wiki:GEC11PosterDescriptions

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GEC 11 Poster Descriptions

Secure Content Centric Mobile Network (SECON)

Mooi Choo Chuah, Lehigh University
Xiong Xiong, Lehigh University

Abstract

New wireless technologies allow mobile users to have easy access to real time data, and stay connected with friends, colleagues, & business partners. However emerging applications are usually data-centric but existing IP oriented paradigms are not flexible enough to support this. To support emerging mobile applications, we are developing a next generation mobile network that supports mobile content centric networking features, namely (a) intentional named message delivery, (b) content-centric security, (c) push-pull based data disseminations.

In our new SECON network, users can send User Interest (UI) packets to Content Resolution Server (CRS) to request for content data (CD) packets associated with a particular URI. The UIs will be forwarded by the receiving CRS to other CRSes that know who will be publishing content packets related to that URI. The UIs can also have intentional-named destinations e.g. all CRSes within a certain geographical area. In addition content publishers can send content publish announcements to CRSes before they forward content data packets to these CRSes. We have a preliminary prototype that supports UI, CPA & CD features. More features will be added in the near future.

More Information:

http://www.cse.lehigh.edu/~chuah/public_secon.html
http://www.cse.lehigh.edu/~chuah/secon.html


GENI Experiments on P2P and MANET Networks

Haiyin (Helen) Shen, Clemson University
Kuang-Ching Wang, Clemson University
Kang Chen, Clemson University
Ke Xu, Clemson University
Steven Winburn, Clemson University

Abstract

Today’s society is witnessing a tremendous increase in digital information. Myriads of applications call for the pooling and sharing of massive amounts of widely-scattered data at ever increasing scales that require a commensurate infrastructure of powerful networked distributed systems across wide and diverse areas. We will implement two existing data sharing algorithms, Cycloid and LORD, on the P2P and MANET networks, and thus identify and investigate potential issues in data sharing applications in these different heterogeneous networks.  We are using GENI as the testbed for simulating the P2P and MANET network environments.  Also, we will conduct a multi-system GENI experiment to demonstrate how each domain should have its own routing solutions while all the domains are federated through OpenFlow gateways.


Developing GENI Aggregates for Real-TIme Large-Scale Network Simulation (PrimoGENI)

Nathanael Van Vorst, School of Computing and Information Sciences, Florida International University
Miguel Erazo, School of Computing and Information Sciences, Florida International University
Hao Jiang, School of Computing and Information Sciences, Florida International University
Ting Li, School of Computing and Information Sciences, Florida International University
Jason Liu, School of Computing and Information Sciences, Florida International University

Abstract

The goal of PrimoGENI is to incorporate real-time network simulation into the GENI "ecosystem". We have extended PRIME, our existing real-time large-scale network simulator, to become part of the GENI federation. PrimoGENI will support large-scale GENI experiments with millions of simulated network entities (hosts, routers, and links) and thousands of emulated elements running unmodified network protocols and applications.

GENI Project:

PrimoGENI

More Information:

https://www.primessf.net/pub/Public/PrimoGENIProject/gec11.pdf
http://www.primessf.net/PrimoGENI


TUNIE: A Flexible and Programmable Virtualized Network Innovation Environment in China

Yong Li, Electronic Engineering, Tsinghua University

Abstract

Network community needs a flexible platform for network experiment of new architectures, algorithms and protocols in the research of network innovation. However, building such a platform faces lots of challenges due to its complicate requirements. In this poster, we present TUNIE, a network testbed for rapid concurrent experiment of network innovation on virtualized programmable infrastructure in China. ExpoNet provides end-to-end slice including wired and wireless components, which integrates both software- and hardware-based router virtualization technologies to provide a flexible approach to configure and customize both the control plane and data plane while satisfying various experiment requirements. In the wireless part, we have a sensor testbed including 100 wireless sensor nodes, and a WiFi testbed. In the wired part, we have setup one OpenFlow network, and two virtualization testbed based on multi-core servers and FPGA data plane. In our current platform implementation, we have four sites, two sites in Tsinghua University, one another university of BUPT, and one in China Union, one of the largest Service Providers in China. We have setup a Federation plan to extend our platform with other Universities and companies like HUST, Huawei, etc.

More Information:

http://166.111.66.197:81/Main/LabTeams


Applying a Distributed Security Sensor Network to GENI (HiveMind)

Sean Peisert, University of California, Davis (PI)
Matt Bishop, University of California, Davis
Steven Templeton, University of California, Davis
Carrie Gates, CA Labs (CoPI)

GENI Project:

HiveMind

More Information:

http://hivemind.cs.udavis.edu/


Taiwan Integrated Research Network (iGENI)

Chu-Sing Yang, National Cheng Kung University (NCKU)
Mon-Yen Luo, National Kao Hsiung University of Applied Science (KUAS)
Te-Lung Liu, National Center for High Performance Computing (NCHC)
Robert Ricci, University of Utah
Joe Mambretti, Northwestern University
Jim Chen, Northwestern University
Fei Yeh, Northwestern University
Alan Verlo, University of Illinois, Chicago
Maxine Brown, University of Illinois, Chicago
Tom DeFanti, University of California, San Diego

Abstract

One of the international partner projects for iGENI in Taiwan, the National Science Council/Taiwan funded the National Telecommunication Project: Study and Deployment of Network Virtualization Architecture(NCKU,KUAS and other universities) has initiated the development and deployment of a new network virtualization architecture on a national research/education backbone: TWAREN (NCHC). In addition to this collaboration project, iGENI also worked with ProtoGENI team to implement a direct connection between ProtoGENI and network research infrastructure in Taiwan, which is enabling an enhanced partnership between GENI community and the Taiwan network research communities.

GENI Project:

IGENI
ProtoGENI

More Information:

http://www.icair.org/


Trema; An Open Source OpenFlow Controller Platform

Hideyuki Shimonishi, System Platforms Research Laboratories, NEC Corporation
Yasunobu Chiba, System Platforms Research Laboratories, NEC Corporation
Yasuhito Takamiya, System Platforms Research Laboratories, NEC Corporation
Kazushi Sugyo, System Platforms Research Laboratories, NEC Corporation

Abstract

  • Trema is a free OpenFlow controller platform (GPL v2)
    • Assists anyone who wants to develop his/her own OpenFlow controller
    • Not targeted for any specific OpenFlow controller implementation
  • Trema allows to implement OpenFlow controllers in C and Ruby
  • Trema provides:
    • Various basic libraries on which you can build your own OpenFlow controller
    • Integrated network emulator and developing environment
  • Contact

More Information:

http://trema.github.com/trema/doc/Trema_GEC11_poster.pdf
http://trema.github.com/trema/
https://github.com/trema/trema/wiki


TransCloud (GENICloud)

*NO AFFILIATIONS GIVEN*

Alvin AuYoung
Andy Bavier
Jessica Blaine
Jim Chen, Northwestern University
Yvonne Coady
Paul Muller
Joe Mambretti, Northwestern University
Chris Matthews, University of Victoria, Canada
Rick McGeer
Chris Pearson
Alex Snoeren
Fei Yeh, Northwestern University
Marco Yuen

Abstract Transcontinental federation of cloud systems.

GENI Project:

GENICloud


Measurement Data Archive (DigitalObjectRegistry)

Giridhar Manepalli, CNRI
Prasad Calyam, Ohio Supercomputing Center

Abstract

Corporation for National Research Initiatives (CNRI) will be demonstrating the functionality of the proposed Measurement Data Archive, which is implemented using the Digital Object Architecture.

The Measurement Data Archive prototype system consists of two components: 1) User Workspace and 2) Object Archive. The User Workspace component is an entry point for users (e.g., experimenters, instrumentation researchers, etc.) to store and transfer measurement data, which could be in a variety of forms (e.g., formatted datasets, raw files, etc.). Data and metadata files managed in the user workspace can be archived for long-term storage in an Object Archive. Once data is archived, a persistent and unique identifier is created.

GENI Project:

DigitalObjectRegistry

More Information:

http://mda.doregistry.org/


Integration of LEARN with GENI Infrastructures using ORCA: VLAN Assignments and Cluster Deployment Plans - Collaborative Efforts on Measurements: IF-MAP for GENI and Collaboration with IMF

Deniz Gurkan, University of Houston
Karthik Ram Narumanchi, University of Houston
Anand Arun Daga, University of Houston
Ilia Baldine, RENCI
Rick Kagan, Infoblox
Ben Warren, Infoblox

Abstract

LEARN regional optical network in Texas has been demonstrated with VLAN assignments to reach four major institutions during GEC10 (University of Houston, University of Texas at Austin, Texas A&M University, and Rice University). Planned deployment of clusters to two end points is presented (at University of Houston and Rice University). In addition, the feasibility and applicability of IF-MAP (Trusted Network Computing's Interface Metadata Access Point architecture) to the I&M services in GENI has been presented. A collaborative initiative to deploy IMF's optical physical layer monitoring software in perfSONAR to the LEARN nodes is in progress.

GENI Project:

ORCA and IMF

More Information:

http://groups.geni.net/geni/wiki/LEARN


DDoS Attack Detection & DoS Attacks Exploiting WiMAX System Parameters

Ilker Ozcelik, Holcombe Department of Electrical & Computer Engineering
Lu Yu, Clemson University

Abstract

The poster comprises two parts. In part one, we are collecting the Internet traffic signature on OpenFlow to use as backgroutnd traffic. By using the real background traffic, we are investigating the effectiveness of theoretical DDoS attack detection techniques on GENI. We are also trying to evaluate our proposed equation of necessary traffic for DDoS attack. Part two focuses on analyzing DoS attacks that exploit WiMAX system parameter settings. We concentrate on parameters concerning bandwidth contention resolution in IEEE 802.16 standards. We use analysis of variance (ANOVA) to find how parameter settings affect the ability of DoS attackers to monopolize network bandwidth. We are carrying out a DoS attack against WiMAX on GENI ORBIT and collecting the data used for ANOVA.


Evaluating Schemes for Adapting to Cloud Dynamics using GENI

Ashiwan Sivakumar, Purdue University
Shankaranarayanan PN, Purdue University
Mohammad Hajjat, Purdue University
Dr. Sanjay Rao, Purdue University

Abstract

Enterprises are increasingly deploying their applications in the cloud given the cost-saving advantages, and the potential to geo-distribute applications to ensure resilience and better service experience. Latency and availability are critical with such performance sensitive applications. A key problem then is to meet the stringent response time requirements of enterprise applications in the cloud. We build a system that we term Dealer which for each component, dynamically splits transactions among its replicas in different data-centers. It adapts to sudden changes in delay across components and routes requests to replicas of the components in a different data-center. In doing so, Dealer seeks to minimize user response times, and takes component performance, as well as intra-data- center and inter-data-center communication latencies into account. We have integrated the system with a performance sensitive trading application called Daytrader in GENI.
Our approach to evaluate the system makes use of the controlled and repeatable environment provided by GENI. The experiments that we have conducted on GENI aim at emulating sudden spikes in delay between components. We have studied the dynamic response time of Dealer by subjecting it to a Step Up input reference waveform. We have also compared the user response times in a Multi cloud environment on ProtoGENI with and without dealer. We present the results of the evaluation experiments conducted on GENI.

More Information:

http://docs.lib.purdue.edu/cgi/viewcontent.cgi?article=1415&context=ecetr


Leveraging and Abstracting Measurements with PerfSONAR (LAMP)

Guilherme Fernandes, University of Delaware
Ezra Kissel, University of Delaware
Matthew Jaffee, University of Delaware
Martin Swany, University of Delaware
Jason Zurawski, Internet2
Matt Zekauskas, Internet2
Eric Boyd, Internet2

GENI Project:

LAMP


GENI Meta Operation Center (GMOC)

Camilo Viecco, Indiana University, Global Research NOC

Abstract

GMOC is now providing more operations support, including tickekting, documentation, measurements and a protected database. We have also done another emergency shutdown drill and are working to improve the process.

GENI Project:

GENIMetaOps

More Information:

http://gmoc-db.grnoc.iu.edu/protected
http://gmoc.grnoc.iu.edu/
https://tick.globalnoc.iu.edu/fp_tools/public_ticket_viewer/


A New Generation Network Architecture to Accommodate Virtual Network Application Service Providers

Eiji Kawai, National Institute of Information and Communications Technology (NICT), Japan
Shuji Ishii, National Institute of Information and Communications Technology (NICT), Japan
Hiroaki Yamanaka, National Institute of Information and Communications Technology (NICT), Japan
Katsuyoshi Iida, Tokyo Institute of Technology, Japan
Masayoshi Shimamura, Tokyo Institute of Technology, Japan
Takuya Omizo, Tokyo Institute of Technology, Japan
Masato Tsuru, Kyushu Institute of Technology, Japan

Abstract

An essential issue in the future Internet is how to efficiently manage the network and computational resources shared by a variety of application services with different QoS requirements over multiple diverse infrastructural networks. Network virtualization is a promising approach but further studies to develop an effective and practical architecture are required. Our poster presents an outline of a proposed architecture aiming to efficiently accommodate heterogeneous and numerous virtual network application service providers assuming the use of OpenFlow-based technology. In particular, the architecture focuses on the following features: (1) OpenFlow network virtualization in a large-scale testbed environment, (2) management of resources by a meta-resource provider to accommodate diverse QoS requirements and dynamic resource status over infrastructural network domains, and (3) distributed information management of network and computational resources based on perfSONAR technology.

Keywords:

  • Future Internet
  • New generation network architecture
  • Network Virtualization
  • OpenFlow
  • perfSONAR

Infinity: In-Network Storage for Mobile Devices

Yudong Gao, University of Michigan

Abstract

Data accessed on the mobile devices is exploding, but current mobile applications do a poor job in conserving energy while ensuring good performance, to satisfy the rapid increase in the frequency and volume of data access. The cloud services accessed by these applications consider neither the role of mobile operator’s network nor the mobile device state, leading to poor application performance and wastage of network resources. Today’s mobile operator (MO)’s networks are no longer “dumb pipes” but are connected to data centers with large amount of resources. We argue that this disruptive change makes MO’s network increasingly resemble a cloud computing infrastructure. We propose a storage platform called Infinity that can be used by service providers to effectively exploit the mobile operator’s network, while saving energy on the mobile devices.

GENI Project:

EAGER: Enabling Mobile Services through In-network Storage and Computation - Evaluation using the GENI Infrastructure.


OpenFlow Campus Trial at Clemson: An OpenFlow Service for Seamless Enhancement of Data Transport Throughput (OFCLEM)

Aaron Rosen, Clemson University
Kuang-Ching Wang, Clemson University
Jim Pepin, Clemson University
Daniel Schmiedt, Clemson University

Abstract

In a software defined network, packet forwarding methods can be changed on the fly to suit the needs of different traffic types. Not only can such a network redirect traffic's path, but it can also inject software agents in the forwarding path to provide additional services. At Clemson, we developed a solution to seamlessly enhance end-to-end data transport throughput across wide area networks. By decoupling end user and the core network's choice of transport protocols, the network provider can seamlessly enhance end users' experienced performance without requiring them to upgrade to unfamiliar new transport protocols.

GENI Project:

OFCLEM

More Information:

http://openflow.clemson.edu/gec11-poster.pdf
http://openflow.clemson.edu/


Scalable Sensing Service (S3MONITOR)

Sonia Fahmy, Purdue University
Ethan Blanton, Purdue University
Sumit Kala, HP Labs

Abstract

The Scalable Sensing Service (S3 Monitor) provides basic management services for users to take controlled measurements, e.g., available bandwidth or packet loss, between GENI nodes. A web interface is provided to the user for scheduling and initiating measurements, managing ongoing measurements, and retrieving measurement results.

GENI Project:

Scalable, Extensible, and Safe Monitoring of GENI: ScalableMonitoring

More Information:

http://groups.geni.net/geni/attachment/wiki/ScalableMonitoring/gec11-onepage.pdf


SPP Deployment and Named Data Networking Research

Patrick Crowley (PI), Washington University
Jon Turner (PI), Washington University
John DeHart, Washington University
Mart Haitjema, Washington University
Shakir James, Washington University
Jyoti Parwatikar, Washington University
Michael Wilson, Washington University
Haowei Yuan, Washington University

Abstract

Washington University Internet Scale Overlay Hosting/SPP Deployment

More Information:

http://wiki.arl.wustl.edu/index.php/Internet_Scale_Overlay_Hosting