Structured Random Model for Fast and Robust Phase Retrieval

arXiv - PHYS - Optics Pub Date : 2024-09-09 DOI:arxiv-2409.05734

Zhiyuan Hu, Julián Tachella, Michael Unser, Jonathan Dong

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Abstract

Phase retrieval, a nonlinear problem prevalent in imaging applications, has been extensively studied using random models, some of which with i.i.d. sensing matrix components. While these models offer robust reconstruction guarantees, they are computationally expensive and impractical for real-world scenarios. In contrast, Fourier-based models, common in applications such as ptychography and coded diffraction imaging, are computationally more efficient but lack the theoretical guarantees of random models. Here, we introduce structured random models for phase retrieval that combine the efficiency of fast Fourier transforms with the versatility of random diagonal matrices. These models emulate i.i.d. random matrices at a fraction of the computational cost. Our approach demonstrates robust reconstructions comparable to fully random models using gradient descent and spectral methods. Furthermore, we establish that a minimum of two structured layers is necessary to achieve these structured-random properties. The proposed method is suitable for optical implementation and offers an efficient and robust alternative for phase retrieval in practical imaging applications.

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用于快速稳健相位检索的结构化随机模型

相位检索是成像应用中普遍存在的一个非线性问题，人们利用随机模型对其进行了广泛研究，其中一些随机模型具有 i.i.d. 传感矩阵组件。虽然这些模型提供了稳健的重建保证，但它们的计算成本很高，在现实世界中并不实用。相比之下，基于傅立叶的模型（常见于层析成像和编码衍射成像等应用中）计算效率更高，但缺乏随机模型的理论保证。在这里，我们介绍了用于相位检索的结构化随机模型，它结合了快速傅里叶变换的效率和随机对角矩阵的多功能性。这些模型以极低的计算成本模拟了 i.i.d. 随机矩阵。我们的方法利用梯度下降和频谱方法展示了可与完全随机模型相媲美的稳健重建。此外，我们还确定，至少需要两个结构层才能实现结构随机特性。所提出的方法适用于光学实施，为实际成像应用中的相位检索提供了一种高效、稳健的替代方法。

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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arXiv - PHYS - Optics

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