[1] Zhang Jianqi, He Guojing, Liu Delian, et al. Infrared Laser Engineering, 2008, 37(4): 565568. (in Chinese)

[2] Zhang Jianqi, Wang Xiaui. Optoelectronic Imaging System Modeling Perfmance Evaluation They [M]. Xi''an: Xidian University Press, 2010: 305350. (in Chinese)

[3] D E Schmieder, M R Weathersby. Detection performance in clutter with variable resolution. IEEE Transactions on Aerospace and Electronic Systems, 19, 622-630(1983).

[4] S R Rotman, A Cohen, D Shame. Textural metrics for clutter affecting human target acquisition. Infrared Physics & Technology, 37, 667-674(1996).

[5] M V Shirvaikar, M M Trivedi. Developing texture-based image clutter measures for object detection. Opt Eng, 31, 2628-2639(1992).

[6] Biberman L M. Electrooptical Imaging System Perfmance Modeling [M]. US: SPIE Press, 2001: 121.

[7] Chang H H, Zhang J Q. Detection probability detection time using clutter metrics [J]. Infrared Physics & Technology, 2007, 51(2): 8390.

[8] H H Chang, J Q Zhang. New metrics for clutter affecting human target acquisition. IEEE Transactions on Aerospace & Electronic System, 42, 361-368(2006).

[9] Wang Zhou, A C Bovik, H R Sheikh, et al. Image quality assessment: From error visibility to structural similarity. IEEE Transactions on Image Processing, 13, 600-612(2004).

[10] Dejiang Xu, Zelin Shi, Haibo Luo. Image structure difference clutter measurement using human visual characteristics. Infrared and Laser Engineering, 42, 1635-1641(2013).

[11] Li Qian, Zhang Jianqi, Yang Cui. Edge structure background clutter scale[J]. Journal of Xidian University (Natural Science Edition), 2012, 39(3): 9599. (in Chinese)

[12] Chuanmin Xiao, Zelin Shi, Yunpeng Liu. Image background clutter measurement with gradient distribution feature. Optical Precision Engineering, 23, 3472-3479(2015).

[13] Qian Li, Cui Yang, Jianqi Zhang. Hidden Markov models for background clutter. Optical Engineering, 52, 073108(2013).

[14] Yang C, Wu J, Li Q. Sparserepresentationbased clutter metric[J]. Applied Optics, 2011, 50(11): 16011605.

[15] Li Q, Yang C, Zhang J. Target acquisition perfmance in a cluttered environment[J]. Applied Optics, 2012, 51(31): 76687673.

[16] Vollmerhausen R H, Jacobs E, Driggers R G. New metric f predicting target acquisition perfmance[J]. Optical Engineering, 2004, 43: 28062818.

[17] Albright T D. Direction ientation ivity of neurons in visual area MT of the macaque[J]. J Neurophysiol, 1984, 52(6): 1106–1130.

[18] Hubel D H, Wiesel T N. Receptive fields, binocular interaction functional architecture in the cat’s visual ctex[J]. J Physiol, 1962, 160(1): 106154.

[19] Hubel D H, Wiesel T N. Receptive fields functional architecture in two nonstriate visual areas (18 19) of the cat [J]. J Neurophysiol, 1965, 28: 229289.

[20] Hansel D, Vreeswijk C. The mechanism of ientation ivity in primary visual ctex without a functional map [J]. J Neurosci, 2012, 32(12): 40494064.

[21] Campbell F W, Kulikowski J J. ientational ivity of the human visual system [J]. J Physiol, 1966, 187(2): 437445.

[22] Wang Z, Bovik A, Sheikh H, et al. Image quality assessment: from err visibility to structural similarity [J]. IEEE Transactions on Image Processing, 2004, 13(4): 600612.

[23] Zhai G, Wu X, Yang X, et al. A psychovisual quality metric in freeenergy principle[J]. IEEE Transactions on Image Processing, 2012, 21(1): 4152.

[24] Friston K, Kilner J, Harrison L. A free energy principle f the brain[J]. J Physiology, 2006, 100(13): 7087.

[25] A Toet, P Bijl, J M Valeton. Image dataset for testing search and deletion models. Optical Engineering, 40, 1760-1767(2001).

[26] A Toet. Structural similarity determines search time and detection probability. Infrared Physics & Technology, 53, 464-468(2010).

[27] D L Wilson. Image-based contrast-to-clutter modeling of detection. Optical Engineering, 40, 1852-1857(2001).