Research on Signal-Noise Separation Algorithm of Ptychography

被引：0

作者：

Xing Z. ^{[1
,2
]}

Xu Z. ^{[1
,3
]}

Sun T. ^{[1
,2
]}

Zhang X. ^{[1
,3
]}

Tai R. ^{[1
,3
]}

机构：

[1] Department of Physics and Environment Sciences, Shanghai Institute of Applied Physics, Chinese Academy of Sciences, Shanghai

[2] University of Chinese Academy of Sciences, Beijing

[3] Shanghai Synchrotron Radiation Facility, Shanghai Advanced Research Institute, Chinese Academy of Sciences, Shanghai

来源：

Guangxue Xuebao/Acta Optica Sinica | 2021年 / 41卷 / 22期

关键词：

Background noise; Phase retrieval iterative algorithm; Ptychography; Signal-to-noise separation; X-ray optics;

D O I：

10.3788/AOS202141.2234001

中图分类号：

学科分类号：

摘要：

Ptychographic coherent diffraction imaging is a novel lensless imaging method, which removes the resolution limitation by imaging elements in traditional optical lens imaging, so that its theoretical resolution is only limited by the X-ray wavelength and the numerical aperture of detector. However, the experiment background noise limits the further improvement of the imaging quality by this method, and may lead to the failure of image reconstruction. A new phase-retrieval iterative algorithm is proposed in this paper after studying the existing ptychographic iterative algorithms. The new algorithm uses the high redundancy of the ptychographic data set, and uses the gradient descent minimization method to reconstruct the background noise in synchronization with the reconstruction of the object and the detection, and realizes the blind separation of the noise and the signal. This algorithm is compared with the traditional iterative algorithms in simulation and experiment data reconstructions, demonstrating that this new algorithm can achieve a better signal-noise separation and a higher imaging quality. © 2021, Chinese Lasers Press. All right reserved.

引用

共 32 条

[1] Kirz J, Jacobsen C, Howells M., Soft X-ray microscopes and their biological applications, Quarterly Reviews of Biophysics, 28, 1, pp. 33-130, (1995)
[2] Tan X X, Liu H G, Guo Z, Et al., Simulation of coherent diffraction imaging based on scanning transimission X-ray microscopy of Shanghai synchrotron radiation facility, Acta Optica Sinica, 31, 4, (2011)
[3] Fienup J R., Reconstruction of an object from the modulus of its Fourier transform, Optics Letters, 3, 1, pp. 27-29, (1978)
[4] Sayre D, Chapman H N, Miao J., On the extendibility of X-ray crystallography to noncrystals, Acta Crystallographica Section A Foundations of Crystallography, 54, 2, pp. 232-239, (1998)
[5] Miao J W, Charalambous P, Kirz J, Et al., Extending the methodology of X-ray crystallography to allow imaging of micrometre-sized non-crystalline specimens, Nature, 400, 6742, pp. 342-344, (1999)
[6] Miao J, Ishikawa T, Robinson I K, Et al., Beyond crystallography: diffractive imaging using coherent X-ray light sources, Science, 348, 6234, pp. 530-535, (2015)
[7] Spence J C H, Weierstall U, Howells M., Coherence and sampling requirements for diffractive imaging, Ultramicroscopy, 101, pp. 149-152, (2004)
[8] Maiden A M, Rodenburg J M., An improved ptychographical phase retrieval algorithm for diffractive imaging, Ultramicroscopy, 109, 10, pp. 1256-1262, (2009)
[9] Rodenburg J M, Hurst A C, Cullis A G, Et al., Hard-X-ray lensless imaging of extended objects, Physical Review Letters, 98, 3, (2007)
[10] Zhang F C, Rodenburg J M., Phase retrieval based on wave-front relay and modulation, Physical Review B, 82, 12, (2010)

← 1 2 3 4 →