基于抛物面镜的积分场单元

Proceedings of the 30th International Conference on Computer Graphics and Machine Vision (GraphiCon 2020). Part 2 Pub Date : 2020-12-17 DOI:10.51130/graphicon-2020-2-4-48

Mariia Orekhova, A. Bakholdin

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引用次数: 0

摘要

最近研制出许多现代仪器和系统来研究太阳。为此，最常用的是高光谱分辨率的光谱仪器。在实现光谱分辨率的同时，实现高空间分辨率与许多科学任务息息相关。在实际应用中，利用积分场光谱技术可以同时获得高光谱分辨率和空间分辨率。本文致力于寻找集成场单元(IFU)的系统解决方案，并将其应用于太阳天文望远镜光学系统中。主镜直径D = 3 m。望远镜工作光谱范围∆λ = 390 ~ 1600 nm。整体式现场单元基于反射元件。它将尺寸为0.7500 ×1200(0.145 mm×2.327 mm)的矩形的输入字段分成8个部分，每个部分的尺寸为0.09400×9600(0.018 mm×18.617 mm)。利用抛物面镜为所有(8)通道创建IFU光学系统的可能性被展示。评估了光学系统的质量，以及渐晕对切片镜的影响。

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An Integral Field Unit Based on Parabolic Mirror

Recently many modern instruments and systems have been developed to study the Sun. For that, spectral instruments with high spectral resolution are most often used. It is relevant to achieve high spatial resolution along with spectral one for many scientific tasks. In practice, the achievement of both high spectral and spatial resolution can be done by the use of integral field spectroscopy. Current paper is devoted to searching for a system solution for an integral field unit (IFU), which will be implemented to the optical system of solar telescopecoronagraph. The diameter of the main mirror is D = 3 m. Telescope’s working spectral range is ∆λ = 390 − 1600 nm. The integral field unit is based on reflective elements. It divides the input field of a rectangular shape with a size of 0.7500 ×1200(0.145 mm×2.327 mm) into 8 parts with a size of 0.09400×9600(0.018 mm×18.617 mm) each. The possibility of creating an IFU optical system using a parabolic mirror for all (eight) channels is shown. The quality of the optical system was evaluated, as well as the effect of vignetting on the slicing mirrors.

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Proceedings of the 30th International Conference on Computer Graphics and Machine Vision (GraphiCon 2020). Part 2

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