2nd International IEEE/Create-Net Conference on Testbeds and Research Infrastructures for the Development of Networks and Communities

Research Article

Mapping link SNRs of wireless mesh networks onto an indoor testbed

  • @INPROCEEDINGS{10.1109/TRIDNT.2006.1649173,
        author={Jing  Lei and Roy  Yates and Larry  Greenstein and Hang  Liu},
        title={Mapping link SNRs of wireless mesh networks onto an indoor testbed},
        proceedings={2nd International IEEE/Create-Net Conference on Testbeds and Research Infrastructures for the Development of Networks and Communities},
        publisher={IEEE},
        proceedings_a={TRIDENTCOM},
        year={2006},
        month={7},
        keywords={},
        doi={10.1109/TRIDNT.2006.1649173}
    }
    
  • Jing Lei
    Roy Yates
    Larry Greenstein
    Hang Liu
    Year: 2006
    Mapping link SNRs of wireless mesh networks onto an indoor testbed
    TRIDENTCOM
    IEEE
    DOI: 10.1109/TRIDNT.2006.1649173
Jing Lei1,*, Roy Yates1,*, Larry Greenstein1,*, Hang Liu1,*
  • 1: WINLAB, Rutgers University, 671 Route 1 South, North Brunswick, NJ 08902, USA
*Contact email: michelle@winlab.rutgers.edu, ryates@winlab.rutgers.edu, ljg@winlab.rutgers.edu, hliu@winlab.rutgers.edu

Abstract

As a platform for synergistic theory-experiment exploration in the field of wireless networking, wireless testbeds have been used to facilitate a broad range of research. From the perspective of system-level wireless emulation, average link SNR is the dominant factor in the performance of a wireless link. Thus, this work seeks to develop a systematic link SNR mapping method that replicates real-world link SNRs on an indoor testbed. The challenge is to optimize the nodes' spatial configuration and transmission powers to overcome the inherent propagation differences, as expressed in terms of pathloss exponents and environmental shadowing, between the real world and a given testbed. To avoid the technical difficulty of "forward mapping" from the real world to the testbed, we have developed a reverse mapping method to turn a testbed configuration with given link SNRs into a corresponding real-world configuration. By inducing the dB link gain differences between the testbed and the real world distance-dependent path loss to have a Gaussian distribution, a close approximation to real-world log-normal shadow fading is achieved. We present results for a variety of indoor and outdoor real-world scenarios.