An Antennas and Propagation Approach to Improving Physical Layer Performance in Wireless Body Area Networks

A combined antennas and propagation study has been undertaken with a view to directly improving link conditions for wireless body area networks. Using tissue-equivalent numerical and experimental phantoms representative of muscle tissue at 2.45 GHz, we show that the node to node |S21| path gain performance of a new wearable integrated antenna (WIA) is up to 9 dB better than a conventional compact Printed-F antenna, both of which are suitable for integration with wireless node circuitry. Overall, the WIA performed extremely well with a measured radiation efficiency of 38% and an impedance bandwidth of 24%. Further benefits were also obtained using spatial diversity, with the WIA providing up to 7.7 dB of diversity gain for maximal ratio combining. The results also show that correlation was lower for a multipath environment leading to higher diversity gain. Furthermore, a diversity implementation with the new antenna gave up to 18 dB better performance in terms of mean power level and there was a significant improvement in level crossing rates and average fade durations when moving from a single-branch to a two-branch diversity system.

[1]  Simon L. Cotton,et al.  An experimental investigation into the influence of user state and environment on fading characteristics in wireless body area networks at 2.45 GHz , 2009, IEEE Transactions on Wireless Communications.

[2]  William Scanlon,et al.  Numerical analysis of bodyworn UHF antenna systems , 2001 .

[3]  Aleksandar Milenkovic,et al.  Journal of Neuroengineering and Rehabilitation Open Access a Wireless Body Area Network of Intelligent Motion Sensors for Computer Assisted Physical Rehabilitation , 2005 .

[4]  Norman C. Beaulieu,et al.  Analysis of equal gain diversity on Nakagami fading channels , 1991, IEEE Trans. Commun..

[5]  Ayman F. Naguib,et al.  Space–Time Codes for Wireless Communications , 2003 .

[6]  Carmen C. Y. Poon,et al.  A novel biometrics method to secure wireless body area sensor networks for telemedicine and m-health , 2006, IEEE Communications Magazine.

[7]  S. Drude,et al.  Requirements and Application Scenarios for Body Area Networks , 2007, 2007 16th IST Mobile and Wireless Communications Summit.

[8]  C. Parini,et al.  Antennas and propagation for on-body communication systems , 2007, IEEE Antennas and Propagation Magazine.

[9]  Akram Hammoudeh,et al.  Frequency domain characterization of LoS nonfading indoor wireless LAN channel employing frequency and polarization diversity in the 63.4-65.4 GHz band , 2004, IEEE Transactions on Vehicular Technology.

[10]  D. Puccinelli,et al.  Wireless sensor networks: applications and challenges of ubiquitous sensing , 2005, IEEE Circuits and Systems Magazine.

[11]  Simon L. Cotton,et al.  Characterization and modeling of on-body spatial diversity within indoor environments at 868 MHz , 2009, IEEE Transactions on Wireless Communications.

[12]  Kin-Lu Wong,et al.  Characteristics of a 2.4‐GHz compact shorted patch antenna in close proximity to a lossy medium , 2005 .

[13]  W.G. Scanlon,et al.  Characterization and Modeling of the Indoor Radio Channel at 868 MHz for a Mobile Bodyworn Wireless Personal Area Network , 2007, IEEE Antennas and Wireless Propagation Letters.

[14]  W. Stutzman,et al.  Spatial, polarization, and pattern diversity for wireless handheld terminals , 2001 .

[15]  W. Scanlon,et al.  Antennas for Over-Body-Surface Communication at 2.45 GHz , 2009, IEEE Transactions on Antennas and Propagation.

[16]  Michel Daoud Yacoub,et al.  Second-order statistics for diversity-combining techniques in Nakagami-fading channels , 2001, IEEE Trans. Veh. Technol..

[17]  C. Gabriel Compilation of the Dielectric Properties of Body Tissues at RF and Microwave Frequencies. , 1996 .

[18]  Simon L. Cotton,et al.  Spatial Diversity and Correlation for Off-Body Communications in Indoor Environments at 868 MHz , 2007, 2007 IEEE 65th Vehicular Technology Conference - VTC2007-Spring.

[19]  W. C. Jakes,et al.  Microwave Mobile Communications , 1974 .

[20]  P.S. Hall,et al.  Diversity Measurements for On-Body Communication Systems , 2007, IEEE Antennas and Wireless Propagation Letters.

[21]  Aleksandar Milenkovic,et al.  System architecture of a wireless body area sensor network for ubiquitous health monitoring , 2005 .

[22]  A.M.D. Turkmani,et al.  An experimental evaluation of the performance of two-branch space and polarization diversity schemes at 1800 MHz , 1995 .

[23]  Emad K. Al-Hussaini,et al.  Performance of MRC Diversity Systems for the Detection of Signals with Nakagami Fading , 1985, IEEE Trans. Commun..

[24]  P. Takis Mathiopoulos,et al.  Analytical level crossing rates and average fade durations for diversity techniques in Nakagami fading channels , 2002, Vehicular Technology Conference. IEEE 55th Vehicular Technology Conference. VTC Spring 2002 (Cat. No.02CH37367).

[25]  M. Stuchly,et al.  A study of the handset antenna and human body interaction , 1996 .

[26]  Julien Ryckaert,et al.  Channel model for wireless communication around human body , 2004 .

[27]  Geert Van der Plas,et al.  Ultra-wide-band transmitter for low-power wireless body area networks: design and evaluation , 2005, IEEE Transactions on Circuits and Systems I: Regular Papers.

[28]  Sweta Sneha,et al.  Patient monitoring using ad hoc wireless networks: reliability and power management , 2006, IEEE Communications Magazine.

[29]  L. Lukama,et al.  Application of three-branch polarisation diversity in the indoor environment , 2003 .

[30]  S. O. Rice,et al.  Statistical properties of a sine wave plus random noise , 1948, Bell Syst. Tech. J..