Title :
Gains For RF Tags Using Multiple Antennas
Author :
Griffin, Joshua D. ; Durgin, Gregory D.
Author_Institution :
Georgia Inst. of Technol., Atlanta
Abstract :
Backscatter radio systems, including high frequency radio frequency identification (RFID), operate in the dyadic backscatter channel - a two-way pinhole channel that has deeper small-scale fades than that of a conventional one-way channel. This paper shows that pinhole diversity is available in a rich scattering environment caused by modulating backscatter with multiple RF tag antennas - no diversity combining at the reader, channel knowledge, or signaling scheme change is required. Pinhole diversity, along with increased RF tag scattering aperture, can cause up to a 10 dB reduction in the power required to maintain a constant bit-error-rate for an RF tag with two antennas. Through examples, it is shown that this gain results in increased backscatter radio system communication reliability and up to a 78% increase in RF tag operating range.
Keywords :
antenna arrays; backscatter; error statistics; radiofrequency identification; telecommunication network reliability; wireless channels; RFID tag; backscatter radio system; bit-error-rate; communication reliability; dyadic backscatter channel; high frequency radio frequency identification; multiple antenna; pinhole channel diversity; Backscatter; Bit error rate; Diversity methods; Diversity reception; Fading; Loaded antennas; RF signals; Radio frequency; Radiofrequency identification; Scattering; Dyadic backscatter channel; RF tag; modulated backscatter; pinhole channel; pinhole diversity; probability; radio frequency identification (RFID); radio link budget;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2007.915423
