可见光波段多路合束及闭环校正技术研究 -

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可见光波段多路合束及闭环校正技术研究

doi:10.37188/CO.2023-0077

1.
中国科学院长春光学精密机械与物理研究所, 吉林长春 130033
2.
中航凯迈(上海)红外科技有限公司, 上海 201306)

基金项目:吉林省科技发展计划资助项目（No. 20180520185JH）

详细信息

作者简介:
徐新行（1983—）男，河南周口人，博士，副研究员，2015年于中国科学院大学长春光机所获得博士学位，主要从事光束控制、光电转台及光电编码器的研究工作。E-mail：xxh123321xxh@163.com
李高生（1996—），男，河南项城人，硕士研究生，2020年于上海工程技术大学获得学士学位,主要从事光电对抗相关光学仪器的研究。E-mail：ligaos182@163.com

中图分类号:TP394.1
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出版历程
- 网络出版日期:2023-09-14

Multi-channel laser beam combining and closed-loop correction technology in visible light band

1.
Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, ChangChun 130033, China
2.
AVIC CAMA(ShangHai)Infrared technology Co.Ltd, ShangHai 201306, China

Funds:Supported by Science and Technology Development Plan Funded Projects of Jilin Province (No. 20180520185JH)

More Information

Corresponding author:ligaos182@163.com

摘要

摘要:
为了实现可见光波段多路不同波长的周期性闭环校正，设计了一种具有光束指向和位置偏差独立监测与调节的合束系统。首先，根据系统的应用需求，提出了合束系统的设计指标与整体合束方案。然后，在合束方案的基础上，建立了合束系统的光束控制模型，并通过数值仿真得到了合束系统光束控制的解算方法。闭环合束系统通过光束指向和位置监测装置分别实现合束指向偏差与位置偏差的独立监测，并根据监测结果进行光束调节装置控制量的解算；进而通过两维摆镜和一维平移台分别实现光束指向和位置偏差的独立高效调节。最后，采用两路不同波长的束，配合光束监测与调节装置，搭建了闭环合束模拟实验平台，对周期性闭环合束系统的合束效果进行了验证。实验结果表明：在长时间的工作过程中，两路均实现了与基准光路的精密合束，合束指向精度优于±7 μrad，位置精度优于±0.84 mm。本研究所组建的合束系统不仅具有合束精度高、校正速度快、光路扩展性强的优势，而且可实现束的周期性闭环校正，能够有效保证合束的长期工作稳定性。
- 合束/
- 光束监测/
- 光束控制/
- 指向偏差/
- 位置偏差
Abstract:
To achieve periodic closed-loop correction of multiple visible wavelength lasers, a laser beam combining system is being designed. This system involves independent monitoring and adjusting of beam pointing and position deviation. First, according to the application requirements of the system, the design indexes of the beam combining system and the overall beam combining scheme are proposed. Then, based on the overall beam combining scheme, we establish the beam control model for the beam combining system. Through numerical simulation experiments, we obtain the solution method for beam control of the beam combining system. The closed-loop beam combining system enables independent monitoring of the unit beam’s pointing and position deviation through the respective beam pointing and position monitoring device. The monitoring results are then used to calculate the control quantity of the beam adjusting device. The independent and efficient adjustment of beam pointing, and position deviation is achieved using a two-dimensional swing mirror and a one-dimensional platform, respectively. Finally, a closed-loop beam combining simulation experimental system with beam monitoring and adjustment device was built using tow laser beams of different wavelengths. The periodic closed-loop beam combining system was verified to have an effective beam combing effect. The experimental results demonstrate that over an extended operational period, both lasers achieve precise beam combining with the reference optical path. Furthermore, the beam combining pointing accuracy is better than ±7 μrad , and the positioning accuracy is better than ±0.84 mm. The laser beam combining system developed in this study boast high beam combining accuracy, a fast correction speed, and excellent augmentability for multiple laser beams. Besides, it can accomplish periodic closed-loop beam combining of laser beams, ensuring long-term working stability of the combined laser.
- laser beam combining/
- beam monitoring/
- beam control/
- beam direction deviation/
- beam positional deviation

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图 1 合束及闭环校正系统整体布局

Figure 1.Overall layout of laser beam combining and closed-loop correction system

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图 2两维摆镜光束指向调节示意图

Figure 2.Schematic diagram of beam pointing adjustment by two-dimensional oscillating mirror

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图 3光束指向调节示意图

Figure 3.Schematic diagram of beam pointing adjustment

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图 4光束位置调节原理示意图

Figure 4.Principle diagram of beam position adjustment

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图 5光束左右位置调节示意图

Figure 5.Schematic diagram of beam left and right position adjustment

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图 6左右位置调节装置实物

Figure 6.Physical map of left-right adjusting device

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图 7光束高低位置调节示意图

Figure 7.Schematic diagram of beam high and low position adjustment

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图 8高低位置调节装置原理和实物

Figure 8.Principle and physical map of beam high-low adjusting device

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图 9合束系统模拟实验

Figure 9.Simulation experiment of beam combining system

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图 10光束1周期性闭环合束指向偏差实时监测数据

Figure 10.Real-time direction deviation of corrected beam-1 by cycle closed-loop combining

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图 11光束1周期性闭环合束位置偏差实时监测数据

Figure 11.Real-time monitoring data of beam 1 periodic closed-loop beam combining position deviation

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图 12光束2周期性闭环合束指向偏差实时监测数据

Figure 12.Real-time monitoring data of beam 2 periodic closed-loop beam combining pointing deviation

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图 13光束2周期性闭环合束位置偏差实时监测数据

Figure 13.Real-time monitoring data of beam 2 periodic closed-loop beam combining position deviation

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图 14监测装置监测精度实验检测

Figure 14.Monitoring device monitoring accuracy test

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图 15合束系统光束调节部分的光路图

Figure 15.Optical path diagram of the beam adjustment section of the beam combining system

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表 1 合束系统设计要求

Table 1.Design requirements for beam combining system

Items	Requirement
Wavelength	400～900 nm
Aperture	≥Φ40 mm
Precision of direction	±20 μrad
Precision of positional	±1 mm
Direction correction range	θx≥±600 μrad; θy≥±600 μrad
Positional correction range	≥±7.5 mm

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表 2指向调节仿真实验数据(单位：μrad)

Table 2.Pointing adjustment simulation experiment data

方位偏差δ_y	俯仰偏差δ_x	方位控制量α	俯仰控制量β	δ_y与2α 差值	δ_x与$ \sqrt{2}\beta $ 差值
−1500	0	−749.886	0	−0.228	0
−1000	0	−499.992	0	−0.016	0
−500	0	−249.959	0	−0.082	0
500	0	249.958	0	0.084	0
1000	0	499.922	0	0.156	0
1500	0	749.886	0	0.228	0
0	−1500	0	−1060.652	0	−0.012
0	−1000	0	−707.099	0	−0.011
0	−500	0	−353.546	0	−0.010
0	0	0	0	0	0
0	500	0	353.546	0	0.010
0	1000	0	707.099	0	0.011
0	1500	0	1060.652	0	0.011
250	250	124.982	176.790	0.036	−0.019
500	500	249.930	353.630	0.140	−0.108
1000	1000	499.740	707.450	0.520	−0.485

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表 3左右位置调节仿真实验数据

Table 3.Left and right position adjustment the simulation experiment data

左右控制量(mm)	0.1	1	2	3	4	6	8	10
坐标变化量$ \Delta x $(μm)	0.224	2.249	3.699	5.249	6.598	7.499	8.899	10.512
坐标变化量$ \Delta y $(mm)	0.099	0.999	1.997	2.995	3.994	5.991	7.988	9.985

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表 4高低位置调节仿真实验数据

Table 4.Simulated experimental data for high and low position adjustment

左右控制量(mm)	0.1	1	2	3	4	>−	8	10
坐标变化量$ \Delta x $(mm)	0.100	1.002	2.002	3.004	4.005	>−.009	8.011	10.017
坐标变化量$ \Delta y $(μm)	-0.300	-3.124	->−.125	-9.253	-9.527	-10.83>−	-11.259	-12.452

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