The Segmented Planar Imaging Detector for Electro-Optical Reconnaissance
(SPIDER) is an optical interferometric imaging device that aims to offer an
alternative to the large space telescope designs of today with reduced size,
weight and power consumption. This is achieved through interferometric imaging.
State-of-the-art methods for reconstructing images from interferometric
measurements adopt proximal optimization techniques, which are computationally
expensive and require handcrafted priors. In this work we present two
data-driven approaches for reconstructing images from measurements made by the
SPIDER instrument. These approaches use deep learning to learn prior
information from training data, increasing the reconstruction quality, and
significantly reducing the computation time required to recover images by
orders of magnitude. Reconstruction time is reduced to ∼10
milliseconds, opening up the possibility of real-time imaging with SPIDER for
the first time. Furthermore, we show that these methods can also be applied in
domains where training data is scarce, such as astronomical imaging, by
leveraging transfer learning from domains where plenty of training data are
available.Comment: 21 pages, 14 figure