Abstract
We introduce the use of Super-Gaussian apodizing functions in the telescope pupil plane and/or the coronagraph Lyot plane to improve the imaging contrast in ground-based coronagraphs. We describe the properties of the Super-Gaussian function, we estimate its second-order moment in the pupil and Fourier planes and we check it as an apodizing function. We then use Super-Gaussian function to apodize the telescope pupil, the coronagraph Lyot plane or both of them. The result is that a proper apodizing masks combination can reduce the exoplanet detection distance up to a 45% with respect to the classic Lyot coronagraph, for moderately aberrated wavefronts. Compared to the prolate spheroidal function the Super-Gaussian apodizing function allows the planet light up to 3 times brighter. An extra help to increase the extinction rate is to perform a frame selection (Lucky Imaging technique). We show that a selection of the 10% best frames will reduce up to a 20% the detection angular distance when using the classic Lyot coronagraph but that the reduction is only around the 5% when using an apodized coronagraph.
Highlights
Apodization has been a relevant topic for the last decades
Diameter and r0 the Fried parameter. This condition can be satisfied on visible or infrared bands depending on the telescope size and the degree of compensation achieved by the Adaptive Optics system
Data correspond to clear (HEP), Super-Gaussian apodized (SGP), and prolate spheroidal apodized (PSP) telescope pupils, and for hard-edge and Super-Gaussian apodized Lyot stops (HEL and SGL)
Summary
Apodization has been a relevant topic for the last decades. In 1978 Harris [1] published an extensive review of apodizing functions for improving signal detectability. We checked that the use of the average Super-Gaussian mask was more efficient than the use of individual adaptive masks This result encouraged us to check the behavior of the Super-Gaussian transmission profile as an apodizing function for both the entrance pupil of the telescope and the Lyot stop. We restricted our analysis to ground based telescopes in which the condition D/r0 < 8 is fulfilled, where D is the pupil diameter and r0 the Fried parameter This condition can be satisfied on visible or infrared bands depending on the telescope size and the degree of compensation achieved by the Adaptive Optics system.
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