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PIER PIER B PIER C PIER M PIER Letters
2013-01-27
Near-Field Error Analysis for Arbitrary Scanning Grids Using Fast Irregular Antenna Field Transformation Algorithm
By
Muhammad Ayyaz Qureshi,

    Mr. Muhammad Ayyaz Qureshi

    Technische Universitat Munchen

    Lehrstuhl fur Hochfrequenztechnik

    Germany

    Homepage

Carsten H. Schmidt,

    Dr. Carsten H. Schmidt

    Lehrstuhl für Hochfrequenztechnik

    Technische Univerität München

    Germany

    Homepage

Thomas F. Eibert

    Dr. Thomas F. Eibert

    Lehrstuhl für Hochfrequenztechnik

    Technische Univerität München

    Germany

    Homepage

Progress In Electromagnetics Research B, Vol. 48, 197-220, 2013
doi:10.2528/PIERB12121502 | Google Scholar

Abstract
An extensive error analysis for arbitrary near-field antenna measurements is performed. Expressions are derived to estimate the far-field uncertainty using the available near-field data together with the measurement inaccuracy but, most importantly, without the knowledge of the reference far field. Error analysis techniques presented so far either assume a specific set of antennas or a specific measurement surface and are difficult to generalize. We present a generalized approach providing realistic error estimates using the recently developed Fast Irregular Antenna Field Transformation Algorithm (FIAFTA). FIAFTA utilizes equivalent plane wave sources to represent radiated antenna fields and is able to process near-field data collected on arbitrary measurement grids. The unknown plane wave coefficients are determined by solving a linear system of equations. The error model is applied to planar, cylindrical, and spherical near-field measurements and is also valid for arbitrary measurement grids. The estimated far-field uncertainties show good agreement with the real far-field errors.
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Citation
Muhammad Ayyaz Qureshi, Carsten H. Schmidt, and Thomas F. Eibert, "Near-Field Error Analysis for Arbitrary Scanning Grids Using Fast Irregular Antenna Field Transformation Algorithm," Progress In Electromagnetics Research B, Vol. 48, 197-220, 2013.
doi:10.2528/PIERB12121502
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