矩形大口径光束质量评价光学系统设计 -

姓名
邮箱
手机号码
标题
留言内容
验证码

矩形大口径光束质量评价光学系统设计

doi:10.37188/CO.2021-0130

1.
长春理工大学光电工程学院，吉林长春 130022
2.
中国人民解放军63867部队，吉林白城 137000
3.
吉林江机特种工业有限公司八分厂，吉林吉林 132021

基金项目:吉林省科技发展计划项目(No. 20200401054GX)；长春理工大学青年基金(No. XQNJJ-2019-01)；吉林省教育厅“十三五”科学技术项目(No. JJKH20200756KJ)；高等学校学科创新引智计划(No. D21009)

详细信息

作者简介:
潘国涛(1998—)，男，天津人，硕士研究生，2020年于长春理工大学光电工程学院获得学士学位，研究方向包括光学设计，光机结构设计，误差分析，光电检测技术。E-mail:851993727@qq.com
闫钰锋（1978—），男，吉林长春人，工学博士，教授，博士生导师，2010于长春理工大学测试计量技术与仪器专业获得博士学位，研究方向包括：光机结构设计，光电检测技术，仪器精度分析，光学测量，主要从事光电仪器设计、精密光电测量技术等。E-mail:yanyufeng@cust.edu.cn

中图分类号:TG502.33;TH74
计量
- 文章访问数:863
- HTML全文浏览量:441
- PDF下载量:186
- 被引次数:0
出版历程
- 收稿日期:2021-06-26
- 修回日期:2021-07-26
- 网络出版日期:2021-10-22
- 刊出日期:2022-03-21

Design of optical system for quality evaluation of a large rectangular aperture laser beam

1.
School of Opto-Electronic Engineering, Changchun University of Science and Technology, Changchun 130022, China
2.
63867 unit of the Chinese People's Liberation Army, Baicheng 137000, China
3.
Jilin Jiangji Special Industry Co., LTD. No. 8 branch, Jilin 132021, China

Funds:Supported by Science and Technology Development Project of Jilin Province (No. 20200401054GX); Youth Fund of Changchun University of Science and Technology (No. XQNJJ-2019-01); “The Thirteenth Five-Year Plan” Science and Technology Project of the Education Department of Jilin Province (No. JJKH20200756KJ); The 111 Project of China (No. D21009)

More Information

Corresponding author:yanyufeng@cust.edu.cn

摘要

摘要:自适应光学校正技术可有效提升固体板条器的光束质量，但随着器输出功率的提升，输出光束口径逐渐增加，系统体积逐渐增大，自适应光学校正系统的设计难度也增加了。因此，在满足自适应光学校正系统中共轭探测等需求的前提下，统筹优化系统的尺寸参数，同时实现波前相位、光束质量评估等多参数的检测具有一定的研究意义。本文在系统整体尺寸为350 mm×180 mm×220 mm（长×宽×高）的条件下，研究实现了板条器输出160 mm×120 mm矩形光束多参数的检测。针对探测口径大、筒长限制、长出瞳距等技术要求，首先，利用双高斯初始结构的消像差特点，结合非球面技术，采用大倍率光束压缩后分光探测的设计方案，实现多参数的同时探测。其次，基于摄远成像和共轭成像等原理，确定系统初始参数。接着，建立仿真模型分析系统的成像质量和公差，为实验的搭建提供依据。最后，搭建实验平台验证设计结果。结果表明：所设计系统可在满足物像共轭、尺寸约束等条件下，实现对大口径矩形光束的共轭波前探测、光强均匀度检测和光束质量评估。实验测得被测光束 β因子为1.24倍衍射极限，均匀度为73.8%，满足技术指标要求。
- 板条器/
- 自适应光学校正/
- 矩形光束/
- 共轭波前探测/
- 光束质量评估
Abstract:The adaptive optical correction technology can effectively improve the beam quality of solid slab lasers, but with the increase of laser output power, the output beam aperture and the system volume increase gradually, which make the design of adaptive optical correction system more difficult. Therefore, under the premise of meeting the requirements of conjugate detection in the adaptive optical correction system, it is of certain research significance to optimize the size parameters of the detection system as a whole, and realize the detection of multiple parameters such as wavefront phase and beam quality evaluation. In this paper, we realized the multi-parameter detection of 160 mm×120 mm rectangular beam emitted by slab laser under the condition that the overall size of the system is 350 mm×180 mm×220 mm (length × width × height). According to the technical requirements of large detection apertures, limitation of tube length and long exit pupil distance, firstly, the dual-Gaussian initial structure was used to eliminate the aberration. Combined with the aspheric surface technology, the design scheme of splitting detection after high-ratio beam compression was adopted to realize the simultaneous detection and evaluation of multiple parameters. Secondly, the initial parameters of the system were determined based on the principles of telephoto imaging and conjugate imaging. Thirdly, the simulation model of the detection system was established to analyze the imaging quality and the tolerance of the system, which were implemented to provide the basis for the construction of the experiment. Finally, the experiments were carried out to verify the design results. Results indicate that the conjugate wavefront detection, light intensity uniformity detection and beam quality evaluation of 160 mm × 120 mm rectangular beam can be realized under the conditions of the object-image conjugation and size constraint conditions. In the experiment, the βfactor of the measured beam is 1.24 times the diffraction limit, and the uniformity is 73.8 %, which meet the technical requirements.
- slab laser/
- adaptive optical correction/
- rectangular beam/
- conjugate wavefront detection/
- beam quality evaluation

HTML全文

图 1矩形大口径光束质量评价系统示意图

Figure 1.Schematic diagram of evaluation system of the large rectangular aperture laser beam quality

下载: 全尺寸图片幻灯片

图 2系统2D结构图

Figure 2.Schematic diagram of system (2D structure)

下载: 全尺寸图片幻灯片

图 3主缩束系统的光学结构示意图

Figure 3.Schematic diagram of optical structure of main beam compression system

下载: 全尺寸图片幻灯片

图 4非球面子午曲率和弧矢曲率曲线图

Figure 4.Curves of tangential and sagittal curvature of aspheric surfaces

下载: 全尺寸图片幻灯片

图 5主缩束系统像质评价

Figure 5.Image quality evaluation results of the main beam compression system

下载: 全尺寸图片幻灯片

图 6光束质量探测子系统波像差

Figure 6.Wavefront aberration of the beam quality detection subsystem

下载: 全尺寸图片幻灯片

图 7光束质量探测子系统2D图

Figure 7.2D diagram of the beam quality detection subsystem

下载: 全尺寸图片幻灯片

图 8光束质量探测系统2D图

Figure 8.2D diagram of the beam quality detection system

下载: 全尺寸图片幻灯片

图 9光束质量探测系统像质评价

Figure 9.Evaluation results of the image quality of the beam quality detection system

下载: 全尺寸图片幻灯片

图 10光束均匀性探测子系统波像差

Figure 10.Wavefront aberration of the beam uniformity detection subsystem

下载: 全尺寸图片幻灯片

图 11光束均匀性探测子系统2D图

Figure 11.2D diagram of beam uniformity detection subsystem

下载: 全尺寸图片幻灯片

图 12光束均匀性探测系统加入理想透镜2D图

Figure 12.2D diagram of the beam uniformity detection system with an ideal lens

下载: 全尺寸图片幻灯片

图 13光束均匀性探测系统像质分析

Figure 13.Evaluation of the image quality of the beam uniformity detection system

下载: 全尺寸图片幻灯片

图 14矩形大口径近红外光束质量评价系统

Figure 14.Beam quality evaluation system of the large rectangular aperture near-infrared laser

下载: 全尺寸图片幻灯片

图 15哈特曼传感器光斑阵列图像

Figure 15.Spot array image of Hartmann sensor

下载: 全尺寸图片幻灯片

图 16光束质量的探测图像

Figure 16.Detection image of the beam quality

下载: 全尺寸图片幻灯片

图 17光束均匀性的探测图像

Figure 17.Detection image of the beam uniformity

下载: 全尺寸图片幻灯片

表 1 光束质量评价系统的技术指标

Table 1.The technical specifications of the laser beam quality evaluation system

参数	数值
主缩束装置倍率	11×
主缩束系统通光口径	160 mm×120 mm
视场	±3′
波长	(1064±0.3) nm
主缩束入瞳位置	500 mm
主缩束出瞳位置	≥40 mm
主缩束系统筒长	≤320 mm
主缩束系统配合光束质量探测光学系统EFFL	5500 mm
光束均匀性探测光学系统缩束倍率	4.5×
光束质量β因子	≤1.3×DL
系统整体尺寸	350 mm×180 mm×220 mm (长×宽×高)

下载: 导出CSV

表 2主缩束系统透镜数据

Table 2.Lens data of the main beam compression system

Type	Radius	Thickness	Glass
Even Asphere	440.000	22.893	H-ZLAF52A
Standard	−2924.268	1.000	−
Standard	231.431	28.018	H-ZLAF55D
Standard	925.079	56.403	−
Standard	394.602	10.800	H-ZF73
Standard	64.282	30.000	H-ZLAF68C
Standard	191.455	154.885	−
Standard	−13.435	2.009	H-ZLAF55D
Standard	−1053.154	4.077	−
Standard	−20.488	4.037	H-ZLAF53B
Standard	−13.485	0.811	−
Standard	311.182	4.496	H-ZLAF53B
Standard	−25.212	41.405	−

下载: 导出CSV

表 3光束质量探测子系统透镜数据

Table 3.Lens data of beam quality detection subsystem

Radius	Thickness	Glass
36.523	7.047	H-ZLA
415.691	20.267	—
−38.384	8.628	H-ZF88
155.064	38.737	—
−124.904	5.558	H-ZLA
12.285	45.272	—

下载: 导出CSV

表 4光束质量探测系统的公差数据

Table 4.Tolerance data of beam quality detection system

No.	Radius	Thickness/mm	Decenter (X/Y)/mm	Tilt (X/Y)/(′)	Index	Abbe.
Len1	±0.02	±0.025	±0.01	±0.7	±0.0005	±0.08%
Len2	±0.02	±0.025	±0.01	±0.6	±0.0005	±0.08%
Len3	±0.02	±0.025	±0.01	±0.7	±0.0005	±0.08%
Len4	±0.03	±0.025	±0.03	±0.1	±0.002	±0.2%
Len5	±0.03	±0.0375	±0.01	±1.5	±0.002	±0.2%
Len6	±0.03	±0.0375	±0.02	±1.5	±0.002	±0.2%
Len7	±0.03	±0.0375	±0.02	±2	±0.002	±0.3%
Len8	±0.03	±0.0375	±0.02	±2	±0.002	±0.3%
Len9	±0.03	±0.0375	±0.02	±2	±0.002	±0.3%

下载: 导出CSV

表 5光束质量探测系统的1000次蒙特卡罗分析结果

Table 5.1000 Monte Carlo statistical analysis results of the beam quality detection system

Percentage of Monte Carlo/%	RMS Wavefront
98	0.2715
90	0.1871
80	0.1586
50	0.1109

下载: 导出CSV

表 6光束均匀性探测子系统透镜数据

Table 6.Lens data of the beam uniformity detection subsystem

Radius	Thickness	Glass
66.752	3.964	H-ZF7LA
Infinity	0.800	−
−154.456	6.000	H-ZF7LAGT
−340.621	117.358	−
−5.693	3.326	H-K9L
−7.277	1.000	−
−23.127	3.893	H-ZLAF68N
−10.385	3.000	−
−6.247	3.950	H-K9L
−6.247	26.932	−

下载: 导出CSV

表 7光束均匀性探测系统公差数据

Table 7.Tolerance data of the beam uniformity detection system

No.	Radius	Thickness	Decenter (X/Y)/mm	Tilt (X/Y)/(′)	Index	Abbe.
Len1	±0.02	±0.025 mm	±0.01	±0.8	±0.0005	±0.08%
Len2	±0.02	±0.025 mm	±0.01	±0.6	±0.0005	±0.08%
Len3	±0.02	±0.025 mm	±0.01	±0.8	±0.0005	±0.08%
Len4	±0.03	±0.035 mm	±0.03	±1.5	±0.0005	±0.2%
Len5	±0.03	±0.035 mm	±0.01	±1.5	±0.003	±0.2%
Len6	±0.03	±0.035 mm	±0.03	±1.5	±0.003	±0.2%
Len7	±0.03	±0.035 mm	±0.03	±3.0	±0.001	±0.2%
Len8	±0.03	±0.035 mm	±0.03	±3.0	±0.003	±0.2%
Len9	±0.03	±0.035 mm	±0.03	±3.0	±0.003	±0.2%
Len10	±0.03	±0.035 mm	±0.03	±3.0	±0.003	±0.2%
Len11	±0.03	±0.035 mm	±0.03	±3.0	±0.003	±0.2%

下载: 导出CSV

表 8光束均匀性探测系统1000次蒙特卡罗分析结果

Table 8.1000 Monte Carlo statistical analysis results of the beam uniformity detection system

Percentage of Monte Carlo	RMS Wavefront
98%	0.2403
90%	0.1874
80%	0.1625
50%	0.1189

下载: 导出CSV

参考文献 (19)

[1]	KOSSOWSKY R, JELINEK M, WALTER R F.High Power Lasers——Science and Engineering[M]. Dordrecht: Springer, 1996.
[2]	LIU B L, WANG ZH CH, YANG F,et al. High brightness 556 nm laser by frequency doubling of a 1112 nm Nd∶YAG laser[J].IEEE Photonics Technology Letters, 2014, 26(10): 969-972.doi:10.1109/LPT.2014.2309795
[3]	唐睿, 高子叶, 吴正茂, 等. 基于SESAM被动调Q的二极管泵浦Yb∶CaYAlO₄脉冲器[J]. 中国光学,2019,12(1):167-178.doi:10.3788/co.20191201.0167 TANG R, GAO Z Y, WU ZH M,et al. Output characteristics of diode-pumped passivelyQ-switched Yb∶CaYAlO₄pulsed laser based on a SESAM[J].Chinese Optics, 2019, 12(1): 167-178. (in Chinese)doi:10.3788/co.20191201.0167
[4]	刘学胜, 董剑, 徐爱东, 等. 双程放大740 mJ TEC冷却LD泵浦Nd∶YAG 器[J]. 发光学报,2018,39(7):991-996.doi:10.3788/fgxb20183907.0991 LIU X SH, DONG J, XU A D,et al. Two-pass amplifier 740 mJ diode-pumped Nd∶YAG laser with thermoelectric cooler[J].Chinese Journal of Luminescence, 2018, 39(7): 991-996. (in Chinese)doi:10.3788/fgxb20183907.0991
[5]	岱钦, 张善春, 杨帆, 等. 高光束质量高斯非稳腔固体器研究[J]. 中国光学,2019,12(3):559-566.doi:10.3788/co.20191203.0559 DAI Q, ZHANG SH CH, YANG F,et al. Research on the high beam quality of Gaussian unstable resonators in solid state lasers[J].Chinese Optics, 2019, 12(3): 559-566. (in Chinese)doi:10.3788/co.20191203.0559
[6]	YU X, DONG L ZH, LAI B H,et al. Automatic low-order aberration correction based on geometrical optics for slab lasers[J].Applied Optics, 2017, 56(6): 1730-1739.doi:10.1364/AO.56.001730
[7]	FAN ZH W, QIU J S, KANG ZH J,et al. High beam quality 5 J, 200 Hz Nd: YAG laser system[J].Light:Science&Applications, 2017, 6(3): e17004.
[8]	于信. 板条低阶像差自动校正技术研究[D]. 成都: 电子科技大学, 2018: 1-14. YU X.Research on automatic low-order aberration correction of slab laser[D]. Chengdu: University of Electronic Science and Technology of China, 2018: 1-14. (in Chinese)
[9]	相里微. 大功率波前测量系统设计[D]. 西安: 西安电子科技大学, 2012: 21-24. XIANG L W.Design of high-power laser wavefront measurement system[D]. Xi’an: Xidian University, 2012: 21-24. (in Chinese)
[10]	张成栋. 光束质量诊断与测量研究[D]. 长沙: 国防科学技术大学, 2017: 30-38. ZHANG CH D.Diagnosis and measurement of laser beam quality[D]. Changsha: National University of Defense Technology, 2017: 30-38. (in Chinese)
[11]	张禹, 杨忠明, 刘兆军, 等. 大口径多光谱通道波前测量系统设计[J]. 红外与工程,2020,49(8):20190559.doi:10.3788/IRLA20190559 ZHANG Y, YANG ZH M, LIU ZH J,et al. Design of large aperture multi-spectra channel wavefront measurement system[J].Infrared and Laser Engineering, 2020, 49(8): 20190559. (in Chinese)doi:10.3788/IRLA20190559
[12]	张禹. 共轴式大口径多光谱通道波前测量系统的研究[D]. 济南: 山东大学, 2020: 10-21, 41-43. ZHANG Y.Research on coaxial large aperture multi-spectra channel wavefront measurement system[D]. Ji’nan: Shandong University, 2020: 10-21, 41-43. (in Chinese)
[13]	FOURMAUX S, PAYEUR S, ALEXANDROV A,et al. Laser beam wavefront correction for ultra high intensities with the 200 TW laser system at the advanced laser light source[J].Optics Express, 2008, 16(16): 11987-11994.doi:10.1364/OE.16.011987
[14]	LU H H, LIN CH Y, LU T C,et al. 150 m/280 Gbps WDM/SDM FSO link based on OEO-based BLS and afocal telescopes[J].Optics Letters, 2016, 41(12): 2835-2838.doi:10.1364/OL.41.002835
[15]	郁道银, 谈恒英. 工程光学[M]. 3版. 北京: 机械工业出版社, 2011. YU D Y, TAN H Y.Engineering Optics[M]. 3rd ed. Beijing: China Machine Press, 2011. (in Chinese)
[16]	傅瑞斯. 摄远物镜初步设计的一种方法[J]. 云光技术,2002,34(2):21-24. FU R S. A method for primary design of telephoto objective[J].Yunguang Technology, 2002, 34(2): 21-24. (in Chinese)
[17]	CHEN ZH ZH, XU Y T, GUO Y D,et al. 8.2 kW high beam quality quasi-continuous-wave face-pumped Nd: YAG slab amplifier[J].Applied Optics, 2015, 54(16): 5011-5015.doi:10.1364/AO.54.005011
[18]	REDMOND S, MCNAUGHT S, ZAMEL J,et al. . 15 kW near-diffraction-limited single-frequency Nd: YAG laser[C].2007 Conference on Lasers and Electro-Optics (CLEO),IEEE, 2005: 1-2.
[19]	林星辰, 朱洪波, 王彪, 等. 均匀光强分布的5 kW半导体硬化光源研制[J]. 光学精密工程,2017,25(5):1178-1184.doi:10.3788/OPE.20172505.1178 LIN X CH, ZHU H B, WANG B,et al. Development of 5 kW diode laser hardening source with homogenized intensity distribution[J].Optics and Precision Engineering, 2017, 25(5): 1178-1184. (in Chinese)doi:10.3788/OPE.20172505.1178