[1] JENKINS F A, WHITE H E. Fundamentals of optics[M]. 4th ed. New York: McGraw-Hill Primls Custom Publishing, 2001: 266-267.

[2] DAUKANTAS P. 200 years of Fresnel’s legacy[J]. Optics and photonics news, 2015, 26(9): 40-47.

[3] WANG P, PENG S Y. Effects of placement method on the Fresnel double prism experiment[J]. Physics experimentation, 2009, 29(10): 34-36. (in Chinese)

[4] LIU Q W, WANG X H. Measurement of distance of virtual light sources using object equaling image method in Fresnel biprism interference[J]. College physics, 2017, 36(3): 28-31. (in Chinese)

[5] ZHANG S H, WU T A, ZHANG Y. Improving the adjustment method in biprism interference experiment[J]. Physical experiment of college, 2016, 29(4): 59-61. (in Chinese)

[6] DOBLAS A, SAAVEDRA G, MARTINEZ-CORRAL M, et al. Axial resonance of periodic patterns by using a Fresnel biprism[J]. Journal of the Optical Society of America A, 2013, 30(1): 140-148.

[7] EBRAHIMI S, DASHTDAR M, SáNCHEZ-ORTIGA E, et al. Stable and simple quantitative phase-contrast imaging by Fresnel biprism[J]. Applied physics letters, 2018, 112(11): 113701.

[8] CHAUSSARD F, RIGNEAULT H, FINOT C. Two-wave interferences space-time duality: Young slits, Fresnel biprism and Billet bilens[J]. Optics communications, 2017, 397: 31-38.

[9] EBRAHIMI S, DASHTDAR M, ANAND A, et al. Comon-path lensless digital holographic microscope employing a Fresnel biprism[J]. Optics and lasers in engineering, 2020, 128: 106014.

[10] HAYES-ROUNDS C, BOGUE-JIMENEZ B, GARCIA-SUCERQUIA J I, et al. Advantages of Fresnel biprism- based digital holographic microscopy in quantitative phase imaging[J]. Journal of biomedical optics, 2020, 25(8): 086501.

[11] ZHANG Y T, LI H G. Investigation of Fresnel biprism interference from the perspective of information optics[J]. Chinese optics, 2019, 12(1): 122-129. (in Chinese)

[12] ZHANG J, DAI S, MA C, et al. A review of common-path off-axis digital holography: towards high stable optical instrument manufacturing[J]. Light: advanced manufacturing, 2021, 2(3): 333-349.

[13] JAFARFARD M R. Dual-wavelength and double-field-of-view quantitative phase microscopy using a Fresnel bi-prism[J]. Optics continuum, 2022, 1(6): 1413-1417.

[14] JOGLEKAR M, TRIVEDI V, CHHANIWAL V, et al. LED based large field of view off-axis quantitative phase contrast microscopy by hologram multiplexing[J]. Optics express, 2022, 30(16): 29234-29245.

[15] INCLáN LADINO A, MENDOZA-HERNáNDEZ J, ARROYO-CARRASCO M L, et al. Large depth of focus plasmonic metalenses based on Fresnel biprism[J]. AIP advances, 2020, 10(4): 045025.

[16] LI H G, ZHANG R X, LIU Z D, et al. Second-order Talbot self-imaging effect in the time domain[J]. Physical review A, 2019, 100(1): 013846.

[17] JIA T T, LI Z G, YANG G, et al. Second-order Temporal Lau effect based on optical field intensity correlation[J]. Journal of optoelectronics·laser, 2021, 32(10): 1111-1118. (in Chinese)