[1] Xie Bo. Research of Quasi-static 3D Ultrasound Elastography[D]. South China University of Technology, 2013. 12-14.

[2] Cai Weirui. A Research on the Technique of Magnetic Resonance Elastography based on Pneumatic Driver[D]. Changsha: Hunan University, 2012. 22-25.

[3] Ophir J, Alam S K, Garra B, et al.. Elastography: ultrasonic estimation and imaging of the elastic properties of tissues [J]. Proceedings of the Institution of Mechanical Engineers, 1999, 213(3): 203-233.

[4] Liang X, Oldenburg A L, Crecea V, et al.. Optical micro-scale mapping of dynamic biomechanical tissue properties[J]. Optics Express, 2008, 16(15): 11052-11065.

[5] Adie S G, Kennedy B F, Armstrong J, et al.. Audio frequency in vivo optical coherence elastography[J]. Physics in Medicine and Biology, 2009, 54(10): 3129-3139.

[6] Kennedy B F, Hillman T R, McLaughlin R A, et al.. In vivo dynamic optical coherence elastography using a ring actuator [J]. Optics Express, 2009, 17(24): 21762-21772.

[7] Li C, Guan G, Cheng X, et al.. Quantitative elastography provided by surface acoustic waves measured by phasesensitive optical coherence tomography[J]. Optics Letters, 2012, 37(4): 722-724.

[8] Scruby C B, Drain L E. Laser ultrasonics techniques and applications[M]. Boca Raton: CRC Press, 1990. 57-59.

[9] Wang H C, Fleming S, Lee Y C, et al.. Laser ultrasonic surface wave dispersion technique for non- destructive evaluation of human dental enamel[J]. Optics Express, 2009, 17(18): 15592-15607.

[10] Schneider D, Schwarz T. A photoacoustic method for characterising thin films[J]. Surface and Coatings Technology, 1997, 91(1): 136-146.

[11] Sohn Y, Krishnaswamy S. Mass spring lattice modeling of the scanning laser source technique[J]. Ultrasonics, 2002, 39(8): 543-551.

[12] Zhu J. Non- contact ndt of concrete structures using air coupled sensors[R]. Newmark Structural Engineering Laboratory. University of Illinois at Urbana-Champaign., 2008.

[13] Li C, Guan G, Cheng X, et al.. Quantitative elastography provided by surface acoustic waves measured by phasesensitive optical coherence tomography[J]. Optics Letters, 2012, 37(4): 722-724.

[14] Li C, Guan G, Huang Z, et al.. Noncontact all-optical measurement of corneal elasticity[J]. Optics Letters, 2012, 37(10): 1625-1627.

[15] Wang S, Larin K V, Li J, et al.. A focused air-pulse system for optical-coherence-tomography-based measurements of tissue elasticity[J]. Laser Physics Letters, 2013, 10(7): 075605.

[16] Song S, Huang Z, Wang R K. Tracking mechanical wave propagation within tissue using phase- sensitive optical coherence tomography: motion artifact and its compensation[J]. Journal of Biomedical Optics, 2013, 18(12): 121505.

[17] Song S, Huang Z, Nguyen T M, et al.. Shear modulus imaging by direct visualization of propagating shear waves with phase-sensitive optical coherence tomography[J]. Journal of Biomedical Optics, 2013, 18(12): 121509.

[18] Qi W, Chen R, Chou L, et al.. Phase- resolved acoustic radiation force optical coherence elastography[J]. Journal of Biomedical Optics, 2012, 17(11): 110505.

[19] Kennedy B F, Liang X, Adie S G, et al.. In vivo three- dimensional optical coherence elastography[J]. Optics Express, 2011, 19(7): 6623-6634.

[20] Liang X, Oldenburg A L, Crecea V, et al.. Optical micro- scale mapping of dynamic biomechanical tissue properties[J]. Optics express, 2008, 16(15): 11052-11065.

[21] Kennedy B F, Wojtkowski M, Szkulmowski M, et al.. Improved measurement of vibration amplitude in dynamic optical coherence elastography[J]. Biomedical Optics Express, 2012, 3(12): 3138-3152.

[22] Liang X, Adie S G, John R, et al.. Dynamic spectral-domain optical coherence elastography for tissue characterization [J]. Optics Express, 2010, 18(13): 14183-14190.

[23] Kennedy B F, Koh S H, McLaughlin R A, et al.. Strain estimation in phase-sensitive optical coherence elastography[J]. Biomedical Optics Express, 2012, 3(8): 1865-1879.

[24] Crecea V, Oldenburg A L, Liang X, et al.. Magnetomotive nanoparticle transducers for optical rheology of viscoelastic materials[J]. Optics Express, 2009, 17(25): 23114-23122.

[25] Oldenburg A, Toublan F, Suslick K, et al.. Magnetomotive contrast for in vivo optical coherence tomography[J]. Optics Express, 2005, 13(17): 6597-6614.

[26] Kennedy B F, Kennedy K M, Sampson D D. A review of optical coherence elastography: fundamentals, techniques and prospects[J]. IEEE J Sel Top Quantum Electron, 2014, 20(2): 7101217.

[27] Li C, Guan G, Cheng X, et al.. Quantitative elastography provided by surface acoustic waves measured by phasesensitive optical coherence tomography[J]. Optics Letters, 2012, 37(4): 722-724.

[28] Doyley M M. Model- based elastography: a survey of approaches to the inverse elasticity problem[J]. Physics in medicine and biology, 2012, 57(3): R35-R73.

[29] S C Cowin, and S. B. Doty. Tissue Mechanics[M]. New York: Springer, 2007. 113-116.

[30] S J Kirkpatrick, D D Duncan. Optical assessment of tissue mechanics[M]// V V Tuchin. handbook of optical biomedical diagnostics. Bellingham: SPIE Press, 2002, 2(7): 1037-108.

[31] Ophir J, Alam S K, Garra B, et al.. Elastography: ultrasonic estimation and imaging of the elastic properties of tissues[J]. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 1999, 213(3): 203-233.

[32] Greenleaf J F, Fatemi M, Insana M. Selected methods for imaging elastic properties of biological tissues[J]. Annual review of biomedical engineering, 2003, 5(1): 57-78.

[33] Parker K J, Doyley M M, Rubens D J. Imaging the elastic properties of tissue: the 20 year perspective[J]. Physics in medicine and biology, 2012, 57(16): 5359-5360.

[34] Parker K J, Taylor L S, Gracewski S, et al.. A unified view of imaging the elastic properties of tissue[J]. The Journal of the Acoustical Society of America, 2005, 117(5): 2705-2712.

[35] T A Krouskop, T M Wheeler, F Kallel, et al.. Elastic moduli of breast and prostate tissues under compression[J]. Ultrasonic Imaging, 1998, 20(4): 260-274.

[36] B F Kennedy, S H Koh, R A McLaughlin, et al.. Strain estimation in phase-sensitive optical coherence elastography[J]. Biomedical Optics Express, 2012, 3(8): 1865-1879.

[37] Zaitsev V Y, Matveev L A, Matveyev A L, et al.. Elastographic mapping in optical coherence tomography using an unconventional approach based on correlation stability[J]. Journal of Biomedical Optics, 2014, 19(2): 021107.

[38] Sun C, Vuong C, Wen X, et al.. Preliminary study of digital image correlation based optical coherence elastography[C]. SPIE, 2013, 8802: 880207.

[39] Parker K J, Taylor L S, Gracewski S, et al.. A unified view of imaging the elastic properties of tissue[J]. The Journal of the Acoustical Society of America, 2005, 117(5): 2705-2712.

[40] Szkulmowski M, Szkulmowska A, Bajraszewski T, et al.. Flow velocity estimation using joint spectral and time domain optical coherence tomography[J]. Optics Express, 2008, 16(9): 6008-6025.

[41] Ding Zhihua, Zhao Chen, Bao Wen, et al.. Advances in doppler optical coherence tomography[J]. Laser & Optoelectronics Progress, 2013, 50(8): 080005.

[42] Kallel F, Ophir J. A least-squares strain estimator for elastography[J]. Ultrasonic imaging, 1997, 19(3): 195-208.

[43] Zhang X, Greenleaf J F. Estimation of tissue′ s elasticity with surface wave speed[J]. The Journal of the Acoustical Society of America, 2007, 122(5): 2522-2525.

[44] Wang Chi, Bi Shubo, Ding Wei，et al.. Optical characteristic parameters of gradient- index fiber probe[J]. Chinese J Lasers, 2012, 39(9): 0905001.

[45] Chong Bo, Zhu Yongkai. Method to improve axial resolution of spectral domain optical coherence tomography[J]. Acta Optica Sinica, 2012, 33(2): 0217001.