Precision speckle interferometry with CMOS detector

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-09-16 DOI:arxiv-2409.10249

I. A. Strakhov, B. S. Safonov, D. V. Cheryasov

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Abstract

Speckle polarimeter (SPP) is a facility instrument of the 2.5-m telescope of the Caucasian Mountain Observatory of SAI MSU. By design it is a combination of a speckle interferometer and a dual--beam polarimeter. In 2022 we performed a major upgrade of the instrument. New version of the instrument features Hamamatsu ORCA-Quest qCMOS C15550-20UP, having subelectron readout noise, as a main detector, as opposed to EMCCD Andor iXon 897 used in previous version. Optical distortions present in the instrument are considered as they directly affect the accuracy of the speckle interferometric astrometric measurements of binary stars. We identified the Atmospheric Dispersion Compensator (ADC) as the main source of distortions which are not constant and depend on the rotational angles of ADCs prisms. Distortions are estimated using internal calibration light source and multiple binary stars measurements. Method for their correction is developed. Flux ratio estimates are subject to CMOS-specific negative factors: spatially correlated noise and flux-dependent pixel-to-pixel sensitivity difference. We suggest ways to mitigate these factors. The use of speckle transfer function measured using a reference star further improves flux ratio estimation performance. We discuss the precision of the estimates of position angle, separation and flux ratio of binary stars.

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使用 CMOS 探测器的精密斑点干涉仪

斑点偏振计（SPP）是 MSU 高加索山天文台 2.5 米望远镜的设施仪器。根据设计，它是斑点干涉仪和双光束偏振计的结合体。2022 年，我们对该仪器进行了重大升级。新版本的仪器采用了具有亚电子读出噪声的华松ORCA-Quest qCMOS C15550-20UP作为主探测器，而之前版本使用的是EMCCD Andor iXon 897。我们将大气色散补偿器（ADC）确定为畸变的主要来源，这种畸变并非恒定不变，而是取决于 ADC 棱镜的旋转角度。我们利用内部校准光源和多双星测量来估算畸变。开发了校正方法。通量比估算受制于 CMOS 特有的负面因素：空间相关噪声和与通量相关的像素间灵敏度差异。我们提出了缓解这些因素的方法。使用参考星测量的斑点传递函数可进一步提高通量比估算性能。我们讨论了双星的位置角、分离度和通量比的估计精度。

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arXiv - PHYS - Instrumentation and Methods for Astrophysics

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