[1] [1] A. N. Bashkatov, E. A. Genina, V. V. Tuchin, “Optical properties of skin, subcutaneous, and muscle tissues: A review," J. Innovat. Opt. Health Sci. 4(1), 9–38 (2011).

[2] [2] D. S. Wiersma, “Disordered photonics," Nat. Photon 7(3), 188–196 (2013).

[3] [3] A. P. Mosk, A. Lagendijk, G. Lerosey, M. Fink, “Controlling waves in space and time for imaging and focusing in complex media," Nat. Photon 6(5), 283–292 (2012).

[4] [4] P. Hong, O. S. Ojambati, A. Lagendijk, A. P. Mosk, W. L. Vos, “Three-dimensional spatially resolved optical energy density enhanced by wavefront shaping," Optica 5(7), 844–849 (2018).

[5] [5] H. He, Y. Guan, J. Zhou, “Image restoration through thin turbid layers by correlation with a known object," Opt. Exp. 21(10), 12539–12545 (2013).

[6] [6] H. Hexiang, W. Kam Sing, “An improved wavefront determination method based on phase conjugation for imaging through thin scattering medium," J. Opt. 18(8), 085604 (2016).

[7] [7] F. Wang, H. He, H. Zhuang, X. Xie, Z. Yang, Z. Cai, H. Gu, J. Zhou, “Controlled light field concentration through turbid biological membrane for phototherapy," Biomed. Opt. Exp. 6(6), 2237–2245 (2015).

[8] [8] A. Velten, T. Willwacher, O. Gupta, A. Veeraraghavan, M. G. Bawendi, R. Raskar, “Recovering three-dimensional shape around a corner using ultrafast time-of-flight imaging," Nat. Commun. 3, 745 (2012).

[9] [9] G. Satat, B. Heshmat, D. Raviv, R. Raskar, “All photons imaging through volumetric scattering," Sci. Rep. 6, 33946 (2016).

[10] [10] Z. Yaqoob, D. Psaltis, M. S. Feld, C. Yang, “Optical phase conjugation for turbidity suppression in biological samples," Nat. Photon 2(2), 110–115 (2008).

[11] [11] C. Ma, X. Xu, Y. Liu, L. V. Wang, “Time-reversed adapted-perturbation (TRAP) optical focusing onto dynamic objects inside scattering media," Nat. Photon. 8, 931 (2014).

[12] [12] J. Yang, J. Li, S. He, L. V. Wang, “Angular-spectrum modeling of focusing light inside scattering media by optical phase conjugation," Optica 6(3), 250–256 (2019).

[13] [13] M. Qiao, H. Liu, S. Han, “Bidirectional image transmission through physically thick scattering media using digital optical phase conjugation," Opt. Exp. 26(25), 33066–33079 (2018).

[14] [14] Y.-W. Yu, C.-C. Sun, X.-C. Liu, W.-H. Chen, S.-Y. Chen, Y.-H. Chen, C.-S. Ho, C.-C. Lin, T.-H. Yang, P.-K. Hsieh, “Continuous amplified digital optical phase conjugator for focusing through thick, heavy scattering medium," OSA Continuum 2(3), 703–714 (2019).

[15] [15] Y. M. Wang, B. Judkewitz, C. A. DiMarzio, C. Yang, “Deep-tissue focal fluorescence imaging with digitally time-reversed ultrasound-encoded light," Nat. Commun. 3, 928 (2012).

[16] [16] L. Zhao, M. Yang, Y. Jiang, C. Li, “Optical fluence compensation for handheld photoacoustic probe: An in vivo human study case," J. Innovat. Opt. Health Sci. 10(4), 1740002 (2017).

[17] [17] Y. Baek, K. Lee, Y. Park, “High-resolution holographic microscopy exploiting speckle-correlation scattering matrix," Phys. Rev. Appl. 10(2), 024053 (2018).

[18] [18] B. Zhuang, C. Xu, Y. Geng, G. Zhao, H. Chen, Z. He, L. Ren, “An early study on imaging 3D objects hidden behind highly scattering media: A round-trip optical transmission matrix method," Appl. Sci. 8(7), 1036 (2018).

[19] [19] S. M. Popoff, G. Lerosey, R. Carminati, M. Fink, A. C. Boccara, S. Gigan, “Measuring the transmission matrix in optics: An approach to the study and control of light propagation in disordered media," Phys. Rev. Let. 104(10), 100601 (2010).

[20] [20] S. Popoff, G. Lerosey, M. Fink, A. C. Boccara, S. Gigan, “Image transmission through an opaque material," Nat. Commun. 1, 81 (2010).

[21] [21] S. Li, J. Zhong, “Dynamic imaging through turbid media based on digital holography," J. Opt. Soc. Am. A 31(3), 480–486 (2014).

[22] [22] A. K. Singh, D. N. Naik, G. Pedrini, M. Takeda, W. Osten, “Looking through a diffuser and around an opaque surface: A holographic approach," Opt. Exp. 22(7), 7694–7701 (2014).

[23] [23] W. Harm, C. Roider, A. Jesacher, S. Bernet, M. Ritsch-Marte, “Lensless imaging through thin diffusive media," Opt. Exp. 22(18), 22146–22156 (2014).

[24] [24] F. Isaac, “Looking through walls and around corners," Physica A 168(1), 49–65 (1990).

[25] [25] J. A. Newman, K. J. Webb, “Imaging optical fields through heavily scattering media," Phys. Rev. Lett. 113(26), 263903 (2014).

[26] [26] G. Stern, O. Katz, “Noninvasive focusing through scattering layers using speckle correlations," Opt. Lett. 44(1), 143–146 (2019).

[27] [27] Y. Li, Y. Xue, L. Tian, “Deep speckle correlation: A deep learning approach toward scalable imaging through scattering media," Optica 5(10), 1181–1190 (2018).

[28] [28] M. Cua, E. Zhou, C. Yang, “Imaging moving targets through scattering media," Opt. Exp. 25(4), 3935–3945 (2017).

[29] [29] T. Wu, O. Katz, X. Shao, S. Gigan, “Single-shot diffraction-limited imaging through scattering layers via bispectrum analysis," arXiv:1608.05200.

[30] [30] Y. Shi, Y. Liu, J. Wang, T. Wu, “Non-invasive depth-resolved imaging through scattering layers via speckle correlations and parallax," Appl. Phys. Lett. 110(23), 231101 (2017).

[31] [31] E. Edrei, G. Scarcelli, “Optical imaging through dynamic turbid media using the Fourier-domain shower-curtain effect," Optica 3(1), 71–74 (2016).

[32] [32] K. T. Takasaki, J. W. Fleischer, “Phase-space measurement for depth-resolved memory-effect imaging," Opt. Exp. 22(25), 31426–31433 (2014).

[33] [33] J. Bertolotti, E. G. van Putten, C. Blum, A. Lagendijk, W. L. Vos, A. P. Mosk, “Non-invasive imaging through opaque scattering layers," Nature 491(7423), 232–234 (2012).

[34] [34] H. Zhuang, H. He, X. Xie, J. Zhou, “High speed color imaging through scattering media with a large field of view," Sci. Rep. 6, 32696 (2016).

[35] [35] O. Katz, P. Heidmann, M. Fink, S. Gigan, “Noninvasive single-shot imaging through scattering layers and around corners via speckle correlations," Nat. Photon 8(10), 784–790 (2014).

[36] [36] S. Feng, C. Kane, P. A. Lee, A. D. Stone, “Correlations and fluctuations of coherent wave transmission through disordered media," Phys. Rev. Lett. 61(7), 834–837 (1988).

[37] [37] I. Freund, M. Rosenbluh, S. Feng, “Memory effects in propagation of optical waves through disordered media," Phys. Rev. Lett. 61(20), 2328–2331 (1988).

[38] [38] X. Xie, Y. Chen, K. Yang, J. Zhou, Harnessing the point-spread function for high-resolution far-field optical microscopy," Phys. Rev. Lett. 113(26), 263901 (2014).

[39] [39] X. Xie, H. Zhuang, H. He, X. Xu, H. Liang, Y. Liu, J. Zhou, “Extended depth-resolved imaging through a thin scattering medium with PSF manipulation," Sci. Rep. 8(1), 4585 (2018).

[40] [40] X. Xu, X. Xie, A. Thendiyammal, H. Zhuang, J. Xie, Y. Liu, J. Zhou, A. P. Mosk, “Imaging of objects through a thin scattering layer using a spectrally and spatially separated reference," Opt. Exp. 26(12), 15073–15083 (2018).

[41] [41] S. K. Sahoo, D. Tang, C. Dang, “Single-shot multispectral imaging with a monochromatic camera," Optica 4(10), 1209–1213 (2017).

[42] [42] Z. Wang, X. Jin, Q. Dai, “Non-invasive imaging through strongly scattering media based on speckle pattern estimation and deconvolution," Sci. Rep. 8(1), 9088 (2018).

[43] [43] Q. Chen, H. He, X. Xu, X. Xie, H. Zhuang, J. Ye, Y. Guan, “Memory effect based filter to improve imaging quality through scattering layers," IEEE Photon. J. 10(5), 6901010 (2018).

[44] [44] X. Xu, X. Xie, H. He, H. Zhuang, J. Zhou, A. Thendiyammal, A. P. Mosk, “Imaging objects through scattering layers and around corners by retrieval of the scattered point spread function," Opt. Exp. 25(26), 32829–32840 (2017).

[45] [45] L. Li, Q. Li, S. Sun, H.-Z. Lin, W.-T. Liu, P.-X. Chen, “Imaging through scattering layers exceeding memory effect range with spatial-correlationachieved point-spread-function," Opt. Lett. 43(8), 1670–1673 (2018).

[46] [46] D. Tang, S. K. Sahoo, V. Tran, C. Dang, “Singleshot large field of view imaging with scattering media by spatial demultiplexing," Appl. Opt. 57(26), 7533–7538 (2018).

[47] [47] M. O. Geokkan, M. Engin, “Artificial neural networks based estimation of optical parameters by diffuse reflectance imaging under in vitro conditions," J. Innovat. Opt. Health Sci. 10(1), 1650027 (2016).

[48] [48] J. W. Goodman, Speckle Phenomena in Optics: Theory and Applications, Roberts and Company Publishers (2007).

[49] [49] X. Yang, L. Xiang, “Photoacoustic imaging of prostate cancer," J. Innovat. Opt. Health Sci. 10(4), 1730008 (2017).

[50] [50] M. S. Wróbel, A. P. Popov, A. V. Bykov, M. Kinnunen, M. Jedrzejewska-Szczerska, V. V. Tuchin, “Multi-layered tissue head phantoms for noninvasive optical diagnostics," J. Innovat. Opt. Health Sci. 8(3), 1541005 (2014).

[51] [51] V. Crosignani, S. Jahid, A. Dvornikov, E. Gratton, “Deep tissue imaging by enhanced photon collection," J. Innovat. Opt. Health Sci. 7(5), 1450034 (2014).

[52] [52] A. R. Kherlopian, T. Song, Q. Duan, M. A. Neimark, M. J. Po, J. K. Gohagan, A. F. Laine, “A review of imaging techniques for systems biology," BMC Syst. Biol. 2(1), 74 (2008).

[53] [53] R. C. Gonzalez, R. E. Woods, Digital Image Processing, 2nd Edition (Prentice Hall, 2002).