Imaging Cloaked Objects: Diffraction Tomography of Realistic Invisibility Devices

Abstract

AbstractInvisibility cloaks have become one of the most outstanding developments among the wide range of applications in the field of metamaterials. So far, most efforts in invisibility science have been devoted to achieving practically realizable cloak designs and to improving the effectiveness of these devices in reducing their scattering cross‐section (SCS), a scalar quantity accounting for the total electromagnetic energy scattered by an object. However, little attention has been paid to the opposite side of the technology: the development of more efficient techniques for the detection of invisibility devices. For instance, the SCS ignores the phase change introduced by the cloak, as well as the angular dependence of the incident and scattered waves. Here, a different path is proposed, which takes advantage of the smarter way in which diffraction tomography processes all this overlooked information to improve the efficiency in unveiling the presence of invisibility devices. This approach not only results in a considerable sensitivity enhancement in the detection of different kinds of cloaks based on both scattering cancellation and transformation optics, but also enables us to obtain images depicting the approximate shape and size of the cloak. The proposed method can be extended to the detection of sound cloaks.