Prof. Dr. Paul Müller, pmueller@informatik.uni-kl.de, University of Kaiserslautern Germany |
272 | | |
273 | | {{{ |
274 | | #!html |
275 | | <h1 style="text-align: center; color: #808080"> |
276 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #808080;"></div> |
277 | | }}} |
278 | | |
279 | | ==== ARCCN Self-Organized Cloud Platform ==== |
280 | | |
281 | | '' This demo shows a working prototype of the cloud orchestration platform with VNF use-case demonstration.'' |
282 | | |
283 | | Attendees interested in cloud computing, DC, NFV, SND, network visualization and !OpenStack should see this demo. |
284 | | |
285 | | The Self-organizing cloud platform (SOC) to deploy virtual networks in DC is presented. The platform supports both IaaS mode and PaaS mode. SOC platform uses some components of !OpenStack (Nova, Cinder, Keystone, Rabbit Message Queue) in combination with the original specialized components: !OpenFlow controller, orchestrator, unified scheduler for consistent resource allocation, graphical user interface (GUI) for network definition, an extensive “sensor” system for physical resources monitoring and management, and modified !OpenStack component Neutron. |
286 | | |
287 | | SOC cloud platform considered in this demo allows us to deploy both manageable and non-manageable virtual networks in the data center. The possibility of virtual resources migration, consistent scheduling and management of computing resources allows one to ensure a high load of physical resources and guaranteed SLA compliance for the network as a whole. A request for virtual network creation can be defined either by means of the network description language or by means of a GUI. |
288 | | |
289 | | Participants: |
290 | | * Vitaly Antonenko, anvial@lvk.cs.msu.su, Moscow State University |
291 | | |
292 | | {{{ |
293 | | #!html |
294 | | <h1 style="text-align: center; color: #808080"> |
295 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #808080;"></div> |
296 | | }}} |
297 | | |
298 | | ==== ARCCN RUNOS Controller ==== |
299 | | |
300 | | '' This demo shows a working prototype high speed SDN controller. '' |
301 | | |
302 | | Attendees interested in SDN networks, SDN applications, Distributed systems should see this demo. In Demo presented novel approach where network administrators no longer need to manually configure all network devices, they can simple "draw" a path between network elements and the system will automatically program the network elements. The demonstration shows possibility to manage the complex network from nice graphical interface without manual accessing to network elements. |
303 | | |
304 | | Participants: |
305 | | * Vitaly Antonenko, anvial@lvk.cs.msu.su, Moscow State University |
306 | | |
307 | | |
308 | | {{{ |
309 | | #!html |
310 | | <h1 style="text-align: center; color: #808080"> |
311 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #808080;"></div> |
312 | | }}} |
313 | | |
314 | | ==== SDN-based Transparent Handover Scheme in Heterogeneous Wireless Networks ==== |
315 | | ''This demo shows a working prototype of a transparent handover scheme in heterogeneous wireless networks. '' |
316 | | |
317 | | Attendees interested in emerging SDN and its application in heterogeneous wireless networks. |
318 | | |
319 | | In this project, we will show to exploit SDN to realize transparent handover between different wireless networks in a heterogeneous wireless network environment. Heterogeneous wireless has been more and more common recently. However, these networks are utilized separately currently. In order to utilize them as a whole, transparent handover is a necessary component. |
320 | | |
321 | | Participants: |
322 | | * Kang Chen, kangc@g.clemson.edu, Clemson University |
323 | | * Jim Martin, JMARTY@clemson.edu, Clemson University |
324 | | * Kuang-Ching Wang, kwang@clemson.edu, Clemson University |
325 | | * Anjan Rayamajhi, arayama@clemson.edu, Clemson University |
326 | | * Jianwei Liu, ljw725@gmail.com, Clemson University |
327 | | |
328 | | {{{ |
329 | | #!html |
330 | | <h1 style="text-align: center; color: #808080"> |
331 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #808080;"></div> |
332 | | }}} |
| 197 | |
392 | | === Safety === |
393 | | {{{ |
394 | | #!html |
395 | | <h1 style="text-align: center; color: #FF0000"> |
396 | | <div class="alignleft" style="width:100%;height:5;border-top:10px solid #FF0000;"></div> |
397 | | }}} |
398 | | |
399 | | ==== Symbiotic Evolution of CAV Applications and Networks ==== |
400 | | |
401 | | ''This poster shows how a working platform and the technologies of vehicular sensing and control (VSC) designed for enabling high-fidelity, at scale evaluation of protocols in vehicular networking. Visit us if you are interested in VSC networking and its real-world application'' |
402 | | |
403 | | * Yuehua Wang, yuehua.research@gmail.com, Wayne State University |
404 | | |
405 | | |
406 | | {{{ |
407 | | #!html |
408 | | <h1 style="text-align: center; color: #FF0000"> |
409 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #FF0000;"></div> |
410 | | }}} |
411 | | |
412 | | ==== A WiMAX-Based Public Safety 3D Surveillance Network ==== |
413 | | |
414 | | ''' The poster presents updates of our public surveillance project for a university campus in Philadelphia, PA. ''' |
415 | | |
416 | | People interested in implementing video heavy systems using cellular and GENI resources, as well as attendees interested in public safety surveillance systems in general. Real time mobile surveillance systems are challenging to deploy in practice given the limited wireless bandwidth available for streaming videos. The project will use 2D and 3D cameras to function under different environments and high speed wireless networks to accomplish real time streaming. The poster describes the on-going design of a mobile surveillance system designed to be implemented on police vehicles. The project is a partnership with the Temple University Police Department. |
417 | | |
418 | | Participants: |
419 | | |
420 | | * cctan@temple.edu, Temple University |
421 | | |
422 | | |
423 | | {{{ |
424 | | #!html |
425 | | <h1 style="text-align: center; color: #FF0000"> |
426 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #FF0000;"></div> |
427 | | }}} |
428 | | |
429 | | ==== SDN-Enabled Highly Resilient and Efficient Microgrids ==== |
430 | | '' This poster shows our current work that uses Software Defined Networking (SDN) to support highly resilient communication in Microgrids.'' |
431 | | |
432 | | Attendees interested in Microgrid, smart grid, and Software Defined Networking should attend demo. Microgrid is an emerging and promising paradigm to improve the resilience of the electric distribution infrastructure. The communication infrastructure plays a particularly critical role for microgrids with renewable energy sources due to their much smaller inertia as compared to traditional energy generation sources. The poster shows our current work on using ultra-fast programmable networks as the communication infrastructure for microgrids. Specifically, we show various functionalities including route reconfiguration, packet prioritization and guaranteed latency, realized using a local testbed and Open vSwitches in GENI infrastructure. |
433 | | |
434 | | Participants: |
435 | | |
436 | | * Yanyuan Qin, qin.yanyuan@gmail.com, University of Connecticut |
437 | | |
438 | | {{{ |
439 | | #!html |
440 | | <h1 style="text-align: center; color: #FF0000"> |
441 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #FF0000;"></div> |
442 | | }}} |
505 | | ==== Software Defined Network Exchanges (SDXs) and a Prototype Bioinformatics SDX at !StarLight ==== |
506 | | |
507 | | ''This demo shows working prototypes of SDXs at !StarLight and partner sites which enable the exchange of research traffic among different types of Software Define Networks and traditional networks. '' |
508 | | |
509 | | Attendees interested in |
510 | | (1) Investigating the current challenges related to managing SDN networks in production exchanges [[BR]] |
511 | | (2) Options that have been proposed to address these challenges and the prototype demos that implement some of these options [[BR]] |
512 | | (3) A Virtual Exchange Prototype (VEP): SDXs for Bioinformatics Big Data [[BR]] |
513 | | (4) A Virtual Exchange Prototype (VEP): SDXs for Clouds [[BR]] |
514 | | |
515 | | The challenges in connecting and exchanging different types of network traffic for research and education communities consists of a number of topics that are not well known out side a very small group of network exchange communities. The recent SDN/OpenFlow technology proliferation makes these challenge important to investigate by all interested parties. !StarLight and partner sites present current prototype work underway to address such challenges, the prototype SDXs include the NSI, ofNSI, GENI AM integration, virtual SDXs for Bioinformatics SDX and Virtual SDXs for the Chameleon NSFCloud testbed. |
516 | | |
517 | | Participants: |
518 | | * Joe Mambretti, j-mambretti@northwestern.edu, Northwestern University |
519 | | * Jim Chen, jim-chen@northwestern.edu, Northwestern University |
520 | | * Fei Yeh, fyeh@northwestern.edu, Northwestern University |
521 | | |
522 | | {{{ |
523 | | #!html |
524 | | <h1 style="text-align: center; color: #FFC0CB"> |
525 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #FFC0CB;"></div> |
526 | | }}} |
| 319 | |
619 | | === Future Provider Networks === |
620 | | {{{ |
621 | | #!html |
622 | | <h1 style="text-align: center; color: #FFD700"> |
623 | | <div class="alignleft" style="width:100%;height:5;border-top:10px solid #FFD700;"></div> |
624 | | }}} |
625 | | |
626 | | ==== GENI-VIRO ==== |
627 | | |
628 | | '' VIRO -- a Scalable and Resilient, Name-Space (Non-IP) Routing Protocol for Emerging Large Dynamic Networks.'' |
629 | | |
630 | | We will provide a demo about our VIRO-GENI project, where we have implemented an innovative non-IP routing protocol -- Virtual Id Routing (VIRO) -- using the OVS-SDN platform in GENI. In this demo will be showing VIRO running live on GENI: an opt-in client machine streams a video from a server in GENI. Both client and server are attached to a network composed with VIRO switches in GENI. In addition, we will also present a novel in-network pathlet switching framework for SDN networks using our VIRO architecture deployed in GENI. |
631 | | |
632 | | Participants: |
633 | | * Zhi-Li Zhang, zhzhang@cs.umn.edu, University of Minnesota |
634 | | * Braulio Dumba, braulio@cs.umn.edu, University of Minnesota |
635 | | |
636 | | |
637 | | {{{ |
638 | | #!html |
639 | | <h1 style="text-align: center; color: #FFD700"> |
640 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #FFD700;"></div> |
641 | | }}} |
642 | | ==== SmartFIRE EU-South Korea Cooperation on Future Internet Infrastructure ==== |
643 | | |
644 | | '' This poster is to present EU - South Korea cooperation under FIRE project (Future Internet Research and Experimentation = FIRE) '' |
645 | | |
646 | | Attendees interested in using different testbeds (like in ex. !OpenStack? testbed) should attend. There is an increasing demand from both academic and industrial communities to bridge the gap between visionary research and large-scale experimentation, through experimentally driven advanced research consisting of ‘iterative’ cycles of research, design and experimentation of new networking and service architectures and paradigms addressing all levels, including horizontal research on issues such as system complexity and security. |
647 | | |
648 | | This approach needs the set-up of large-scale experimental facilities, going beyond individual project testbeds, which are also needed as validation tools, i.e. for interoperability issues. They would help in anticipating possible migration paths for technological developments, which may be potentially disruptive; in discovering new and emerging behaviors and use patterns; as well as in assessing the socioeconomic implications of new technological solutions at an early stage. |
649 | | |
650 | | FIRE addresses the emerging expectations which are being put upon the Internet, by providing a research environment for investigating and experimentally validating highly innovative and revolutionary ideas. |
651 | | |
652 | | Participants: |
653 | | * Radimor Klacza, radomir.klacza@lip6.fr, !OneLab/Sorbonne Universités, France |
654 | | {{{ |
655 | | #!html |
656 | | <h1 style="text-align: center; color: #FFD700"> |
657 | | <div class="alignleft" style="width:100%;height:2;border-top:2px solid #FFD700;"></div> |
658 | | }}} |
659 | | |
660 | | ==== Transit-analytics: Tracking Transit Passengers through Wireless Monitoring ==== |
661 | | |
662 | | We present a transit passenger monitoring system by using regular WiFi card. The system monitors the packet transmissions from and to passenger's smartphone and/or tablet etc. The system can be used for passenger counting. It can monitor the number of passengers get on/off at each bus stops and provide to the bus company for bus scheduling and route planning. It can also monitor the number of people on street and identify the hot spots in the city. |
663 | | |
664 | | Participants: |
665 | | * Derek Meyer, dmeyer@cs.wisc.edu, Wisconsin Wireless and Networking Systems (WiNGS) Laboratory |
666 | | * Suman Banerjee, suman@cs.wisc.edu, Wisconsin Wireless and Networking Systems (WiNGS) Laboratory |
667 | | |
| 397 | |