Speckle Suppression with the Project 1640 Integral Field Spectrograph
Abstract
Project 1640 is a high-contrast imaging instrument recently commissioned at Palomar observatory. A combination of a coronagraph with an integral field spectrograph (IFS), Project 1640 is designed to detect and characterize extrasolar planets, brown dwarfs, and circumstellar material orbiting nearby stars. In this paper, we present our data processing techniques for improving upon instrument raw sensitivity via the removal of quasi-static speckles. Our approach utilizes the chromatic image diversity provided by the IFS in combination with the locally-optimized combination of images (LOCI) algorithm to suppress the intensity of residual contaminating light in close angular proximity to target stars. We describe the Project 1640 speckle suppression pipeline (PSSP) and demonstrate the ability to detect companions with brightness comparable to and below that of initial speckle intensities using on-sky commissioning data. Our preliminary results indicate that suppression factors of at least one order of magnitude are consistently possible, reaching contrast levels of at in the H-band in 20 minutes of on-source integration time when non-common-path errors are reasonably well-calibrated. These results suggest that near-infrared contrast levels of order at subarcsecond separations will soon be possible for Project 1640 and similarly designed instruments that receive a diffraction-limited beam corrected by adaptive optics (AO) systems employing deformable mirrors with high actuator-density.
Cite
@article{arxiv.1012.4016,
title = {Speckle Suppression with the Project 1640 Integral Field Spectrograph},
author = {Justin R. Crepp and Laurent Pueyo and Douglas Brenner and Ben R. Oppenheimer and Neil Zimmerman and Sasha Hinkley and Ian Parry and David King and Gautam Vasisht and Charles Beichman and Lynne Hillenbrand and Richard Dekany and Mike Shao and Rick Burruss and Lewis C. Roberts and Antonin Bouchez and Jenny Roberts and Remi Soummer},
journal= {arXiv preprint arXiv:1012.4016},
year = {2015}
}
Comments
accepted to ApJ