Abstract
This paper introduces a near-field measurement system concept for the fast testing of linear arrays suited for mass production scenarios where a high number of nominally identical antennas needs to be measured. The proposed system can compute the radiation pattern, directivity and gain on the array plane, as well as the array complex feeding coefficients in a matter of seconds. The concept is based on a multi-probe antenna array arranged in a line which measures the near field of the antenna under test in its array plane. This linear measurement is postprocessed with state-of-the-art single-cut transformation techniques. To compensate the lack of full 3D information, a previous complete characterization of a “Gold Antenna” is performed. This antenna is nominally identical to the many ones that will be measured with the proposed system. Therefore, the data extracted from this full characterization can be used to complement the postprocessing steps of the single-cut measurements. An X-band 16-probe demonstrator of the proposed system is implemented and introduced in this paper, explaining all the details of its architecture and operation steps. Finally, some measurement results are given to compare the developed demonstrator with traditional anechoic measurements, and show the potential capabilities of the proposed concept to perform fast and reliable measurements.
Highlights
Far-Field (FF) radiation pattern is one of the most important parameters to evaluate antenna performance
This paper presents an antenna measurement system which combines the versatility of Multi-Probe Measurement Systems (MPMS)’s with the principles of Single-Cut Transformation (SCT) NF to FF transformation for measurement time enhancement
A linear array of 8 printed dipoles arranged in a column operating at X-band has been manufactured for this purpose
Summary
Far-Field (FF) radiation pattern is one of the most important parameters to evaluate antenna performance. In this context, it is convenient to lose some accuracy in exchange of a measurement time reduction by performing a one-by-one Single-Cut Transformation (SCT) [8,9,10]. A switching matrix is connected to the probe array to perform the complete measurement process virtually at once This set-up allows to retrieve the FF radiation pattern of linear arrays on the array cut, to evaluate its gain and directivity as well as to estimate the array complex feeding coefficients. This system is suited to mass production scenarios where a high number of nominally identical antennas needs to be measured This concept may be extended to any polarization and AUTs by adapting the SCT-MPMS and its postprocessing steps.
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