Image recovery with the solar gravitational lens

V. Toth, S. Turyshev
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引用次数: 2

Abstract

We report on the initial results obtained with an image convolution/deconvolution computer code that we developed and used to study the image formation capabilities of the solar gravitational lens (SGL). Although the SGL of a spherical Sun creates a greatly blurred image, knowledge of the SGL's point-spread function (PSF) makes it possible to reconstruct the original image and remove the blur by way of deconvolution. We discuss the deconvolution process, which can be implemented either with direct matrix inversion or with the Fourier quotient method. We observe that the process introduces a "penalty" in the form of a reduction in the signal-to-noise ratio (SNR) of a recovered image, compared to the SNR at which the blurred image data is collected. We estimate the magnitude of this penalty using an analytical approach and confirm the results with a series of numerical simulations. We find that the penalty is substantially reduced when the spacing between image samples is large compared to the telescope aperture. The penalty can be further reduced with suitable noise filtering, which can yield ${\cal O}(10)$ or better improvement for low-quality imaging data. Our results confirm that it is possible to use the SGL for imaging purposes. We offer insights on the data collection and image processing strategies that could yield a detailed image of an exoplanet within image data collection times that are consistent with the duration of a realistic space mission.
用太阳引力透镜恢复图像
我们报告了用图像卷积/反卷积计算机代码获得的初步结果,我们开发并用于研究太阳引力透镜(SGL)的成像能力。尽管球面太阳的SGL会造成图像的严重模糊,但了解SGL的点扩散函数(PSF)可以重建原始图像,并通过反卷积的方式消除模糊。我们讨论了反卷积过程,它可以用直接矩阵反演或傅立叶商法来实现。我们观察到,与收集模糊图像数据时的信噪比相比,该过程引入了一种“惩罚”,即恢复图像的信噪比(SNR)降低。我们使用分析方法估计了这种惩罚的大小,并通过一系列数值模拟证实了结果。我们发现,与望远镜孔径相比,当图像样本之间的间距较大时,惩罚大大减少。通过适当的噪声滤波可以进一步降低惩罚,对于低质量的成像数据可以产生${\cal O}(10)$或更好的改进。我们的结果证实,它是可能使用SGL成像的目的。我们提供有关数据收集和图像处理策略的见解,这些策略可以在与实际太空任务持续时间一致的图像数据收集时间内生成系外行星的详细图像。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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