Two-way focal stack fusion for light field saliency detection

Yani Zhang; Fen Chen; Fen Chen; Zongju Peng; Zongju Peng; Wenhui Zou; Mengyu Nie; Changhe Zhang

doi:10.1364/AO.500999

Applied Optics
Vol. 62,
Issue 34,
pp. 9057-9065
(2023)
•https://doi.org/10.1364/AO.500999

Two-way focal stack fusion for light field saliency detection

Yani Zhang, Fen Chen, Zongju Peng, Wenhui Zou, Mengyu Nie, and Changhe Zhang

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Yani Zhang, Fen Chen, Zongju Peng, Wenhui Zou, Mengyu Nie, and Changhe Zhang, "Two-way focal stack fusion for light field saliency detection," Appl. Opt. 62, 9057-9065 (2023)

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Abstract

To improve the accuracy of saliency detection in challenging scenes such as small objects, multiple objects, and blur, we propose a light field saliency detection method via two-way focal stack fusion. The first way extracts latent depth features by calculating the transmittance of the focal stack to avoid the interference of out-of-focus regions. The second way analyzes the focused distribution and calculates the background probability of the slice, which can distinguish the foreground from the background. Extracting the potential cues of the focal stack through the two different ways can improve saliency detection in complex scenes. Finally, a multi-layer cellular automaton optimizer is utilized to incorporate compactness, focus, center prior, and depth features to obtain the final salient result. Comparison and ablation experiments are performed to verify the effectiveness of the proposed method. Experimental results prove that the proposed method demonstrates effectiveness in challenging scenarios and outperforms the state-of-the-art methods. They also verify that the depth and focus cues of the focal stack can enhance the performance of previous methods.

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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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Equations (16)

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Settings	$E_{β}$	$S_{λ}$	$F_{β}^{ω}$	$F_{β}$	$M$
$S_{O b j}$	0.724	0.657	0.441	0.572	0.136
$S_{{dcp}_{k}}$	0.694	0.651	0.380	0.542	0.195
$S_{{csp}_{k}}$	0.685	0.645	0.369	0.531	0.199
$S_{cdcp}$	0.718	0.678	0.518	0.572	0.133
$S_{bg}$	0.750	0.694	0.520	0.614	0.125
Ours	0.736	0.694	0.531	0.599	0.126

Category	Model	$E_{β}$	$S_{λ}$	$F_{β}^{ω}$	$F_{β}$	$M$
Light field	Ours	0.736	0.694	0.531	0.599	0.126
	RDFD [13]	0.691	0.619	0.355	0.518	0.215
	DILF [9]	0.693	0.672	0.430	0.530	0.151
	WSC [8]	0.679	0.613	0.428	0.485	0.154
	LFS [7]	0.656	0.547	0.243	0.399	0.230
RGB-D	DCMC [30]	0.727	0.661	0.436	0.582	0.138
RGB-D	CDCP [31]	0.695	0.651	0.448	0.528	0.158
RGB	DCLC [26]	0.726	0.670	0.422	0.563	0.149
RGB	BSCA [27]	0.691	0.654	0.380	0.531	0.190

Settings	$E_{β}$	$S_{λ}$	$F_{β}^{ω}$	$F_{β}$	$M$
$S_{O b j}$	0.724	0.657	0.441	0.572	0.136
$S_{{dcp}_{k}}$	0.694	0.651	0.380	0.542	0.195
$S_{{csp}_{k}}$	0.685	0.645	0.369	0.531	0.199
$S_{cdcp}$	0.718	0.678	0.518	0.572	0.133
$S_{bg}$	0.750	0.694	0.520	0.614	0.125
Ours	0.736	0.694	0.531	0.599	0.126

Category	Model	$E_{β}$	$S_{λ}$	$F_{β}^{ω}$	$F_{β}$	$M$
Light field	Ours	0.736	0.694	0.531	0.599	0.126
	RDFD [13]	0.691	0.619	0.355	0.518	0.215
	DILF [9]	0.693	0.672	0.430	0.530	0.151
	WSC [8]	0.679	0.613	0.428	0.485	0.154
	LFS [7]	0.656	0.547	0.243	0.399	0.230
RGB-D	DCMC [30]	0.727	0.661	0.436	0.582	0.138
RGB-D	CDCP [31]	0.695	0.651	0.448	0.528	0.158
RGB	DCLC [26]	0.726	0.670	0.422	0.563	0.149
RGB	BSCA [27]	0.691	0.654	0.380	0.531	0.190

Abstract

Data availability

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Figures (6)

Tables (2)

Equations (16)

Applied Optics