学术文献库

Recently, digital holographic imaging techniques (including methods with heterodyne detection) have found increased attention in the terahertz (THz) frequency range. However, holographic techniques rely on the use of a reference beam in order to obtain phase information. This letter investigates the potential of reference-free THz holographic imaging and proposes novel supervised and unsupervised deep learning (DL) methods for amplitude and phase recovery. The calculations incorporate Fresnel diffraction as prior knowledge. We first show that our unsupervised dual network can predict amplitude and phase simultaneously, thus overcoming the limitation of previous studies which could only predict phase objects. This is demonstrated with synthetic 2D image data as well as with measured 2D THz diffraction images. The advantage of unsupervised DL is that it can be used directly without labeling by human experts. We then address supervised DL -- a concept of general applicability. We introduce training with a database set of 2D images taken in the visible spectra range and modified by us numerically to emulate THz images. With this approach, we avoid the prohibitively time-consuming collection of a large number of THz-frequency images. The results obtained with both approaches represent the first steps towards fast holographic THz imaging with reference-beam-free low-cost power detection.