Abstract
In the upper millimeter wave range above 100 GHz, the effect of array imperfections like manufacturing uncertainties and mutual antenna coupling increases, which leads to deviations from the nominal antenna positions and angle-dependent errors in direction-of-arrival (DoA) estimation. The proposed calibration procedure aims to correct the assumed array response model, based on nominal antenna positions and therefore to improve the measurement accuracy of the array. Typically, the calibration parameters are obtained by interpolating a data set consisting of calibration measurements at known angles. The required number of measurement points in the calibration procedure increases with larger array size, which makes array calibration very time-consuming and costly. In this article, a highly efficient angular array calibration procedure is proposed based on the modal wave expansion technique. After an initial theoretical formulation of the modal wave expansion followed by simulations, it is shown how the limitation of the minimum required number of measurement points in conventional calibration techniques can be eliminated. Experimental results with an antenna array at 150 GHz demonstrate that this novel approach achieves a significant reduction of the number of angular measurement points, especially for large arrays with a high channel count, without degrading the DoA estimation performance.
Highlights
P HASED arrays and millimeter-wave imaging radars are commonly used in a variety of civil and military applications [1]–[4]
Based on the measurements captured during the calibration, the array response model is adjusted, either in form of calibration parameters like antenna positions and phase offsets or non-parametrically based on angledependent reference measurements [10]
3) Minimum Number of Measurement Points The measurement results from Fig. 9 prove that the calibration based on the modal wave expansion technique provides accurate results up to an angular interval of ∆φ = 20° (3 data points)
Summary
There are mainly two different calibration approaches: array calibration using calibration sources at known locations, self-calibration methods performing a joint estimation of calibration parameters and DoAs based on the same data set [11], [13]. In order to determine a global correction matrix the number of measurement points has to be larger or equal to the number of antennas, which is disadvantageous for arrays with a high number of channels. Another method for array calibration is the interpolation of the measured radiation pattern using interpolation. In this work a fundamentally novel calibration approach based on the modal wave expansion technique is proposed. This method significantly reduces the required number of mea-. 2: Evaluation of the mode spectrum and compensation of possible antenna displacements
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