Experimental validation of joint phase and amplitude wave-front sensing with coronagraphic phase diversity for high-contrast imaging

Context. The next generation of space-borne instruments dedicated to the direct detection of exoplanets requires unprecedented levels of wavefront control precision. Coronagraphic wavefront sensing techniques for these instruments must measure both the phase and amplitude of the optical aberrations using the scientific camera as a wavefront sensor. Aims. In this paper, we develop an extension of coronagraphic phase diversity to the estimation of the complex electric field, that is, the joint estimation of phase and amplitude. Methods. We introduced the formalism for complex coronagraphic phase diversity. We have demonstrated experimentally on the Tr\`es Haute Dynamique testbed at the Observatoire de Paris that it is possible to reconstruct phase and amplitude aberrations with a subnanometric precision using coronagraphic phase diversity. Finally, we have performed the first comparison between the complex wavefront estimated using coronagraphic phase diversity (which relies on time-modulation of the speckle pattern) and the one reconstructed by the self-coherent camera (which relies on the spatial modulation of the speckle pattern). Results. We demonstrate that coronagraphic phase diversity retrieves complex wavefront with subnanometric precision with a good agreement with the reconstruction performed using the self-coherent camera. Conclusions. This result paves the way to coronagraphic phase diversity as a coronagraphic wave-front sensor candidate for very high contrast space missions.

[1]  A. Labeyrie,et al.  The Four-Quadrant Phase-Mask Coronagraph. I. Principle , 2000 .

[2]  Ping Zhou,et al.  Analysis of wavefront propagation using the Talbot effect. , 2010, Applied optics.

[3]  M. Shao,et al.  HIGH-DYNAMIC-RANGE IMAGING USING A DEFORMABLE MIRROR FOR SPACE CORONOGRAPHY , 1995, astro-ph/9502042.

[4]  L M Mugnier,et al.  High-order myopic coronagraphic phase diversity (COFFEE) for wave-front control in high-contrast imaging systems. , 2013, Optics express.

[5]  R. Galicher,et al.  Wavefront error correction and Earth-like planet detection by a self-coherent camera in space , 2008, 0807.2467.

[6]  E. Church Fractal surface finish. , 1988, Applied optics.

[7]  Robert A. Gonsalves,et al.  Phase Retrieval And Diversity In Adaptive Optics , 1982 .

[8]  Marie-Thérèse Velluet,et al.  Laser beam complex amplitude measurement by phase diversity. , 2014, Optics express.

[9]  N. Jeremy Kasdin,et al.  Recursive starlight and bias estimation for high-contrast imaging with an extended Kalman filter , 2016, 1602.02044.

[10]  R. Galicher,et al.  Estimation and correction of wavefront aberrations using the self-coherent camera: laboratory results , 2013 .

[11]  G. Swartzlander,et al.  Optical vortex coronagraph. , 2005, Optics letters.

[12]  Kjetil Dohlen,et al.  Active optics methods for exoplanet direct imaging - Stress polishing of supersmooth aspherics for VLT-SPHERE planet finder , 2012 .

[13]  Laurent M. Mugnier,et al.  Phase Diversity: A Technique for Wave-Front Sensing and for Diffraction-Limited Imaging , 2006 .

[14]  Jérôme Idier,et al.  Bayesian Approach to Inverse Problems: Idier/Bayesian , 2010 .

[15]  L. Mugnier,et al.  Calibration of NAOS and CONICA static aberrations - Application of the phase diversity technique , 2003 .

[16]  J. Idier Bayesian Approach to Inverse Problems: Idier/Bayesian , 2010 .

[17]  Lyu Abe,et al.  Phase Knife Coronagraph II - Laboratory results , 2003 .

[18]  Pierre Baudoz,et al.  The Four Quadrant Phase Mask Coronagraph and its avatars , 2007 .