Terahertz computed tomography (THz-CT) is a popular technique for nondestructive testing. Traditional methods of THz-CT originated from x-ray CT (X-CT), and both are based on the Radon transform. However, those methods only consider the rays propagating along straight lines but neglect the scattering behavior of terahertz waves-particularly refraction and corner scattering, which may result in poor reconstructions. At present, existing research has primarily focused on refractive behavior, but the impact of corner scattering on THz-CT cannot be ignored. This paper proposes an inversion method based on the generalized plane wave spectrum, and it can account for the corner scattering characteristics of layer structures that consist of (semi-)infinite layers. Considering the field differences arising from an ideal plane wave used in theoretical analysis vs a Gaussian beam employed in experiments, this paper proposes a field correction that effectively minimizes the discrepancies between these two conditions. To validate the proposed inversion method, a corner scattering field test system was designed and constructed. This paper prepared a PEC block as the basic model and used the model to compare the proposed inversion method with the ordered subsets expectation maximization method. The accuracy of the proposed method is well validated by the experimental comparison. In addition, this paper also prepared a PEC stripe and dielectric blocks wrapped in a foam box. The inversion results demonstrate that the proposed method is accurate for PEC samples and feasible for dielectric blocks.
Feng et al. (Sun,) studied this question.