基于三角形收缩法改进的分数傅里叶变换估计牛顿环参数

doi:10.3969/j.issn.1000-1158.2023.12.01

摘要
图/表
参考文献(21)
相关文章 (1)

全文: PDF (671 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要针对分数傅里叶变换用于牛顿环参数估计时速度较慢的问题,通过分析牛顿环条纹图分数傅里叶域幅值最大值与相应旋转角的分布规律,提出基于三角形收缩法改进的分数傅里叶变换进行牛顿环参数估计的方法。实验结果表明:该方法具有可行性,对于图像尺寸小于640×640pixels的条纹图,处理所需时间＜1s,随着图像尺寸增加,条纹图中包含的条纹数目增加,曲率半径估计值相对误差降低,而处理时间仍可满足工程实际需求。以处理1080×1080pixels的图像为例,估计值相对误差为0.001%,处理时间为3.31s。该方法估计720×720pixels高斯噪声污损的牛顿环干涉条纹图像平均用时1.28s,约为传统分数傅里叶变换用时的1/700。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	武进敏
	姜盛
	鲁溟峰
	沈德明
	范军芳
	李亚峰
	张峰
	陶然

关键词 ：光学计量, 透镜曲率半径, 牛顿环条纹图, 分数傅里叶变换, 三角形收缩法

Abstract：Aiming at a slower rate when the fractional Fourier transform is used for the estimation of Newton rings parameters, the method based on the triangle shrinkage of the improved fractional Fourier transform is proposed by analyzing the distribution law of the maximum value of the amplitude in the fractional domain of the Newton rings fringe images and the corresponding angle of rotation. The experimental results show that the method is feasible, and the processing time is less than 1s for the fringe images with an image size less than 640×640pixels. With the increase of the image size, the number of fringes contained in the fringe image increases, and the relative error of the estimated value of the radius of curvature decreases. The processing time is still able to meet the practical needs of engineering. When processing the image of 1080×1080pixels, the relative error of the estimated value is 0.001%, and the processing time is 3.31s. The method estimates the 720×720pixels Gaussian noise-damaged Newton ring interferometric fringe image in an average time of 1.28s, which is about 1/700 of the traditional fractional Fourier transform time.

Key words： optical metrology lens curvature radius Newton rings fringe patterns fractional Fourier transform triangle shrinkage method

收稿日期: 2023-05-19 发布日期: 2023-12-27

PACS:

TB96

基金资助:(2020YFC1511705);国家自然科学基金（62171025）;北京市属高等学校高水平科研创新团队建设支持计划(BPHR20220123);北京市自然科学基金 (4232044);北京理工大学实验室研究项目(2021BITSYA18);北京信息科技大学高教研究项目(2022GJYB16)

通讯作者: 鲁溟峰（1978-）,男,北京人,北京理工大学副教授,硕士生导师,博士,主要从事光学测量、电子测量中的现代信号/数据处理、人工智能安全问题和智能监控等方面的研究。Email:lumingfeng@bit.edu.cn E-mail: lumingfeng@bit.edu.cn

作者简介: 武进敏（1989-）,女,山西朔州人,北京信息科技大学讲师,博士,主要研究方向为分数域信号与信息处理,光学干涉测量,检测技术与自动化装置等。Email:wujinmin@bistu.edu.cn

引用本文:

武进敏,姜盛,鲁溟峰,沈德明,范军芳,李亚峰,张峰,陶然. 基于三角形收缩法改进的分数傅里叶变换估计牛顿环参数[J]. 计量学报, 2023, 44(12): 1783-1790.
WU Jin-min,JIANG Sheng,LU Ming-feng,SHEN De-ming,FAN Jun-fang,LI Ya-feng,ZHANG Feng,TAO Ran. Parameters Estimation of Newton Rings Based on Fractional Fourier Transform Modified by Triangle Shrinkage Method. Acta Metrologica Sinica, 2023, 44(12): 1783-1790.

链接本文:

http://jlxb.china-csm.org:81/Jwk_jlxb/CN/10.3969/j.issn.1000-1158.2023.12.01 或 http://jlxb.china-csm.org:81/Jwk_jlxb/CN/Y2023/V44/I12/1783

［6］	吴文贤, 江飞虹. 干涉条纹图相位特征提取的方法研究［J］. 光电技术应用, 2018, 33 (4): 45-48.
［8］	刘育彰, 高宏堂, 程银宝, 等. 基于单稳频激光的端面距离微尺寸测量方法［J］. 计量学报, 2021, 42 (2): 144-149.
［15］	王然, 孙佳欣, 吴江红, 等. 复合型干涉光源在牛顿环实验中的应用［J］.物理实验, 2019, 39 (8): 50-52.
［7］	杨荣岩, 赵洁, 王大勇, 等. 干涉角度显微测量提高光子相关法空气声声压测量精度研究［J］. 计量学报, 2022, 43 (7): 927-933.
［14］	花晓彬, 花世群. 一种牛顿环干涉实验数据处理新方法［J］. 大学物理, 2021, 40 (7): 35-37.
	Shen L, Zhou N J, Dai W H, et al. Development of an equal-thickness interference experimental device based on the optical amplification method ［J］. Physics and Engineering, 2021, 31 (S1): 14-18.
［10］	Ge Z, Kobayashi F. High-precision measurement of a fiber connector end face by use of a Mirau interferometer ［J］. Applied Optics, 2006, 45 (23): 5832-5839.
	Su Y, Fan Q, Wang Y F, et al. High-accuracy Fourier transform analysis of the interference fringes ［J］. Journal of Photonics, 2015, 44 (11): 100-105.
	Guo Y, Chen X T, Mao Q, et al. New algorithm for phase extraction of single interference pattern ［J］. Laser & Infrared, 2015, 45 (1): 94-98.
［2］	李天昊, 何勇, 韩志刚, 等. 基于扩展宽带光双光栅干涉的屈光度测量研究［J］. 计量学报, 2023, 44 (7): 1046-1051.
	Yang R Y, Zhao J, Wang D Y, et al. Research on improving the accuracy of measuring acoustic pressure by photon correlation spectroscopy based on interference angle microscopy ［J］. Acta Metrologica Sinica, 2022, 43 (7): 927-933.
	Hua X B, Hua S Q. A new method for data processing of Newton ring interference experiment ［J］. University Physics, 2021, 40 (7): 35-37.
［19］	Dobroiu A, Alexandrescu A, Apostol D, et al. Centering and profiling algorithm for processing Newtonss rings fringe patterns ［J］. Optical Engineering, 2000, 39 (12): 3201-3206.
［20］	Lu M F, Zhang F, Tao R, et al. Parameter estimation of optical fringes with quadratic phase using the fractional Fourier transform ［J］. Optics and Lasers in Engineering, 2015, 74: 1-16.
［21］	Liang X, Xing R Q, Shen D M, et al. Concise fractional Fourier transform based on a nonuniform order searching method for estimating physical parameters from Newtons rings ［J］. Applied Optics, 2022, 61 (15): 4478-4485.
［1］	张超超, 王建波, 殷聪, 等. 基于光学锁相环的高稳定度激光稳频方法研究［J］. 计量学报, 2022, 43 (9): 1154-1160.
	Wu W X, Jiang F H. Methods for phase feature extraction of interference pattern ［J］. Application of Photoelectric Technology, 2018, 33 (4): 45-48.
	Lu M F, Wu X M, Yang W M, et al. Newton ring experiment based on signal processing and deep learning ［J］. Physical Experiment, 2022, 42 (4): 17-24.
	Guo Y, Mao Q, Chen X T, et al. Research on the fast-window Fourier filtering method for interference fringes ［J］. Journal of Optics, 2014, 34 (6): 159-163.
	Zhang C C, Wang J B, Yin C, et al. Research on high stability laser frequency stabilization method based on optical phase-locked loop ［J］. Acta Metrologica Sinica, 2022, 43 (9): 1154-1160.
	Li T H, He Y, Han Z G, et al. Research on diopter measurement based on extended broadband optical double grating interference ［J］. Acta Metrologica Sinica, 2023, 44 (7): 1046-1051.
［3］	Rajshekhar G, Rastogi P. Fringe analysis: premise and perspectives ［J］. Optics and Lasers in Engineering, 2012, 8 (50): 3-10.
	Xu D H, Tang X H, Fang G M, et al. Calibration method of optical axis parallelism based on interference stripes ［J］. Journal of Optics, 2020, 40 (17): 129-136.
	Liu Y Z, Gao H T, Cheng Y B, et al. Measurement of micro transverse spacing using single frequency-stabilized laser ［J］. Acta Metrologica Sinica, 2021, 42 (2): 144-149.
［12］	Yang Z, Dou J, Du J, et al. Large radius of curvature measurement based on the evaluation of interferogram-quality metric in non-null interferometry ［J］. Optics Communications, 2018, 410: 756-762.
［13］	鲁溟峰, 武进敏, 杨文明, 等. 基于信号处理和深度学习的牛顿环实验［J］. 物理实验, 2022, 42 (4): 17-24.
	Wang R, Sun J X, Wu J H, et al. Application of a composite interference light source in Newtonvs ring experiments ［J］. Physical Experiment, 2019, 39 (8): 50-52.
［18］	郭媛, 毛琦, 陈小天, 等. 干涉条纹快速加窗傅里叶滤波方法的研究［J］. 光学学报, 2014, 34 (6): 159-163.
［4］	沈浪, 周南建, 戴闻浩, 等. 基于光学放大法的等厚干涉实验装置研制［J］. 物理与工程, 2021, 31 (S1): 14-18.
［5］	徐丹慧, 唐霞辉, 方国明, 等. 基于干涉条纹的光轴平行性校准方法［J］. 光学学报, 2020, 40 (17): 129-136.
［9］	Li Y, Qu S, Qu J, et al. Center searching and tracking of circular interference fringes for precision measurement ［J］. Optical Engineering, 2012, 51 (2): 160-168.
［11］	Yang Z, Wang K, Cheng J, et al. Large radius of curvature measurement based on virtual quadratic Newton rings phase-shifting moiré-fringes measurement method in a nonnull interferometer ［J］. Applied Optics, 2016, 55 (17): 4769-4775.
［16］	粟银, 范琦, 王云飞, 等. 干涉条纹的高准确度傅里叶变换分析［J］. 光子学报, 2015, 44 (11): 100-105.
［17］	郭媛, 陈小天, 毛琦, 等. 单幅干涉条纹图相位提取新算法［J］. 激光与红外, 2015, 45 (1): 94-98.