[{“box”:0,”content”:”[if 992 equals=”Open Access”]n
n
Open Access
nn
n
n[/if 992]n
n
n
n
n
n
Aiswarya Nair P, Farsana Muhammed
n
- n t
n
n
n[/foreach]
n
n[if 2099 not_equal=”Yes”]n
- [foreach 286] [if 1175 not_equal=””]n t
- MTech. Scholar, Assistant Professor Department of Electrical and electronics Engineering,TKMCE, Department of Electrical and electronics Engineering,TKMCE Kerala, Kerala India, India
n[/if 1175][/foreach]
n[/if 2099][if 2099 equals=”Yes”][/if 2099]n
Abstract
nThe fundamental concept of operation for the Fabry-Perot interferometer is interference. Coherent light bounces back and forth between two extremely reflecting mirrors as it travels through the interferometer. The device operates on a pattern of constructive and destructive interference that is produced by this. By carefully regulating the space between the mirrors, a resonant optical cavity is created. The Fabry-Perot interferometer (FPI) is one of the most important and versatile optical devices in modern science and engineering. It was named after the physicists Charles Fabry and Alfred Perot, who developed it in the late 19th century. This interferometer has many uses, from spectroscopy and telecommunications to sensing and measurement. Some of the modern research in this field are worth noting due to their uniqueness and the new possibilities they open for further studies and advancements. Some major application discussed in this paper include gas pressure sensing, temperature sensing, load sensing and refractive index measurement.
n
Keywords: Fabry-Perot interferometer, spectroscopy, telecommunication, gas pressure sensing, temperature sensing, load sensing and refractive index measurement.
n[if 424 equals=”Regular Issue”][This article belongs to Journal of Semiconductor Devices and Circuits(josdc)]
n
n
n
n
n
nn[if 992 equals=”Open Access”] Full Text PDF Download[/if 992] n[if 992 not_equal=”Open Access”]
[/if 992]n[if 992 not_equal=”Open Access”] nnn[/if 992]nn[if 379 not_equal=””]n
Browse Figures
n
n[/if 379]n
References
n[if 1104 equals=””]n
] Jian Tang, Guolu Yin, Changrui Liao, Shen Liu, Zhengyong Li, Xiaoyong Zhong, Qiao Wang, Jing Zhao, Kaiming Yang and Yiping Wang, “High-Sensitivity Gas Pressure Sensor Based on Fabry–Pérot Interferometer With a Side-Opened Channel in Hollow-Core Photonic Bandgap Fiber”, IEEE Photonics Journal, Vol.7, Issue 6, 2015
[2] Delin Zhao, Yongfeng Wuna and Jing Wu , “Pressure and Temperature Sensor Based on Fiber-Optic Fabry-Perot Interferometer by Phase Demodulation”, IEEE Access, Vol.7, 2019
[3] Chongjie Qi, Minghong Yang, Dongwen Lee, Weijing Xie and Jixiang Dai , “Improved Sensitivity of Fiber Fabry–Perot Interferometer Based on Phase-Tracking Algorithm”, IEEE Sensors Journal, Vol.15, Issue 10, 2015
[4] Yongfeng Wu, Bo Liu, Jing Wu, Lilong Zhao, Tingting Sun, Yaya Mao, Tong Nan and Jin Wang, “A Transverse Load Sensor With Ultra-Sensitivity Employing Vernier-Effect Improved Parallel-Structured Fiber-Optic Fabry-Perot Interferometer”, IEEE Access, Vol.7, 2019
[5] Meng Wang, Yijian Huang, Li Yu;Zongpeng Song, Dezhi Liang and Shuangchen Ruan , “Multiwavelength Thulium-Doped Fiber Laser Using a Micro Fiber-Optic Fabry–Perot Interferometer”, IEEE Photonics Journal, Vol.10. Issue 4, 2018
[6] X. L. Tan, Y. F. GengX. J. Li, Y. L. Deng, Z. Yin and R. Gao , “UV-Curable Polymer Microhemisphere-Based Fiber-Optic Fabry–Perot Interferometer for Simultaneous Measurement of Refractive index and Temperature”, IEEE Photonics Journal, Vol.6, Issue 4, 2014
[7] Christer Holmlund and Roberts Trops, “Implementation of a Controller for a Space-Grade, Piezo-Actuated Fabry-Perot Interferometer”, IEEE Access, Vol.10, 2022
[8] Danping Xu, Haitao Gao, Zheyu Hou, Yanan Zhang, Xuanxiang Tong, Yizhuo Zhang, Pengyu Zhang, Jian Shen and Chaoyang Li “A High-Sensitivity Fiber-Optic Fabry-Perot Gas Pressure Sensor With Epoxy Resin Adhesive”, IEEE Sensors Journal, Vol.22, Issue 11, 2022
[9] Yunqing Guan;Biao Yin;Xiaopeng Dong, “A High-Precision Method for the Determination of Cavity Length of a Fabry-Perot Interferometer”, IEEE Photonics Journal, Vol.14, Issue 3, 2022
[10] Peng Zhang, Shuang Wang, Junfeng Jiang, Zhiyuan Li, Haokun Yang and Tiegen Liu, “A Fiber-Optic Accelerometer Based on Extrinsic Fabry-Perot Interference for Low Frequency Micro-Vibration Measurement”, IEEE Photonics Journal, Vol.14, Issue 4, 2022
nn[/if 1104][if 1104 not_equal=””]n
- [foreach 1102]n t
- [if 1106 equals=””], [/if 1106][if 1106 not_equal=””],[/if 1106]
n[/foreach]
n[/if 1104]
nn
nn[if 1114 equals=”Yes”]n
n[/if 1114]
n
n
n
n
n
n
n
| Volume | 11 | |
| [if 424 equals=”Regular Issue”]Issue[/if 424][if 424 equals=”Special Issue”]Special Issue[/if 424] [if 424 equals=”Conference”][/if 424] | 01 | |
| Received | May 15, 2024 | |
| Accepted | May 25, 2024 | |
| Published | June 5, 2024 |
n
n
n
n
n
n function myFunction2() {n var x = document.getElementById(“browsefigure”);n if (x.style.display === “block”) {n x.style.display = “none”;n }n else { x.style.display = “Block”; }n }n document.querySelector(“.prevBtn”).addEventListener(“click”, () => {n changeSlides(-1);n });n document.querySelector(“.nextBtn”).addEventListener(“click”, () => {n changeSlides(1);n });n var slideIndex = 1;n showSlides(slideIndex);n function changeSlides(n) {n showSlides((slideIndex += n));n }n function currentSlide(n) {n showSlides((slideIndex = n));n }n function showSlides(n) {n var i;n var slides = document.getElementsByClassName(“Slide”);n var dots = document.getElementsByClassName(“Navdot”);n if (n > slides.length) { slideIndex = 1; }n if (n (item.style.display = “none”));n Array.from(dots).forEach(n item => (item.className = item.className.replace(” selected”, “”))n );n slides[slideIndex – 1].style.display = “block”;n dots[slideIndex – 1].className += ” selected”;n }n”}]