Objective assessment of image quality based on image content contrast perception

Yao Jun-Cai; Shen Jing

doi:10.7498/aps.69.20200335

Abstract

Image quality assessment (IQA) plays a very important role in acquiring, storing, transmitting and processing image and video. Using the characteristics of human visual perception and the features of the gray, gradient, local contrast, and blurring of image, an IQA method based on the image content contrast perception is proposed in the paper, which is called MPCC. In the proposed method, firstly, combining with the characteristics of human visual perception, based on the definition of the contrast in physics, a novel definition for image quality and its calculation method are proposed. Then, based on the gray gradient co-occurrence matrix, a novel concept, namely the gray-gradient entropy of image, and its calculation method, are proposed. And based on the gray-gradient entropy, local contrast and blurring of image, a method of describing the image content and their visual perception are proposed. Finally, based on the image content features and the image quality definition, an IQA method and its mathematical model are proposed by comprehensive analysis. Further, the proposed IQA model MPCC is tested by using 119 reference images and 6395 distorted images from the five open image databases (LIVE, CSIQ, TID2008, TID2013 and IVC). Moreover, the influences of the 52 distortion types on IQA are analyzed. In addition, in order to illustrate the advantages of the MPCC model, it is compared with the seven existing typical IQA models in terms of the accuracy, complexity and generalization performance of model. The experimental results show that the accuracy PLCC of the MPCC model can achieve 0.8616 at lowest and 0.9622 at most in the five databases; among the 52 distortion types, the two distortion types, namely the change of color saturation and the local block-wise distortions of different intensity, have the greatest influence on IQA, and the accuracy PLCC values of the seven existing IQA models are almost all below 0.6, but the PLCC of the MPCC model can reach more than 0.68; and the comprehensive benefit of the performance of the MPCC model is better than those of the seven existing IQA models. These results of test and comparison above show that the proposed IQA method is effective and feasible, and the corresponding model has an excellent performance.

Keywords:

image quality assessment /
human visual perception characteristic /
image content /
contrast

Authors and contacts

Yao Jun-Cai^1,2,3,
Shen Jing¹

1.
School of Computer Engineering, Nanjing Institute of Technology, Nanjing 211167, China
2.
School of Physics and Telecommunication Engineering, Shaanxi University of Technology, Hanzhong 723000, China
3.
School of Information and Communications Engineering, Xi’an Jiaotong University, Xi’an 710049, China

Corresponding author: Yao Jun-Cai, sxhzyjc@sina.com

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References

[1]	Nightingale J, Salva P, Alcarazcalero J M, Wang Q 2018 IEEE Trans. Broadcast. 64 621 Google Scholar
[2]	丰卉, 孙彪, 马书根 2017 物理学报 66 180202 Google Scholar Feng H, Sun B, Ma S G 2017 Acta Phys. Sin. 66 180202 Google Scholar
[3]	Yao J C, Liu G Z 2019 IEEE Trans. Broadcast. 65 546 Google Scholar
[4]	Chandler D M, Hemami S S 2007 IEEE Trans. Image Process. 16 2284 Google Scholar
[5]	Wang Z, Bovik A C, Sheikh H R, Simoncelli E P 2004 IEEE Trans. Image Process. 13 600
[6]	Zhang L, Zhang L, Mou X, Zhang D 2011 IEEE Trans. Image Process. 20 2378 Google Scholar
[7]	Xue W, Zhang L, Mou X, Bovik A C 2014 IEEE Trans. Image Process. 23 684 Google Scholar
[8]	Zhang L, Shen Y, Li H 2014 IEEE Trans. Image Process. 23 4270 Google Scholar
[9]	Larson E C, Chandler D M 2010 J. Electron. Imaging 19 011006 Google Scholar
[10]	Fang Y M, Yan J B, Li L D, Wu J J, Lin W S 2018 IEEE Trans. Image Process. 27 1600 Google Scholar
[11]	方志明, 崔荣一, 金璟璇 2017 物理学报 66 109501 Google Scholar Fang Z M, Cui R Y, Jin J X 2017 Acta Phys. Sin. 66 109501 Google Scholar
[12]	Qi H, Jiao S H, Lin W S, Tang L, Shen W H 2014 Electron. Lett. 50 1435
[13]	Zheng L, Shen L, Chen J, An P, Luo J 2019 IEEE Trans. Multimedia 21 2057 Google Scholar
[14]	Yang X, Wang T, Ji G 2020 IET Image Proc. 14 384 Google Scholar
[15]	Ahar A, Barri A, Schelkens P 2018 IEEE Trans. Image Process. 27 879 Google Scholar
[16]	Zhou W J, Yu L, Zhou Y, Qiu W W, Wu M W 2018 IEEE Trans. Image Process. 27 2086
[17]	Yao J C, Liu G Z 2018 IET Image Proc. 12 872 Google Scholar
[18]	Wang X, Meng F, Huang X Y 2018 Proceeding of the 11 th International Congress on Image and Signal Processing, BioMedical Engineering and Informatics (CISP-BMEI) Beijing, China, October 13—15, 2018 p1
[19]	Ginesu G, Massidda F, Giusto D D 2006 Signal Process. Image Commun. 21 316 Google Scholar
[20]	Nadenau M 2000 Ph. D Dissertation (Lausanne: École Polytechnique Fédérale de Lausanne)
[21]	Niu Y Z, Zhang H F, Guo W Z, Ji R R 2018 IEEE Trans. Circuits Syst. Video Technol. 28 849
[22]	王鸿南, 钟文, 汪静, 夏德深 2004 中国图象图形学报 9 828 Google Scholar Wang H N, Zhong W, Wang J, Xia D S 2004 J. Image Graph. 9 828 Google Scholar
[23]	Sheikh H R, Wang Z, Cormack L LIVE Image Quality Assessment Database Release 2 Available: http://live.ece. utexas.edu/research/quality [2019-12-20]
[24]	Larson E C, Chandler D M The CSIQ image database http://vision.okstate.edu/?loc=csiq [2019-12-20]
[25]	Ponomarenko N, Lukin V, Zelensky A, Egiazarian K, Carli M, Battisti F Tampere Image Database 2008 TID2008, version 1.0 http://www.ponomarenko.info/tid2008.htm [2019-12-20]
[26]	Ponomarenko N, Jin L, Ieremeiev O, Lukin V, Egiazarian K, Astola J, Vozel B, Chehdi K, Carli M, Battisti F, Kuo C C J 2015 Signal Process. Image Commun. 30 57
[27]	Athar S, Wang Z 2019 IEEE Access 7 140030 Google Scholar
[28]	Callet L, Patrick A F Subjective quality assessment IRCCyN /IVC database http://www2.irccyn.ec-nantes.fr/ivcdb/ [2019-12-20]
[29]	Yi Z, Chandler D M 2018 IEEE Trans. Image Process. 27 5433
[30]	Dai T, Gu K, Niu L, et al. 2018 Neurocomputing 290 185
[31]	Zhang C, Cheng W, Hirakawa K 2019 IEEE Trans. Image Process. 28 1732

Cited By

图 1 所提IQA方法的流程图

Figure 1. The architecture of the proposed IQA method.

DownLoad: Full-Size Img PowerPoint

图 2 4个数据库中的图像主客观IQA结果之间的散点图　(a) LIVE; (b) CSIQ; (c) TID2008; (d) TID2013

Figure 2. Scatter plots between the subjective and objective IQA results of images in four databases: (a) LIVE; (b) CSIQ; (c) TID2008; (d) TID2013

DownLoad: Full-Size Img PowerPoint

图 3 所提模型对IVC数据库中灰度和单色图像评价结果

Figure 3. IQA results of the gray and monochrome images in IVC database by the proposed model.

DownLoad: Full-Size Img PowerPoint

图 4 基于TID2008数据库中的图像IQA结果比较所提模型与现有7个模型的精度　(a) PSNR-TID2008; (b) VSNR-TID2008; (c) SSIM-TID2008; (d) FSIMc-TID2008; (e) VSI-TID2008; (f) GMSD-TID2008; (g) MAD-TID2008; (h) MPCC-TID2008

Figure 4. Comparing the accuracy of the proposed model with those of the existing 7 models based on the IQA results in TID2008 database: (a) PSNR-TID2008; (b) VSNR-TID2008; (c) SSIM-TID2008; (d) FSIMc-TID2008; (e) VSI-TID2008; (f) GMSD-TID2008; (g) MAD-TID2008; (h) MPCC-TID2008.

DownLoad: Full-Size Img PowerPoint

图 5 基于平均每10幅图像的评价运行时间比较8个IQA模型的复杂性

Figure 5. Comparison of the complexity of 8 IQA models based on the IQA running time per 10 images.

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图 6 基于3个数据库中28类失真图像评价结果的PLCC值以8个IQA模型的精度对比　(a) CSIQ; (b) LIVE; (c) TID2008

Figure 6. Accuracy comparisons among 8 IQA metrics based on PLCC of IQA results from 28 types of distortion images in three databases: (a) CSIQ; (b) LIVE; (c) TID2008.

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图 7 所提IQA模型对CSIQ库中6种失真类型的失真图像评价结果的散点图　(a) awgn; (b) jpeg; (c) jpeg2k; (d) fnoise; (e) blur; (f) contrast

Figure 7. Scatter plots of the IQA results of 6 kinds of distorted images in CSIQ database evaluating by the proposed IQA model: (a) awgn; (b) jpeg; (c) jpeg2k; (d) fnoise; (e) blur; (f) contrast.

DownLoad: Full-Size Img PowerPoint

图 10 所提IQA模型对TID2013库中24种失真类型的失真图像评价结果的散点图　(a) AGN; (b) NCC; (c) SCN; (d) MN; (e) HFN; (f) IN; (g) QN; (h) GB; (i) ID; (j) JPEG; (k) JPEG2k; (l) JPEGtrans; (m) JPEG2ktrans; (n) NEPN; (o) LBWD; (p) MS; (q) CC; (r) CCS; (s) MGN; (t) CN; (u) LCN; (v) CQWD; (w) CA; (x) SSR

Figure 10. Scatter plots of the IQA results of 24 kinds of distorted images in TID2013 database evaluating by the proposed IQA model: (a) AGN; (b) NCC; (c) SCN; (d) MN; (e) HFN; (f) IN; (g) QN; (h) GB; (i) ID; (j) JPEG; (k) JPEG2k; (l) JPEGtrans; (m) JPEG2ktrans; (n) NEPN; (o) LBWD; (p) MS; (q) CC; (r) CCS; (s) MGN; (t) CN; (u) LCN; (v) CQWD; (w) CA; (x) SSR.

DownLoad: Full-Size Img PowerPoint

图 8 所提IQA模型对LIVE库中5种失真类型的失真图像评价结果的散点图　(a) jpeg2k; (b) jpeg; (c) WN; (d) gblur; (e) fastfading

Figure 8. Scatter plots of the IQA results of 5 kinds of distorted images in LIVE database evaluating by the proposed IQA model: (a) jpeg2k; (b) jpeg; (c) WN; (d) gblur; (e) fastfading.

DownLoad: Full-Size Img PowerPoint

图 9 所提IQA模型对TID2008库中17种失真类型的失真图像评价结果的散点图　(a) AGN; (b) ANCC; (c) SCN; (d) MN; (e) HFN; (f) IN; (g) QN; (h) GB; (i) ID; (j) JPEG; (k) JPEG2k; (l) JPEGtrans; (m) JPEG2ktrans; (n) NEPN; (o) LBWD; (p) MS; (q) CC

Figure 9. Scatter plots of the IQA results of 17 kinds of distorted images in TID2008 database evaluating by the proposed IQA model: (a) AGN; (b) ANCC; (c) SCN; (d) MN; (e) HFN; (f) IN; (g) QN; (h) GB; (i) ID; (j) JPEG; (k) JPEG2k; (l) JPEGtrans; (m) JPEG2ktrans; (n) NEPN; (o) LBWD; (p) MS; (q) CC.

DownLoad: Full-Size Img PowerPoint

表 1 4个数据库中的图像主客观IQA分数之间的相关性参数计算结果

Table 1. Calculated 4 correlation parameters between the subjective and objective IQA scores of images in 4 databases.

数据库	LIVE(779)	CSIQ(866)	TID2008(1700)	TID2013(3000)	加权
PLCC	0.9622	0.9586	0.8778	0.8616	0.8915
SROCC	0.9660	0.9569	0.8831	0.8452	0.8854
RMSE	7.4397	0.0747	0.6427	0.6293	—
OR	0.1531	0.2690	0.1287	0.1198	—

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表 2 基于CSIQ, LIVE和TID2013数据库中的图像IQA结果比较所提模型与现有7个模型的精度

Table 2. Comparing the accuracy of the proposed model with those of the existing 7 models based on the IQA results in CSIQ, LIVE, and TID2013 databases.

数据库	参数	PSNR	VSNR	SSIM	FSIMc	VSI	GMSD	MAD	MPCC
CSIQ	PLCC	0.8000	0.8002	0.8613	0.9192	0.9279	0.9541	0.9502	0.9587
	SROCC	0.8058	0.8106	0.8756	0.9310	0.9423	0.9570	0.9466	0.9569
	RMSE	0.1575	0.1575	0.1334	0.1034	0.0979	0.0786	0.0818	0.0748
	OR	0.4220	0.3832	0.3535	0.3041	0.2873	0.2742	0.2829	0.2738
LIVE	PLCC	0.8723	0.9231	0.9449	0.9613	0.9482	0.9603	0.9675	0.9620
	SROCC	0.8756	0.9274	0.9479	0.9645	0.9524	0.9603	0.9669	0.9660
	RMSE	13.3597	10.5059	8.9455	7.5296	8.6816	7.6214	6.9073	7.4598
	OR	0.2179	0.2151	0.1865	0.1627	0.1853	0.1643	0.1529	0.1606
TID2013	PLCC	0.7062	0.7402	0.7895	0.8769	0.9000	0.8553	0.8267	0.8648
	SROCC	0.6917	0.7316	0.7417	0.8510	0.8965	0.8044	0.7807	0.8452
	RMSE	0.8887	0.8392	0.7608	0.5959	0.5404	0.6423	0.6975	0.6224
	OR	0.1636	0.1552	0.1427	0.1132	0.1045	0.1242	0.1323	0.1179

DownLoad: CSV

表 3 基于TID2013库中24类失真图像评价结果的PLCC值以8个IQA模型的精度对比

Table 3. Accuracy comparisons among 8 IQA metrics based on PLCC of IQA results from 24 types of distortion images in TID2013 database.

失真类别	PSNR	VSNR	SSIM	FSIMc	VSI	GMSD	MAD	MPCC
1 Additive Gaussian noise(AGN)	0.9552	0.8319	0.8685	0.9152	0.9527	0.9503	0.8897	0.8706
2 Noise in color comp. (NCC)	0.9256	0.7814	0.8050	0.8873	0.9172	0.9118	0.8438	0.8324
3 Spatially correl. noise (SCN)	0.9525	0.8105	0.8621	0.8989	0.9472	0.9391	0.9008	0.7457
4 Masked noise (MN)	0.8707	0.7715	0.8219	0.8492	0.8203	0.7547	0.8009	0.6943
5 High frequency noise (HFN)	0.9731	0.9061	0.9081	0.9475	0.9655	0.9567	0.9233	0.9090
6 Impulse noise (IN)	0.8887	0.7442	0.7415	0.8171	0.8635	0.7572	0.3206	0.7408
7 Quantization noise (QN)	0.8880	0.8384	0.8702	0.8794	0.8747	0.9110	0.8571	0.8122
8 Gaussian blur (GB)	0.9169	0.9437	0.9634	0.9544	0.9551	0.9099	0.9357	0.9252
9 Image denoising (ID)	0.9640	0.9463	0.9589	0.9652	0.9707	0.9759	0.9645	0.9594
10 JPEG compression (JPEG)	0.9167	0.9386	0.9551	0.9754	0.9858	0.9843	0.9638	0.9509
11 JPEG2000 compression (JPEG2 K)	0.9170	0.9513	0.9658	0.9754	0.9845	0.9812	0.9740	0.9452
12 JPEG transm. errors (JPEG trans.)	0.8104	0.8597	0.9181	0.9176	0.9457	0.9079	0.9001	0.8805
13 JPEG2000 transm. errors (JPEG2K trans)	0.9002	0.8435	0.8801	0.8929	0.9192	0.9085	0.8838	0.8699
14 Non ecc. patt. noise (NEPN)	0.6746	0.6774	0.7773	0.8068	0.8162	0.8133	0.8608	0.8132
15 Local block-wise dist. (LBWD)	0.2410	0.3632	0.6022	0.5542	0.4984	0.6520	0.4187	0.6845
16 Mean shift (MS)	0.8056	0.5160	0.8019	0.7869	0.8021	0.7707	0.6934	0.7720
17 Contrast change (CC)	0.5811	0.4251	0.6026	0.7266	0.6974	0.7111	0.3199	0.8108
18 Change of color saturation (CSS)	0.3294	0.4184	0.4590	0.8228	0.8052	0.4234	0.2846	0.7583
19 Multipl. Gauss. noise (MGN)	0.9204	0.7730	0.7896	0.8660	0.9136	0.8911	0.8529	0.8759
20 Comfort noise (CN)	0.8702	0.9016	0.9022	0.9463	0.9546	0.9562	0.9444	0.8476
21 Lossy compr. of noisy (LCN)	0.9429	0.8960	0.9174	0.9564	0.9636	0.9703	0.9562	0.7889
22 Image color quant. w. dither (CQWD)	0.9308	0.8773	0.8619	0.8911	0.8963	0.9192	0.8779	0.8721
23 Chromatic aberrations (CA)	0.9556	0.9592	0.9770	0.9794	0.9748	0.9737	0.9696	0.9473
24 Sparse sampl. and reconstr. (SSR)	0.9296	0.9477	0.9667	0.9776	0.9808	0.9849	0.9766	0.9349
Max	0.9731	0.9592	0.9770	0.9794	0.9858	0.9849	0.9766	0.9594
Min	0.2410	0.3632	0.4590	0.5542	0.4984	0.4234	0.2846	0.6845
波动范围宽度	0.7321	0.5959	0.5181	0.4252	0.4873	0.5614	0.6920	0.2750
所有整体精度	0.7062	0.7402	0.7895	0.8769	0.9000	0.8553	0.8267	0.8648

DownLoad: CSV

[1]	Nightingale J, Salva P, Alcarazcalero J M, Wang Q 2018 IEEE Trans. Broadcast. 64 621 Google Scholar
[2]	丰卉, 孙彪, 马书根 2017 物理学报 66 180202 Google Scholar Feng H, Sun B, Ma S G 2017 Acta Phys. Sin. 66 180202 Google Scholar
[3]	Yao J C, Liu G Z 2019 IEEE Trans. Broadcast. 65 546 Google Scholar
[4]	Chandler D M, Hemami S S 2007 IEEE Trans. Image Process. 16 2284 Google Scholar
[5]	Wang Z, Bovik A C, Sheikh H R, Simoncelli E P 2004 IEEE Trans. Image Process. 13 600
[6]	Zhang L, Zhang L, Mou X, Zhang D 2011 IEEE Trans. Image Process. 20 2378 Google Scholar
[7]	Xue W, Zhang L, Mou X, Bovik A C 2014 IEEE Trans. Image Process. 23 684 Google Scholar
[8]	Zhang L, Shen Y, Li H 2014 IEEE Trans. Image Process. 23 4270 Google Scholar
[9]	Larson E C, Chandler D M 2010 J. Electron. Imaging 19 011006 Google Scholar
[10]	Fang Y M, Yan J B, Li L D, Wu J J, Lin W S 2018 IEEE Trans. Image Process. 27 1600 Google Scholar
[11]	方志明, 崔荣一, 金璟璇 2017 物理学报 66 109501 Google Scholar Fang Z M, Cui R Y, Jin J X 2017 Acta Phys. Sin. 66 109501 Google Scholar
[12]	Qi H, Jiao S H, Lin W S, Tang L, Shen W H 2014 Electron. Lett. 50 1435
[13]	Zheng L, Shen L, Chen J, An P, Luo J 2019 IEEE Trans. Multimedia 21 2057 Google Scholar
[14]	Yang X, Wang T, Ji G 2020 IET Image Proc. 14 384 Google Scholar
[15]	Ahar A, Barri A, Schelkens P 2018 IEEE Trans. Image Process. 27 879 Google Scholar
[16]	Zhou W J, Yu L, Zhou Y, Qiu W W, Wu M W 2018 IEEE Trans. Image Process. 27 2086
[17]	Yao J C, Liu G Z 2018 IET Image Proc. 12 872 Google Scholar
[18]	Wang X, Meng F, Huang X Y 2018 Proceeding of the 11 th International Congress on Image and Signal Processing, BioMedical Engineering and Informatics (CISP-BMEI) Beijing, China, October 13—15, 2018 p1
[19]	Ginesu G, Massidda F, Giusto D D 2006 Signal Process. Image Commun. 21 316 Google Scholar
[20]	Nadenau M 2000 Ph. D Dissertation (Lausanne: École Polytechnique Fédérale de Lausanne)
[21]	Niu Y Z, Zhang H F, Guo W Z, Ji R R 2018 IEEE Trans. Circuits Syst. Video Technol. 28 849
[22]	王鸿南, 钟文, 汪静, 夏德深 2004 中国图象图形学报 9 828 Google Scholar Wang H N, Zhong W, Wang J, Xia D S 2004 J. Image Graph. 9 828 Google Scholar
[23]	Sheikh H R, Wang Z, Cormack L LIVE Image Quality Assessment Database Release 2 Available: http://live.ece. utexas.edu/research/quality [2019-12-20]
[24]	Larson E C, Chandler D M The CSIQ image database http://vision.okstate.edu/?loc=csiq [2019-12-20]
[25]	Ponomarenko N, Lukin V, Zelensky A, Egiazarian K, Carli M, Battisti F Tampere Image Database 2008 TID2008, version 1.0 http://www.ponomarenko.info/tid2008.htm [2019-12-20]
[26]	Ponomarenko N, Jin L, Ieremeiev O, Lukin V, Egiazarian K, Astola J, Vozel B, Chehdi K, Carli M, Battisti F, Kuo C C J 2015 Signal Process. Image Commun. 30 57
[27]	Athar S, Wang Z 2019 IEEE Access 7 140030 Google Scholar
[28]	Callet L, Patrick A F Subjective quality assessment IRCCyN /IVC database http://www2.irccyn.ec-nantes.fr/ivcdb/ [2019-12-20]
[29]	Yi Z, Chandler D M 2018 IEEE Trans. Image Process. 27 5433
[30]	Dai T, Gu K, Niu L, et al. 2018 Neurocomputing 290 185
[31]	Zhang C, Cheng W, Hirakawa K 2019 IEEE Trans. Image Process. 28 1732

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Vol. 69, Issue 14 - 2020-07-20

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