%0 Journal Article %A Moghadas, Davood %A André, Frédéric %A Bradford, John H. %A van der Kruk, Jan %A Vereecken, Harry %A Lambot, Sébastien %T Electromagnetic induction antenna modelling using a linear system of complex antenna transfer functions %D 2012 %J Near Surface Geophysics, %V 10 %N 3 %P 237-247 %@ 1873-0604 %R https://doi.org/10.3997/1873-0604.2012002 %I European Association of Geoscientists & Engineers, %X ABSTRACT The quantitative retrieval of soil apparent electrical conductivity using electromagnetic induction (EMI) has remained limited due to strong simplifications regarding EMI antenna modelling. In this paper, a new technique for EMI antenna modelling is applied for the common‐offset EMI systems. The EMI system is efficiently described using global transmission and reflection coefficients and Green's functions are used to describe wave diffusion for horizontal and vertical dipole modes. We performed EMI measurements along a 180‐metre‐long transect with two different instrument heights above the soil surface, as well as with different orientations and frequencies. To ensure proper retrieval of the soil apparent electrical conductivity, the reference values were obtained from electrical conductivity data measured from 11 undisturbed soil cores taken along the EMI transect. The apparent electrical conductivity values calculated by applying the proposed model have a good agreement with reference values, however some discrepancies can be observed that are mainly attributed to the presence of local heterogeneities and also errors due to the variations in the height of the EMI instruments above the ground. The proposed method appears to be promising for quantitative retrieval of soil apparent electrical conductivity and resolving calibration issues that are typically encountered using EMI. In addition, the model calibration (antenna transfer functions determination) was successfully accomplished using conductivity values measured from the soil cores. %U https://www.earthdoc.org/content/journals/10.3997/1873-0604.2012002