Concept of dual-resolution light field imaging using an organic photoelectric conversion film for high-resolution light field photography

Daisuke Sugimura; Suguru Kobayashi; Takayuki Hamamoto

doi:10.1364/AO.56.008687

Applied Optics
Vol. 56,
Issue 31,
pp. 8687-8698
(2017)
•https://doi.org/10.1364/AO.56.008687

Concept of dual-resolution light field imaging using an organic photoelectric conversion film for high-resolution light field photography

Daisuke Sugimura, Suguru Kobayashi, and Takayuki Hamamoto

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Daisuke Sugimura, Suguru Kobayashi, and Takayuki Hamamoto, "Concept of dual-resolution light field imaging using an organic photoelectric conversion film for high-resolution light field photography," Appl. Opt. 56, 8687-8698 (2017)

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Abstract

Light field imaging is an emerging technique that is employed to realize various applications such as multi-viewpoint imaging, focal-point changing, and depth estimation. In this paper, we propose a concept of a dual-resolution light field imaging system to synthesize super-resolved multi-viewpoint images. The key novelty of this study is the use of an organic photoelectric conversion film (OPCF), which is a device that converts spectra information of incoming light within a certain wavelength range into an electrical signal (pixel value), for light field imaging. In our imaging system, we place the OPCF having the green spectral sensitivity onto the micro-lens array of the conventional light field camera. The OPCF allows us to acquire the green spectra information only at the center viewpoint with the full resolution of the image sensor. In contrast, the optical system of the light field camera in our imaging system captures the other spectra information (red and blue) at multiple viewpoints (sub-aperture images) but with low resolution. Thus, our dual-resolution light field imaging system enables us to simultaneously capture information about the target scene at a high spatial resolution as well as the direction information of the incoming light. By exploiting these advantages of our imaging system, our proposed method enables the synthesis of full-resolution multi-viewpoint images. We perform experiments using synthetic images, and the results demonstrate that our method outperforms other previous methods.

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Notation	Definition
$K$	Number of viewpoints
$N$	Number of pixels of the image sensor
$f^{k}$	Super-resolved $k$ -th viewpoint image
$d$	High-resolution depth map
$m^{k}$	Red and blue image at $k$ -th viewpoint
$M^{K}$	A set of observed multi-viewpoint images
$f_{G}^{k_{c}}$	Green image captured with OPCF
$K$	A set of multi-viewpoint image indices
$M^{k}$	Image warping operator
${(\cdot)}_{n}$	Operator extracting the $n$ -th pixel value

	Bicubic	Multi-SR	ASP	Ours
scene1	24.98	27.24	22.01	32.36
scene2	25.15	24.94	26.54	31.28
scene3	29.19	30.29	30.36	36.96
scene4	26.00	27.00	24.51	35.01
scene5	26.39	30.18	26.60	33.89
scene6	27.55	29.07	26.99	32.78
scene7	31.61	30.68	33.71	37.94
scene8	24.95	26.26	28.27	30.85
scene9	25.31	28.00	24.54	31.85

	$σ^{2} = 0$	$σ^{2} = 10$
scene1	32.36	28.38
scene2	31.28	28.16
scene3	36.96	30.54
scene4	35.01	29.17
scene5	33.89	28.80
scene6	32.78	28.90
scene7	37.94	30.83
scene8	30.85	27.24
scene9	31.85	27.03

$A$	0.2	0.4	0.6	0.8	1.0
PSNR [dB]	28.83	31.91	32.89	33.40	33.64

Notation	Definition
$K$	Number of viewpoints
$N$	Number of pixels of the image sensor
$f^{k}$	Super-resolved $k$ -th viewpoint image
$d$	High-resolution depth map
$m^{k}$	Red and blue image at $k$ -th viewpoint
$M^{K}$	A set of observed multi-viewpoint images
$f_{G}^{k_{c}}$	Green image captured with OPCF
$K$	A set of multi-viewpoint image indices
$M^{k}$	Image warping operator
${(\cdot)}_{n}$	Operator extracting the $n$ -th pixel value

Abstract

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Equations (17)

Applied Optics