• DocumentCode
    1755964
  • Title

    Physical Layer Authentication for Mobile Systems with Time-Varying Carrier Frequency Offsets

  • Author

    Weikun Hou ; Xianbin Wang ; Chouinard, Jean-Yves ; Refaey, Ahmed

  • Author_Institution
    Dept. of Electr. & Comput. Eng., Western Univ., London, ON, Canada
  • Volume
    62
  • Issue
    5
  • fYear
    2014
  • fDate
    41760
  • Firstpage
    1658
  • Lastpage
    1667
  • Abstract
    A novel physical layer authentication scheme is proposed in this paper by exploiting the time-varying carrier frequency offset (CFO) associated with each pair of wireless communications devices. In realistic scenarios, radio frequency oscillators in each transmitter-and-receiver pair always present device-dependent biases to the nominal oscillating frequency. The combination of these biases and mobility-induced Doppler shift, characterized as a time-varying CFO, can be used as a radiometric signature for wireless device authentication. In the proposed authentication scheme, the variable CFO values at different communication times are first estimated. Kalman filtering is then employed to predict the current value by tracking the past CFO variation, which is modeled as an autoregressive random process. To achieve the proposed authentication, the current CFO estimate is compared with the Kalman predicted CFO using hypothesis testing to determine whether the signal has followed a consistent CFO pattern. An adaptive CFO variation threshold is derived for device discrimination according to the signal-to-noise ratio and the Kalman prediction error. In addition, a software-defined radio (SDR) based prototype platform has been developed to validate the feasibility of using CFO for authentication. Simulation results further confirm the effectiveness of the proposed scheme in multipath fading channels.
  • Keywords
    Doppler shift; Kalman filters; fading channels; multipath channels; radio networks; radio receivers; radio transmitters; software radio; telecommunication security; CFO; Doppler shift; Kalman filtering; Kalman prediction error; SDR; mobile systems; multipath fading channels; nominal oscillating frequency; physical layer authentication; prototype platform; radio frequency oscillators; radiometric signature; receiver; signal-to-noise ratio; software defined radio; time varying carrier frequency offsets; transmitter; wireless communications devices; wireless device authentication; Authentication; Doppler shift; Estimation; Kalman filters; Physical layer; Signal to noise ratio; Wireless communication; Kalman filtering; Physical layer authentication; carrier frequency offset (CFO); hypothesis testing;
  • fLanguage
    English
  • Journal_Title
    Communications, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0090-6778
  • Type

    jour

  • DOI
    10.1109/TCOMM.2014.032914.120921
  • Filename
    6804410