[1] G CASTANET, L PERRIN, O CABALLINA. Evaporation of closely-spaced interacting droplets arranged in a single row. International Journal of Heat and Mass Transfer, 93, 788-802(2016).

[2] W C TABER, A K AGRAWAL, J A BITTLE. Quantifying liquid boundary and vapor distributions in a fuel spray by rainbow schlieren deflectometry. Applied Optics, 56, 8385-8393(2017).

[3] 宋飞虎, Feihu SONG, 陈海英, Haiying CHEN. Twin primary rainbows scattered by micro-channel with circular cross-section. Journal of Applied Optics, 37, 17-23(2016).

[4] X WU, H JIANG, Y WU. One-dimensional rainbow thermometry system by using slit apertures. Optics Letters, 39, 638-641(2014).

[5] H T YU, F XU, C TROPEA. Optical caustics associated with the primary rainbow of oblate droplets: Simulation and application in non-sphericity measurement. Optics Express, 21, 25761-25771(2013).

[6] H T YU, F XU, C TROPEA. Simulation of optical caustics associated with the secondary rainbow of oblate droplets. Optics Letters, 38, 4469-4472(2013).

[7] J A LOCK, G P KONNEN. Rainbows by elliptically deformed drops I Möbius shift for high-order rainbows. Applied Optics, 56, G88-G97(2017).

[8] C D ROSEBROCK, S SHIRINZADEH, M SOEKEN. Time-resolved detection of diffusion limited temperature gradients inside single isolated burning droplets using Rainbow Refractometry. Combustion and Flame, 168, 255-269(2016).

[9] Yingchun WU, J PROMVONGSA, S SAENGKAEW. Phase rainbow refractometry for accurate droplet variation characterization. Optics Letters, 41, 4672-4675(2016).

[10] J PROMVONGSA, P VALLIKUL, B FUNGTAMMASAN. Multicomponent fuel droplet evaporation using 1D Global Rainbow Technique. Proceedings of the Combustion Institute, 36, 2401-2408(2017).

[11] Yingchun WU, C CYRIL, Haipeng LI, et, al. Simultaneous measurement of monocomponent droplet temperature/refractive index, size and evaporation rate with phase rainbow refractometry. Journal of Quantitative Spectroscopy & Radiative Transfer, 214, 146-157(2018).

[12] 管露露, Lulu GUAN, 于海涛, Haitao YU, 沈建琪, Jianqi SHEN. Third- and fourth-order rainbow fringe characteristics of homogeneous ellipsoid droplets. Acta Optica Sinica, 366-373(2017).

[13] 孙辉, Hui SUN, 于海涛, Haitao YU, 沈建琪, Jianqi SHEN. Study of drop measurement based on Gaussian beam scattering in the primary rainbow region. Acta Photonica Sinica, 47, 0129003(2017).

[14] 宋飞虎, Feihu SONG, 李臻峰, Zhenfeng LI. Reversion algorithm of global rainbow technique based on optimization process. Laser & Optoelectronics Progress, 32, 110-116(2016).

[15] Y H WANG, C H YEH, H W V YOUNG. On the computational complexity of the empirical mode decomposition algorithm. Physica A: Statistical Mechanics and its Applications, 400, 159-167(2014).

[16] T S NGUYEN, C C CHANG, N T HUYNH. A novel reversible data hiding scheme based on difference-histogram modification and optimal EMD algorithm. Journal of Visual Communication and Image Representation, 33, 389-397(2015).

[17] F D CARNELOSSI, L S OLIVEIRA, D MENOTTI. Bias effect on predicting market trends with EMD. Expert Systems with Applications, 82, 19-26(2017).

[18] [18] BOHREN C F, HUFFMAN D R. Absption scattering of light by small particles[M]. New Yk:A WileyInterscience Publication, 1983.

[19] S GRZEGORZ, J MROCZKA. Approximate solution for optical measurements of the diameter and refractive index of a small and transparent fiber. Journal of the Optical Society of America A, 33, 667-676(2016).

[20] L PHILIP. Supernumerary arcs of rainbows: Young’s theory of interference. Applied Optics, 56, G104-G112(2017).

[21] T ZHANG, G FENG, Z SONG. A single-element interferometer for measuring refractive index of transparent liquids. Optics Communications, 332, 14-17(2014).

[22] [22] JOHN R. Hbook of chemistry physics, 99th edition[M]. Boca Raton: CRC Press, 2018.