Add to ORKGPhase retrieval, i.e., the reconstruction of phase information from intensity information, is a central problem in many optical systems. Imaging the emission from a point source such as a single molecule is one example. Here, we demonstrate that a deep residual neural net is able to quickly and accurately extract the hidden phase for general point spread functions (PSFs) formed by Zernike-type phase modulations. Five slices of the 3D PSF at different focal positions within a two micrometer range around the focus are sufficient to retrieve the first six orders of Zernike coefficients
The non-linear equation of phase retrieval appears in many different scenarios, from X-ray imaging t...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
High-contrast imaging instruments are today primarily limited by non-common path aberrations appeari...
Phase retrieval, i.e., the reconstruction of phase information from intensity information, is a cent...
Phase retrieval, i.e., the reconstruction of phase information from intensity information, is a cent...
Phase retrieval, i.e., the reconstruction of phase information from intensity information, is a cent...
In high-contrast imaging applications, such as the direct imaging of exoplanets, a coronagraph is us...
Deep learning has been proven to achieve ground-breaking accuracy in various tasks. In this paper, w...
Phase retrieval approaches based on deep learning (DL) provide a framework to obtain phase informati...
Phase retrieval approaches based on deep learning (DL) provide a framework to obtain phase informati...
Adaptive optics are widely used to correct the wavefront distortion imposed by atmospheric turbulenc...
Adaptive optics are widely used to correct the wavefront distortion imposed by atmospheric turbulenc...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
The non-linear equation of phase retrieval appears in many different scenarios, from X-ray imaging t...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
High-contrast imaging instruments are today primarily limited by non-common path aberrations appeari...
Phase retrieval, i.e., the reconstruction of phase information from intensity information, is a cent...
Phase retrieval, i.e., the reconstruction of phase information from intensity information, is a cent...
Phase retrieval, i.e., the reconstruction of phase information from intensity information, is a cent...
In high-contrast imaging applications, such as the direct imaging of exoplanets, a coronagraph is us...
Deep learning has been proven to achieve ground-breaking accuracy in various tasks. In this paper, w...
Phase retrieval approaches based on deep learning (DL) provide a framework to obtain phase informati...
Phase retrieval approaches based on deep learning (DL) provide a framework to obtain phase informati...
Adaptive optics are widely used to correct the wavefront distortion imposed by atmospheric turbulenc...
Adaptive optics are widely used to correct the wavefront distortion imposed by atmospheric turbulenc...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
The non-linear equation of phase retrieval appears in many different scenarios, from X-ray imaging t...
International audienceWe propose the deep Gauss–Newton (DGN) algorithm. The DGN allows one to take i...
High-contrast imaging instruments are today primarily limited by non-common path aberrations appeari...