Mixed scale dense convolutional networks for x-ray phase contrast imaging

Kannara Mom; Bruno Sixou; Max Langer; Max Langer

doi:10.1364/AO.443330

Applied Optics
Vol. 61,
Issue 10,
pp. 2497-2505
(2022)
•https://doi.org/10.1364/AO.443330

Mixed scale dense convolutional networks for x-ray phase contrast imaging

Kannara Mom, Bruno Sixou, and Max Langer

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Kannara Mom, Bruno Sixou, and Max Langer, "Mixed scale dense convolutional networks for x-ray phase contrast imaging," Appl. Opt. 61, 2497-2505 (2022)

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Abstract

X-ray in-line phase contrast imaging relies on the measurement of Fresnel diffraction intensity patterns due to the phase shift and the attenuation induced by the object. The recovery of phase and attenuation from one or several diffraction patterns is a nonlinear ill-posed inverse problem. In this work, we propose supervised learning approaches using mixed scale dense (MS-D) convolutional neural networks to simultaneously retrieve the phase and the attenuation from x-ray phase contrast images. This network architecture uses dilated convolutions to capture features at different image scales and densely connects all feature maps. The long range information in images becomes quickly available, and greater receptive field size can be obtained without losing resolution. This network architecture seems to account for the effect of the Fresnel operator very efficiently. We train the networks using simulated data of objects consisting of either homogeneous components, characterized by a fixed ratio of the induced refractive phase shifts and attenuation, or heterogeneous components, consisting of various materials. We also train the networks in the image domain by applying a simple initial reconstruction using the adjoint of the Fréchet derivative. We compare the results obtained with the MS-D network to reconstructions using U-Net, another popular network architecture, as well as to reconstructions using the contrast transfer function method, a direct phase and attenuation retrieval method based on linearization of the direct problem. The networks are evaluated using simulated noisy data as well as images acquired at NanoMAX (MAX IV, Lund, Sweden). In all cases, large improvements of the reconstruction errors are obtained on simulated data compared to the linearized method. Moreover, on experimental data, the networks improve the reconstruction quantitatively, improving the low-frequency behavior and the resolution.

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Data availability

Data underlying the simulated results presented in this paper can be generated using TomoPhantom software [22]. Data underlying the experimental results presented are available through the PyPhase package [26].

22. D. Kazantsev, V. Pickalov, S. Nagella, P. Edoardo, and P. J. Withers, “TomoPhantom, a software package to generate 2D–4D analytical phantoms for CT image reconstruction algorithm benchmarks,” SoftwareX 7, 150–155 (2018). [CrossRef]

26. M. Langer, “PyPhase-1.0.1: An open source phase retrieval code,” Zenodo, 2021, https://doi.org/10.5281/zenodo.4623696.

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Material	Symbol	$µ (c m^{- 1})$	$\frac{2 π}{λ} δ_{r} (c m^{- 1})$	$δ_{r} / β$
Gold	Au	2 790	11 395	8.16
Palladium	Pd	615	8 251	26.83
Zinc	Zn	859	5 270	12.27

	# Distances	# Parameters	Attenuation	Phase
CTF	5	–	42.4 (19.7)	30.3 (8.99)
U-Net	5	$31 \times 10^{6}$	11.1 (12.3)	7.65 (9.35)
MS-D Net	5	$49 \times 10^{3}$	7.67 (10.6)	5.33 (6.74)
MS-D Net	1	$45 \times 10^{3}$	11.8 (9.05)	7.76 (6.36)

	# Distances	# Parameters	Attenuation	Phase
CTFHomo	5	–	13.5 (3.92)	13.5 (3.92)
CTFHomo	1	–	21.4 (14.0)	21.4 (14.0)
U-Net	5	$31 \times 10^{6}$	4.29 (4.82)	4.29 (4.82)
MS-D Net	5	$49 \times 10^{3}$	3.95 (4.41)	3.95 (4.41)
MS-D Net	1	$45 \times 10^{3}$	4.37 (5.50)	4.37 (5.50)

Heterogeneous
		Attenuation		Phase
	# Distances	NE (RSD) in %	Resolution (nm)	NE (RSD) in %	Resolution (nm)
CTF	5	81.3 (177)	102	21.6 (30.0)	213
U-Net	5	6.83 (35.5)	96	2.30 (16.0)	159
MS-D Net	5	33.7 (40.6)	98	3.22 (14.2)	202
MS-D Net	1	48.2 (32.0)	92	–11.5 (15.2)	208
Homogeneous
		Attenuation		Phase
	# Distances	NE (RSD) in %	Resolution (nm)	NE (RSD) in %	Resolution (nm)
CTFHomo	5	4.14 (11.5)	197	4.14 (11.5)	197
CTFHomo	1	25.3 (16.0)	128	25.3 (16.0)	128
U-Net	5	14.7 (27.5)	140	14.7 (27.5)	140
MS-D Net	5	2.03 (11.6)	165	1.84 (11.2)	165
MS-D Net	1	2.96 (12.5)	93	2.76 (12.3)	93

	Homogeneous		Heterogeneous
	Attenuation	Phase	Attenuation	Phase
U-Net	9.60 (13.8)	4.74 (8.85)	16.2 (12.3)	5.77 (7.94)
MS-D Net	1.96 (3.05)	1.96 (3.05)	8.19 (6.68)	4.83 (5.17)

Heterogeneous
	Attenuation		Phase
	NE (RSD) in %	Resolution (nm)	NE (RSD) in %	Resolution (nm)
Initialization	$31.6 (93.9)$	371	$22.5 (19.6)$	192
U-Net	$15.1 (24.3)$	72	$7.37 (12.9)$	135
MS-D Net	$- 27.5 (34.2)$	107	$- 4.14 (11.5)$	116
Homogeneous
	Attenuation		Phase
	NE (RSD) in %	Resolution (nm)	NE (RSD) in %	Resolution (nm)
Initialization	$31.6 (93.9)$	371	$22.5 (19.6)$	192
U-Net	$7.04 (11.6)$	133	$8.34 (8.64)$	133
MS-D Net	$1.45 (7.18)$	122	$1.38 (7.15)$	122

Heterogeneous
	Attenuation		Phase
	NE (RSD) in %	Resolution (nm)	NE (RSD) in %	Resolution (nm)
Initialization	$31.6 (93.9)$	371	$22.5 (19.6)$	192
U-Net	$15.1 (24.3)$	72	$7.37 (12.9)$	135
MS-D Net	$- 27.5 (34.2)$	107	$- 4.14 (11.5)$	116
Homogeneous
	Attenuation		Phase
	NE (RSD) in %	Resolution (nm)	NE (RSD) in %	Resolution (nm)
Initialization	$31.6 (93.9)$	371	$22.5 (19.6)$	192
U-Net	$7.04 (11.6)$	133	$8.34 (8.64)$	133
MS-D Net	$1.45 (7.18)$	122	$1.38 (7.15)$	122

Abstract

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Applied Optics