Panov, V.
(2023).
The scientific process of two interferometers (optical) development and the mitigation of external influence.
Scientific Herald of Uzhhorod University. Series "Physics",
(53),
19-30.
https://doi.org/10.54919/physics/53.2023.19
The scientific process of two interferometers (optical) development and the mitigation of external influence
https://doi.org/10.54919/physics/53.2023.19
Abstract
Relevance. The research relevance is predefined by the fact that the presented object of analysis, namely the interferometer, plays an important role in modern science in obtaining accurate measurements and their results, which sets the requirements for improving interferometers and eliminating external influences.
Purpose. The research aims to analyze the progress of the development process of two interferometers, which are used in many scientific spheres, especially in optics, and play an important role in accurate measurement results of research, as well as finding new and effective technologies to eliminate external influences.
Methods. Among the methods used are an analytical method, logical analysis method, functional method, statistical method, synthesis method, and others.
Results. Throughout the study, two compensators and the differences between them were noted, and the features of these compensators’ operation and their reliability were also analyzed. The negative factors that prevent more accurate measurements by interferometer were identified, and the most damaged elements in interferometers and their causes of damage were also identified. It is important to analyze the functioning of interferometers and compensators, and their operating conditions to assess the degree of efficiency, relevance, and progress in optics. The issues of evaluation of the development and problems of two schemes of interferometers with trapezoidal and square beamsplitters were also considered, and recommendations were proposed that would contribute to a more effective mechanism for regulating this issue.
Conclusions. It was determined that the process of developing new generation interferometers and eliminating external influences on them plays a crucial role in the development of optics, significantly affecting the progress in this area. The practical value lies in the application of the identified results, solving the problems of the process of developing interferometers and their progress in operation, taking into account various external influences, which will help to change the scheme of approach to the development of this mechanism and increase resistance to negative external influences
Keywords: compensators, measurements, negative factors, schemes, beam entry
Suggested citation
References
[1] Kolomiytsov YV. Interferometers: Fundamentals of engineering theory. Application. Engineering. Leningrad: Mashinostroyeniye; 1976. 296 p.
[2] Chen Z, Zhang Y, Fan Y, Wang J, Lyu W, Zheng D, et al. Close observation of the evolution process during initial stage of triggered lightning based on continuous interferometer. Remote Sens. 2022;14(4):863. DOI: 10.3390/RS14040863.
[3] Chen B, Jiang J, Lou Y, Yan L. Active linearized PGC demodulation with fusion of PGC-Arctan and PGC-DCM schemes for nonlinear error elimination in SPM interferometer. Opt Express. 2022;30(13):22999–23010. DOI: 10.1364/OE.463593.
[4] Hu M, Yao C, Ventura A, Hayashi JG, Poletti F, Ren W. A comparative study of mid-infrared photothermal spectroscopy with different fiber interferometers. In: Optics and photonics for sensing the environment. Washington: Optica Publishing Group; 2022:3717–3721. DOI: 10.1364/es.2022.etu4h.2.
[5] Zhang H, Wang B, Ning J, Li Y. Interferometry imaging using high-speed-train induced seismic waves. Chin J Geophys. 2019;62(6):2321–2327. DOI: 10.6038/cjg2019M0676.
[6] Lendiel V, Stepakhno I, Yarovoi L. Application of three-wave heterodine interferometry for nanorized layers thickness measurement in the process of their deposition. Bull Kyiv Polytech Inst Ser Instrum Mak., 2022; 63(1):39–45. DOI: 10.20535/1970.63(1).2022.260636.
[7] Gryaznov NA, Goryachkin DA, Kuprenyuk VI, Sosnov EN, Alekseev VL. Passive stabilisation Michelson interferometer. Sci Instrum. 2020;30(4):67–74.
[8] Panov VV, inventor; Ukrainian Institute of Intellectual Property, assignee. Panov interferomete. Ukraine patent 149469. 2021 Feb 08. Available from: https://sis.nipo.gov.ua/uk/search/detail/1651693/.
[9] Panov VV, inventor; Ukrainian Institute of Intellectual Property, assignee. Interferometer. Ukraine patent 149105. 2021 Feb 12. Available from: https://sis.nipo.gov.ua/uk/search/detail/1632108/.
[10] Kabashin AV, Nikitin PI. Interferometer using surface plasmon resonance for sensor applications. Quantum Electron. 1997;24(7):671–672. DOI: 10.1070/QE1997v027n07ABEH001013.
[11] Koronkevich VP, Lenkova GA. Laser interferometer for measuring length [Internet]. 1971 [cited 2022 Nov 30]. Available from: https://scholar.google.com.ua/scholar_host?q=info:8sp9_uci1Z8J:scholar.google.com/output=viewportpg=4hl=ukas_sdt=0,5.
[12] Ostapchuk AA. Research and calculation polarization properties of the interferometer using the method Jones. J Zhytomyr State Technol Univ Eng. 2015;2(73):154–158. DOI: 10.26642/tn-2015-2(73)-154-158.
[13] Vrancken P, Herbst J. Aeronautics application of direct-detection Doppler wind lidar: an adapted design based on a fringe-imaging Michelson interferometer as spectral analyzer. Remote Sens. 2022;14(14):3356. DOI: 10.3390/rs14143356.
[14] Thaisongkroh P, Pullteap S, Seat HC. Low-pressure measurement using an extrinsic fiber-based Fabry-Perot interferometer for industrial applications. Eng J. 2021;25(2):317–325. DOI: 10.4186/ej.2021.25.2.317.
[15] McKinley B, Trott CM, Sokolowski M, Wayth RB, Sutinjo A, Patra N, et al. The All-Sky SignAl Short-Spacing INterferometer (ASSASSIN)–I. Global-sky measurements with the Engineering Development Array-2. Mon Not R Astron Soc. 2020;499(1):52–67. DOI: 10.1093/mnras/staa2804.
[16] Pu Y, Cummer SA. Needles and lightning leader dynamics imaged with 100–200 MHz broadband VHF interferometry. Geophys Res Lett. 2019;46(22):13556–63. DOI: 10.1029/2019GL085635.
[17] Adhikari RX, Arai K, Brooks AF, Wipf C, Aguiar O, Altin P, et al. A cryogenic silicon interferometer for gravitational-wave detection. Class Quantum Gravity. 2020;37(16):165003. DOI: 10.1088/1361-6382/ab9143.
[18] Patel K, Nagora U, Joshi HC, Pathak S, Jadeja KA, Patel K, et al. LabVIEW-FPGA-based real-time data acquisition system for ADITYA-U heterodyne interferometry. IEEE Trans Plasma Sci. 2021;49(6):1891–1897. DOI: 10.1109/TPS.2021.3082159.
[19] Kim W, Jung J, Kim J, Shin I, Kim N, Lee M. A new approach in optical metrology with multi-angle information through self-interferometric ellipsometry. In: Applied optical metrology IV. Washington: SPIE; 2021. p. 26–33. DOI: 10.1117/12.2593375.
[20] Apsari R, Syadyyah H, Ningsih K, Yhuwana YGY. The development of the real-time Michelson interferometer for the measurement of thermal expansion coefficients of dental composites nanofiller. J Phys: Conf Ser. 2022;2274(1):012009. DOI: 10.1088/1742-6596/2274/1/012009.
[21] Lopez B, Lagarde S, Petrov RG, Jaffe W, Antonelli P, Allouche F, et al. MATISSE, the VLTI mid-infrared imaging spectro-interferometer. Astron Astrophys. 2022;659:192. DOI: 10.1051/0004-6361/202141785.
[22] Flores-Bravo JA, Illarramendi MA, Zubia J, Villatoro J. Optical fiber interferometer for temperature-independent refractive index measuring over a broad range. Opt Laser Technol. 2021;139:106977. DOI: 10.1016/j.optlastec.2021.106977.
