Mutual Impedance Extraction and Varactor Calibration Technique for ESPAR Antenna Characterization

• Published in: IEEE transactions on antennas and propagation Vol. 54; no. 12; pp. 3713 - 3720
• Main Authors: Qing Han, Hanna, B., Inagaki, K., Ohira, T.
• Format: Journal Article
• Language: English
• Published: New York, NY IEEE 01.12.2006; Institute of Electrical and Electronics Engineers; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Adaptive arrays; Anechoic chambers; Antenna arrays; Antenna measurements; antenna radiation patterns; Antennas; Applied sciences; Arrays; Beams (radiation); Bias; Calibration; Current measurement; Diodes; Electric potential; Exact sciences and technology; Extraction; Impedance; Mathematical analysis; Mutual impedance; Radio frequency; Radiocommunications; Telecommunications; Telecommunications and information theory; Varactors; Voltage control; Near field; Performance evaluation; Directivity pattern; Adaptive arrays; High precision; Adaptive antenna arrays; Far field; Calibration; Anechoic room; Direct method; Reactance; Integrated antenna; Parasitic component; Steerable antenna; current measurement; Mutual impedance; antenna measurements; Antenna array; anechoic chambers; Antenna radiation patterns
• ISSN: 0018-926X; 1558-2221
• DOI: 10.1109/TAP.2006.886492

An extraction and calibration technique is proposed that allows electronically steerable parasitic array radiator (ESPAR) antennas to achieve high efficiency and precision in performance characterization. The proposed technique is based on a reactive-near-field measurement or direct acquisition of RF current. We present a simple formulation that requires minimal current measurements to successfully extract the mutual impedance. Currents are predicted for an arbitrary combination of bias voltages that are used to control the reactance of varactor diodes integrated with the antenna's parasitic elements. These predicted currents are compared by conducting an experiment with a seven-element ESPAR. For the bias voltage combinations that have reasonably good symmetry, the differences in relative gain, beam direction and half power beam width (HPBW) actually fall within 0.5 dB, 4deg and 9deg, respectively. Directivity patterns obtained by calculating the predicted currents are verified with those obtained by calculating the directly measured currents. Furthermore, the calculated patterns are verified through comparison with far-field measurements in a conventional anechoic chamber. The differences in beam direction and HPBW are also found to be acceptable. Using the proposed technique, the required number of measurements is reduced from 85,766,121 to just 149 for a seven-element array