Spectral Subtraction: A New Approach to Remove Low‐ and High‐Order Speckle Noise

Dou

Zhang

et al. 2012

ApJ

Self Cite

Future ground-based direct imaging of exoplanets depends critically on high-contrast coronagraph and wave-front manipulation. A coronagraph is designed to remove most of the unaberrated starlight. Because of the wave-front error, which is inherit from the atmospheric turbulence from ground observations, a coronagraph cannot deliver its theoretical performance, and speckle noise will limit the high-contrast imaging performance. Recently, extreme adaptive optics, which can deliver an extremely high Strehl ratio, is being developed for such a challenging mission. In this publication, we show that barely taking a long-exposure image does not provide much gain for coronagraphic imaging with adaptive optics. We further discuss a speckle subtraction and suppression technique that fully takes advantage of the high contrast provided by the coronagraph, as well as the wave front corrected by the adaptive optics. This technique works well for coronagraphic imaging with conventional adaptive optics with a moderate Strehl ratio, as well as for extreme adaptive optics with a high Strehl ratio. We show how to substrate and suppress speckle noise efficiently up to the third order, which is critical for future ground-based high-contrast imaging. Numerical simulations are conducted to fully demonstrate this technique.

“…This well-known speckle n 1 is discussed by many authors (Perrin et al 2003;Bloemhof 2004Bloemhof , 2007Ren & Wang 2006).…”

Section: Wave-front Error Properties and Image Rotation Subtractionmentioning

confidence: 91%

Section: Wave-front Error Properties and Image Rotation Subtractionmentioning

confidence: 99%

Section: Wave-front Error Properties and Image Rotation Subtractionmentioning

confidence: 99%

See 1 more Smart Citation

Speckle Noise Subtraction and Suppression With Adaptive Optics Coronagraphic Imaging

Dou

Zhang

et al. 2012

ApJ

Self Cite

“…The residual speckle noise induced by the wave-front error can be further subtracted by using the Spectral Subtraction Algorithm (SSA) ( The SSA can provide an extra contrast gain of 10 -4 ~ 10 -5 at the 0.9 Strehl ratio (Ren & Wang 2006). Fig.…”

Section: Wave-front Error and Speckle Attenuationmentioning

confidence: 99%

“…Ren & Wang 2006) that is a further development of differential imaging(Marois et al 2000). For space-based exoplanet imaging for the detection of life, there are a number of biomarkers that have strong spectral features, which could be used for differential imaging.…”

mentioning

confidence: 99%

Estimated performance of a symmetric nulling coronagraph for exoplanet imaging

Space Telescopes and Instrumentation I: Optical, Infrared, and Millimeter

Serabyn

2006

The direct detection of the earth-similar planets nearby bright stars needs high-contrast imaging. We proposed a nulling coronagraph that can, in principle, totally cancel the on-axis point-source starlight for broadband high-contrast imaging. The nulling coronagraph also features close angular distance imaging and high throughput. Equipped with a telescope with only 1.5-m aperture size, it has the potentiality to be able to resolving and directly detecting earth-similar planets at 0.1″ (1 λ/D) close-distance in the visible wavelength range. The requirement for a small telescope is a significant advantage for future space missions. We discuss the working principle, instrument realization, error and sensitivity analysis, and the estimated performance of the nulling coronagraph.

Focal plane wave-front sensing algorithm for high-contrast imaging

Dou

Sci. China Ser. G-Phys. Mech. Astron.

Zhu

et al. 2009

Self Cite

High-contrast imaging provided by a coronagraph is critical for the direction imaging of the Earth-like planet orbiting its bright parent star. A major limitation for such direct imaging is the speckle noise that is induced from the wave-front error of an optical system. We derive an algorithm for the wave-front measurement directly from 3 focal plane images. The 3 images are achieved through a deformable mirror to provide specific phases for the optics system. We introduce an extra amplitude modulation on one deformable mirror configuration to create an uncorrelated wave-front, which is a critical procedure for wave-front sensing. The simulation shows that the reconstructed wave-front is consistent with the original wave-front theoretically, which indicates that such an algorithm is a promising technique for the wave-front measurement for the high-contrast imaging.high-contrast imaging, multi-image algorithm, speckle nulling technique, wave-front sensing Discovering life on another planet will be one of the most important scientific advances of this century. The search for life requires the ability to detect photons directly from planets and the use of spectroscopy to analyze physical and atmospheric conditions. The direct detection of earth-like low-mass planets is extremely challenging since the brightness ratio between an Earthlike planet and its parent star is in the order of 10 −9 in the visible, and the diffraction of starlight is much stronger than the nearby planet image. A high-contrast imaging coronagraph can be used to suppress the diffraction light from the bright star, so that the nearby planet can be detected in the ideal case [1][2][3] . However, the actual performance of a high-contrast coronagraph is limited by the wave-front error of the coronagraphic system, which induces speckle noise [4] . Because of the large bright difference, the local speckles are much brighter than the planet image, thus making the direct imaging impossible. To eliminate the wave-front error induced speckle noise, the speckle nulling technique [5] is introduced by the using of a deformable mirror (DM) to create a local dark zone that can be served as a discovery area for the planet imaging. It is expected to gain an extra contrast improvement of 10 −2 -10 −3 after eliminating the speckle noise surrounding the star image.The most important procedure for the dark zone correction is the measurement of the wave-front error. One approach is to reconstruct the wave-front directly from a number of images measured on the focal plane. Recently, Borde & Traub [6] and Give'on et al. [7] provided different algorithms that can reconstruct the wave-front error from 3 focal plane images. Although the focal plane wave-front sensing is a promising technique, it is found that some of their assumptions for the phase reconstruc-