For this reason, when the wavefront quality requirement are met, it is an alternative to aperture masking interferometry that can be executed without a mask while retaining phase error rejection properties.
The observables are computed through linear algebra from the Fourier transform of direct images.
They can then be used for statistical testing, model fitting, or image reconstruction.
In order to extract kernel-phases from an image, some requirements must be met: Deviations from these requirements are known to be acceptable, but lead to observational bias that should be corrected by the observation of calibrators.
The method relies on a discrete model of the instrument's pupil plane and the corresponding list of baselines to provide corresponding vectors
When the wavefront error in the pupil plane is small enough (i.e. when the Strehl ratio of the imaging system is sufficiently high), the complex amplitude associated to the instrumental phase in one point of the pupil
to the image plane Fourier phase as a linear transformation described by the matrix
The technique was first used in the re-analysis of archival images[2] from the Hubble Space Telescope where it enabled the discovery of a number of brown dwarf in close binary systems.
The technique is used as an alternative to aperture masking interferometry,[3] especially for fainter stars because it does not require the use of masks that typically block 90% of the light, and therefore allows higher throughput.
It is also considered to be an alternative to coronagraphy for direct detection of exoplanets[4] at very small separations (below
) where coronagraphs are limited by the wavefront errors of adaptive optics.
A Python library called xara is available on GitHub and maintained by Frantz Martinache to facilitate the extraction and interpretation of kernel-phases.
The KERNEL project, has received funding from the European Research Council to explore the potential of these observables for a number of use-cases, including direct detection of exoplanets, image reconstruction, and image plane wavefront sensing for adaptive optics.