Dual-camera compressive hyperspectral imaging based on deep image prior and a guided filter

Haijun Tian; Jufeng Zhao; Jufeng Zhao; Junjie Zhu; Xuanji Tang; Guangmang Cui; Guangmang Cui; Changlun Hou; Changlun Hou

doi:10.1364/AO.483993

Applied Optics
Vol. 62,
Issue 14,
pp. 3649-3659
(2023)
•https://doi.org/10.1364/AO.483993

Dual-camera compressive hyperspectral imaging based on deep image prior and a guided filter

Haijun Tian, Jufeng Zhao, Junjie Zhu, Xuanji Tang, Guangmang Cui, and Changlun Hou

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Haijun Tian, Jufeng Zhao, Junjie Zhu, Xuanji Tang, Guangmang Cui, and Changlun Hou, "Dual-camera compressive hyperspectral imaging based on deep image prior and a guided filter," Appl. Opt. 62, 3649-3659 (2023)

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Table of Contents Category
- Imaging Systems, Image Processing, and Displays
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About this Article
History
- Original Manuscript: December 22, 2022
- Revised Manuscript: March 6, 2023
- Manuscript Accepted: April 11, 2023
- Published: May 3, 2023

Abstract

Coded aperture snapshot spectral imaging (CASSI) aims to capture the high-dimensional (usually 3D) data cube using a 2D sensor in a single snapshot. Due to the ill-posed snapshot, the reconstruction results are not ideal. One feasible solution is to utilize additional information such as the panchromatic measurement in CASSI. In this paper, we propose a dual-camera hyperspectral reconstruction method based on the deep image prior (DIP) and a guided filter. In particular, the panchromatic measurements are used to estimate spatial detail, and spectral details are provided using CASSI measurements. These measurements are used as a priori learning by the self-supervised network. Using iteration combined with DIP, the hyperspectral reconstruction is continuously updated iteratively. Finally, the panchromatic measurement is used as the guidance image, and the reconstruction result is optimized by guide filtering. A large number of experimental results demonstrate that our method without training data can reconstruct spectral data with both high spectral accuracy and spatial resolution.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Method	Index	Thread	Glass	Feathers	Flowers	Oil	Jelly	Cloth	Beads	Average
DCCHI-TV [15]	PSNR	31.19	27.25	34.34	30.48	27.49	29.15	27.40	24.57	28.98
	ERGAS	31.14	23.96	19.29	22.84	18.65	23.38	35.11	38.35	26.58
	SSIM	0.9337	0.9007	0.9440	0.9000	0.7741	0.9279	0.8120	0.8240	0.8771
TSA-Net [27]	PSNR	34.20	32.13	35.38	32.61	27.23	31.48	27.23	28.72	31.12
	ERGAS	17.54	13.68	18.76	19.46	18.67	18.99	25.43	26.37	19.86
	SSIM	0.9232	0.9469	0.9319	0.8837	0.6798	0.9161	0.8583	0.9107	0.8813
ANSR [17]	PSNR	37.89	30.49	38.16	35.36	32.06	33.50	31.28	28.55	33.41
	ERGAS	11.93	16.37	11.93	12.51	10.80	13.22	12.84	24.82	14.30
	SSIM	0.9689	0.9215	0.9700	0.9519	0.9111	0.9486	0.9518	0.8959	0.9400
DCCHI-DeSCI [35]	PSNR	38.22	30.88	38.09	34.84	33.06	34.36	32.50	27.56	33.69
	ERGAS	12.73	15.51	13.14	15.66	9.97	12.95	12.96	28.23	15.14
	SSIM	0.9682	0.9205	0.9499	0.9288	0.9228	0.9584	0.9413	0.9075	0.9372
DCCHI-DIP-GF	ERGAS	38.24	36.54	38.49	36.61	33.53	33.65	33.22	31.41	35.21
	SSIM	11.50	8.14	12.19	10.72	9.22	14.01	12.62	17.49	11.99
	SSIM	0.9669	0.9817	0.9695	0.9525	0.9349	0.9453	0.9712	0.9461	0.9585

		Gavyam	BGU	Eve	Labtest	Omer	Hill	Gavyam	Eve
Method	Index	0945	1419	1633	1502	1118	1219	0930	1647	Average
DCCHI-TV [15]	PSNR	28.99	30.08	29.13	34.71	28.42	30.87	30.38	33.51	30.76
	ERGAS	10.86	10.08	11.10	7.41	5.71	7.33	8.55	6.82	8.48
	SSIM	0.8830	0.8842	0.9016	0.9521	0.9171	0.9211	0.9032	0.9497	0.9140
TSA-Net [27]	PSNR	30.01	32.17	32.83	32.53	30.89	32.16	29.87	37.30	32.22
	ERGAS	10.08	6.15	8.10	11.20	6.06	6.02	9.09	4.64	7.67
	SSIM	0.8981	0.9285	0.9402	0.9533	0.9664	0.9309	0.8995	0.9618	0.9348
ANSR [17]	PSNR	30.93	33.01	31.28	38.16	34.00	37.52	33.45	40.32	34.83
	ERGAS	8.32	5.25	8.86	4.99	2.99	3.38	5.95	3.22	5.37
	SSIM	0.9341	0.9318	0.9392	0.9596	0.9518	0.9776	0.9439	0.9838	0.9527
DCCHI-DeSCI [35]	PSNR	33.71	34.45	33.76	40.14	35.97	39.12	33.88	39.92	36.37
	ERGAS	6.25	4.42	6.86	3.97	2.38	2.92	5.74	3.69	4.53
	SSIM	0.9516	0.9493	0.9653	0.9784	0.9837	0.9832	0.9505	0.9849	0.9684
DCCHI-DIP-GF	PSNR	35.00	35.17	34.30	40.25	37.13	39.76	32.96	40.55	36.89
	ERGAS	5.34	4.05	6.56	3.89	2.10	2.62	6.15	3.16	4.23
	SSIM	0.9650	0.9476	0.9656	0.9795	0.9807	0.9847	0.9469	0.9869	0.9696

	DCCHI-TV	TSA-Net	ANSR	DCCHI-DeSCI	Ours
Point A	0.0289	0.0367	0.0269	0.0228	0.0126
Point B	0.0276	0.0196	0.0384	0.0304	0.0144

	CAVE			ICVL
Method	PSNR	ERGAS	SSIM	PSNR	ERGAS	SSIM
PnP-DIP	29.89	23.10	0.8532	31.69	7.55	0.8838
DCCHI-DIP	33.42	14.84	0.9324	35.04	5.16	0.9424

	CAVE			ICVL
Method	PSNR	ERGAS	SSIM	PSNR	ERGAS	SSIM
DCCHI-DIP	33.42	14.84	0.9324	35.04	5.16	0.9424
DCCHI-DIP-GF	35.21	11.99	0.9585	36.89	4.23	0.9696

Noise level	30 dB			25 dB
Index	PSNR	ERGAS	SSIM	PSNR	ERGAS	SSIM
ANSR	30.85	18.96	0.9014	29.63	20.54	0.8841
DCCHI-DIP	33.13	15.45	0.9262	32.44	16.87	0.9108
DCCHI-DIP-GF	34.75	12.72	0.9528	34.00	13.87	0.9437

Noise level	30 dB			25 dB
Index	PSNR	ERGAS	SSIM	PSNR	ERGAS	SSIM
ANSR	30.85	18.96	0.9014	29.63	20.54	0.8841
DCCHI-DIP	33.13	15.45	0.9262	32.44	16.87	0.9108
DCCHI-DIP-GF	34.75	12.72	0.9528	34.00	13.87	0.9437

Abstract

Data availability

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Tables (7)

Equations (25)

Applied Optics