Title :
Experimental Demonstration of Complex Image Theory and Application to Position Measurement
Author :
Arumugam, Darmindra D. ; Griffin, Joshua D. ; Stancil, Daniel D.
Author_Institution :
Disney Res., Pittsburgh, PA, USA
fDate :
7/3/1905 12:00:00 AM
Abstract :
Measurements of the magnetoquasistatic fields generated from a magnetic dipole (an electrically small current loop) located above the Earth are presented and compared to calculations using complex image theory. With a horizontal (i.e., the surface normal parallel to the Earth) emitting loop located at a height of h and a copolarized horizontal receiving loop located at a height of z ≥ 0, coupling between the dipoles was measured for distances up to 50 m along a direction perpendicular to the surface normal axes of the loops. Inverting the theoretical expressions to estimate the distance from measured field values resulted in peak and rms distance estimation errors of 23.01 and 11.74 cm, respectively, for distances between 1.3 and 34.2 m. Received signals were not strongly affected by the proximity of a group of people even when the line of sight was obstructed.
Keywords :
magnetic field measurement; position measurement; radio tracking; radiofrequency measurement; RMS distance estimation; complex image theory; distance 1.3 m to 34.2 m; distance 11.74 cm; distance 23.01 cm; horizontal emitting loop; magnetic dipole; magnetoquasistatic field measurement; position measurement; wireless position tracking; Conductivity; Frequency measurement; Magnetic resonance imaging; Patents; Receivers; Skin; Voltage measurement; Electromagnetic fields; magnetoquasistatics; radio position measurement; radio tracking;
Journal_Title :
Antennas and Wireless Propagation Letters, IEEE
DOI :
10.1109/LAWP.2011.2136370
