Simulating receptive fields of human visual cortex for 3D image quality prediction

Feng Shao; Wanting Chen; Wenchong Lin; Qiuping Jiang; Gangyi Jiang

doi:10.1364/AO.55.005488

Applied Optics
Vol. 55,
Issue 21,
pp. 5488-5496
(2016)
•https://doi.org/10.1364/AO.55.005488

Simulating receptive fields of human visual cortex for 3D image quality prediction

Feng Shao, Wanting Chen, Wenchong Lin, Qiuping Jiang, and Gangyi Jiang

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Feng Shao, Wanting Chen, Wenchong Lin, Qiuping Jiang, and Gangyi Jiang, "Simulating receptive fields of human visual cortex for 3D image quality prediction," Appl. Opt. 55, 5488-5496 (2016)

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Table of Contents Category
- Vision and Visual Optics
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About this Article
History
- Original Manuscript: May 6, 2016
- Revised Manuscript: June 14, 2016
- Manuscript Accepted: June 15, 2016
- Published: July 12, 2016
Virtual Issues
Virtual Journal for Biomedical Optics Vol. 11, Iss. 8

Abstract

Quality assessment of 3D images presents many challenges when attempting to gain better understanding of the human visual system. In this paper, we propose a new 3D image quality prediction approach by simulating receptive fields (RFs) of human visual cortex. To be more specific, we extract the RFs from a complete visual pathway, and calculate their similarity indices between the reference and distorted 3D images. The final quality score is obtained by determining their connections via support vector regression. Experimental results on three 3D image quality assessment databases demonstrate that in comparison with the most relevant existing methods, the devised algorithm achieves high consistency alignment with subjective assessment, especially for asymmetrically distorted stereoscopic images.

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Disparity ( $d$ )	V. Near Disparity	Near Disparity	Zero Disparity	Far Disparity	V. Far Disparity
Allelotropic shift ( $s$ )	−30	−15	0	15	30

Disparity ( $d$ )	V. Near Disparity	Near Disparity	Zero Disparity	Far Disparity	V. Far Disparity
V. near disparity	–	3	5	3	2
Near disparity	0.4	–	2.8	1.5	0.4
Zero disparity	0.2	1.3	–	1.3	0.2
Far disparity	0.4	1.5	2.8	–	0.4
V. far disparity	2	3	5	3	–

	NBU (312 images)			LIVE I (365 images)			LIVE II (360 images)
IQA Model	PLCC	SRCC	RMSE	PLCC	SRCC	RMSE	PLCC	SRCC	RMSE
FI-PSNR	0.9077	0.8889	7.2081	0.8645	0.8559	8.2424	0.6584	0.6375	8.4956
FI-SSIM	0.9143	0.9093	6.9565	0.8699	0.8606	8.0874	0.6844	0.6795	8.2295
FI-VIF	0.8455	0.8463	9.1739	0.9222	0.9188	6.3423	0.7234	0.7213	7.7936
Benoit [8]	0.8760	0.8812	8.2864	0.8899	0.8901	7.4786	0.7642	0.7475	7.2806
You [9]	0.7346	0.7324	11.6556	0.9303	0.9247	6.0161	0.7744	0.7206	7.1413
Shao [18]	0.9235	0.9271	6.5896	0.9245	0.9217	6.2522	0.7585	0.7451	7.3554
Shao [19]	0.9217	0.9245	6.6321	0.9306	0.9327	6.0571	0.8223	0.8043	6.5737
Shao [20]	0.9238	0.9258	6.5760	0.9367	0.9365	5.7426	0.8601	0.8387	5.7581
Proposed	0.9482^a	0.9369	5.4211	0.9422	0.9295	5.4733	0.9494	0.9418	3.5222

Database	Criteria	FI-PSNR	FI-SSIM	FI-VIF	Benoit [8]	You [9]	Shao [18]	Shao [19]	Shao [20]	Proposed
NBU 3D-IQA Database	JPEG	0.9433	0.9420	0.9467	0.8835	0.7266	0.9367	0.9012	0.9111	0.9427
	JP2K	0.9402	0.9441	0.9259	0.8900	0.6811	0.9192	0.8921	0.9129	0.9666
	WN	0.9158	0.9302	0.9551	0.9386	0.8770	0.9444	0.9235	0.9280	0.9511
	GB	0.9596	0.9578	0.9696	0.9324	0.8258	0.9599	0.9721	0.9582	0.9741
	H246	0.9640	0.9665	0.9672	0.8385	0.7044	0.9260	0.9129	0.9283	0.9639
LIVE 3D-IQA Database Phase I	JPEG	0.2866	0.2741	0.6545	0.5766	0.6333	0.6563	0.6533	0.7636	0.7808
	JP2K	0.8381	0.8210	0.9412	0.8859	0.9410	0.9238	0.9269	0.9518	0.9509
	WN	0.9280	0.9250	0.9310	0.9354	0.9351	0.9410	0.9368	0.9271	0.9643
	GB	0.9475	0.9080	0.9573	0.9217	0.9545	0.9513	0.9534	0.9600	0.9564
	FF	0.7086	0.7297	0.7572	0.7477	0.8589	0.8403	0.8532	0.8765	0.8217
LIVE 3D-IQA Database Phase II	JPEG	0.6124	0.5486	0.8906	0.5328	0.6741	0.7504	0.7857	0.8022	0.9141
	JP2K	0.7457	0.7191	0.9164	0.6467	0.7320	0.8377	0.8124	0.8385	0.9191
	WN	0.9150	0.9139	0.8981	0.8610	0.5464	0.8496	0.8646	0.8577	0.9584
	GB	0.7083	0.7250	0.8993	0.8814	0.9763	0.8270	0.8645	0.9823	0.9868
	FF	0.7025	0.7342	0.7574	0.8472	0.8561	0.8808	0.9035	0.9617	0.9536

Database	Criteria	FI-PSNR	FI-SSIM	FI-VIF	Benoit [8]	You [9]	Shao [18]	Shao [19]	Shao [20]	Proposed
NBU 3D-IQA Database	JPEG	0.9390	0.9456	0.9514	0.8889	0.7606	0.9489	0.9189	0.9273	0.9021
	JP2K	0.9469	0.9439	0.9282	0.8951	0.6754	0.9309	0.9076	0.9252	0.9301
	WN	0.8604	0.9163	0.9233	0.9278	0.8341	0.9336	0.9200	0.9279	0.9021
	GB	0.9526	0.9692	0.9737	0.9304	0.8175	0.9510	0.9790	0.9635	0.9510
	H246	0.9555	0.9536	0.9513	0.8402	0.6685	0.9470	0.9378	0.9443	0.9285
LIVE 3D-IQA Database Phase I	JPEG	0.2070	0.2407	0.6002	0.4983	0.6008	0.6148	0.6167	0.7238	0.6838
	JP2K	0.8388	0.8222	0.9125	0.8730	0.9051	0.8752	0.8789	0.9059	0.8912
	WN	0.9284	0.9282	0.9335	0.9369	0.9403	0.9431	0.9366	0.9258	0.9412
	GB	0.9345	0.8788	0.9329	0.8802	0.9300	0.9375	0.9403	0.9449	0.9000
	FF	0.6581	0.6866	0.7497	0.6242	0.8030	0.7814	0.8056	0.8252	0.7294
LIVE 3D-IQA Database Phase II	JPEG	0.6129	0.5644	0.8768	0.5078	0.5229	0.7195	0.7367	0.7433	0.8581
	JP2K	0.7193	0.7003	0.9212	0.6325	0.7309	0.8477	0.8234	0.8335	0.8857
	WN	0.9073	0.9091	0.9341	0.8569	0.4820	0.8455	0.8589	0.8436	0.9341
	GB	0.7112	0.7387	0.8868	0.8545	0.9227	0.8005	0.8490	0.9575	0.9341
	FF	0.7012	0.7350	0.7586	0.8319	0.8392	0.8509	0.8906	0.9578	0.9253

Training Dataset	Testing Dataset	JPEG	JP2K	WN	GB	H264	FF
NBU	LIVE-I	0.7185	0.9458	0.9219	0.9279	—	0.7922
NBU	LIVE-II	0.8857	0.8277	0.9186	0.6732	—	0.8470
LIVE-I	NBU	0.8274	0.8301	0.9235	0.8317	0.8709	—
LIVE-I	LIVE-II	0.8609	0.7239	0.9374	0.9710	—	0.9523
LIVE-II	NBU	0.8798	0.8374	0.8833	0.9634	0.9430	—
LIVE-II	LIVE-I	0.7227	0.9453	0.9314	0.9253	—	0.8078

Abstract

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Applied Optics