[1]高华兴.基于参数辨识的半导体激光器温度自动控制[J].机械与电子,2022,(11):55-60.
 GAO Huaxing.Automatic Temperature Control of Semiconductor Laser Based on Parameter Identification[J].Machinery & Electronics,2022,(11):55-60.
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基于参数辨识的半导体激光器温度自动控制()
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《机械与电子》[ISSN:1001-2257/CN:52-1052/TH]

卷:
期数:
2022年11期
页码:
55-60
栏目:
自动控制与检测
出版日期:
2022-11-25

文章信息/Info

Title:
Automatic Temperature Control of Semiconductor Laser Based on Parameter Identification
文章编号:
1001-2257 ( 2022 ) 11-0055-06
作者:
高华兴
中国空间技术研究院,北京 100094
Author(s):
GAO Huaxing
( China Academy of Space Technology , Beijing 100094 , China )
关键词:
参数辨识半导体激光器温度自动控制一阶纯滞后热传递性预估量
Keywords:
parameter identification semiconductor laser automatic temperature control first order pure delay heat transfer forecast
分类号:
TN248.4
文献标志码:
A
摘要:
以保证半导体激光器的安全稳定运行为目标,提出基于参数辨识的半导体激光器温度自动控制方法。通过分析温度对半导体激光器的影响及温度控制原理,设计半导体激光器温度控制系统,在该系统支持下利用半导体激光器温度控制数学模型描述其一阶纯滞后性,根据半导体激光器的热传递性获取半导体激光器的离散运行数据,建立半导体激光器参数辨识模型,确定其最佳预估量,并将其输入到 PID 中,利用遗传算法对 PID 参数进行实时调节,以满足半导体激光器温度变化量对 PID 参数的自整定需求,实现半导体激光器温度自动控制的目标。实验结果表明,该方法可实现半导体激光器温度的快速控制,能够快速达到预期温度,温度波动范围在 0.02 ℃ 以内,温度控制后的半导体激光器发光光谱波形平稳,能够保证半导体激光器的安全稳定运行。
Abstract:
In order to ensure the safe and stable operation of semiconductor laser , an automatic temperature control method of semiconductor laser based on parameter identification is proposed.By analyzing the influence of temperature on semiconductor laser and the principle of temperature control , the semiconductor laser temperature control system is designed.With the support of the system , the first-order pure hysteresis is described by using the mathematical model of semiconductor laser temperature control , the discrete operation data of semiconductor laser is obtained according to the heat transfer of semiconductor laser , and the parameter identification model of semiconductor laser is established.The optimal estimation is determined , and the PID parameters are input into THE PID, and the genetic algorithm is used to adjust the PID parameters in real time , so as to meet the self-tuning demand of the temperature change of semiconductor laser and realize the goal of automatic temperature control of semiconductor laser.The experimental results show that this method can realize the rapid control of the temperature of the semiconductor laser , can quickly reach the expected temperature , the temperature fluctuation range is within 0.02℃ , the luminescence spectrum waveform of the semiconductor laser after temperature control is stable , which can ensure the safe and stable operation of the semiconductor laser.

参考文献/References:

[ 1 ] 杨芳权,江渝川 . 基于遗传算法的半导体激光器温度控制系统[ J ] . 沈阳工业大学学报, 2019 , 41 ( 4 ): 445-450.

[ 2 ] 何永勃,杨伟,范广永,等 . 基于速率方程的半导体激光器温度特性研究[ J ] . 应用激光, 2019 , 39 ( 5 ): 880-885.
[ 3 ] 杨鹏,胡业荣,王贵山 . 温度对半导体激光器退化的影响[ J ] . 国防科技大学学报, 2020 , 42 ( 1 ): 45-50.
[ 4 ] 张安迪,张艳荣,李涛 . 论域可变的模糊 PID 控制在半导体激光器温度控制系统中的应 用 [ J ] . 光学 学报,2021 , 41 ( 12 ): 153-161.
[ 5 ] 程前,邓华秋 . 半导体激光器驱动电路及温控系统设计[ J ] . 电子器件, 2019 , 42 ( 5 ): 1185-1189.
[ 6 ] 李良,何瑞东,路艳巧,等 . 基于快速参数辨识的感应电机转子温度在线评估方法[ J ] . 电机与控制应用, 2020 ,47 ( 3 ): 51-56.
[ 7 ] 缪存孝,邢国柱,刘建丰,等 . 高精度激光器电流驱动与交流温控系统设计[ J ] . 红外与激光工程, 2019 , 48 ( 9 ):97-104.
[ 8 ] 崔屹峰,李珍国,贾清泉,等 . 基于参数辨识与状态估计的温控负荷响应能力动态评估[ J ] . 电力系统自动化,2021 , 45 ( 1 ): 150-158.
[ 9 ] 何永勃,杨伟,范广永,等 . 基于速率方程的半导体激光器温度特性研究[ J ] . 应用激光, 2019 , 39 ( 5 ): 880-885.
[ 10 ] 齐艺超,陈伟,穆春元,等 . 基于粒子群自整定 PID 算法的激光器温度控制系统[ J ] . 激光技术, 2019 ,43( 5 ): 60-64.
[ 11 ] 范朋丹,赵天怡,历秀明,等 . 基于滞环继电控制的空调室温滞后模型参数辨识方法[ J ] . 暖通空调, 2019 ,49 ( 6 ): 109-115 , 82.
[ 12 ] 许乐,莫愿斌,卢彦越 . 基于改进海鸥优化算法的 PID 控制器参数优化[ J ] . 机床与液压, 2021 , 49 ( 16 ): 17-23.
[ 13 ] 郭威,杨帆,张剑焜 . 基于改进萤火虫算法的水电机组调速器 PID 参数优化[ J ] . 水力发电, 2019 , 45 ( 5 ):95-97 , 122.
[ 14 ] 孙泽旭,冯泽斌,周翊,等 . 基于强化学习的准分子激光器能量控制算法研究[ J ] . 中国激光, 2020 , 47 ( 9 ):1-10.
[ 15 ] 程鹏飞,彭雨,郝正航,等 . 热电联合供暖系统节能温度控制仿真[ J ] . 计算机仿真, 2018 , 35 ( 12 ): 160-165.

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备注/Memo

备注/Memo:
收稿日期: 2022-02-16
作者简介:高华兴 ( 1993- ),男,吉林长春人,硕士,工程师,研究方向为元器件质量保证。
更新日期/Last Update: 2022-12-13