激光技术, 2017, 41 (5): 734, 网络出版: 2017-09-21
基于DRV595的激光器恒温控制系统
Constant temperature control systems for semiconductor lasers based on DRV595
激光技术 温度控制 比例-积分-微分 半导体激光器 laser technique temperature control proportional-integral-differential DRV595 DRV595 semiconductor lasers
摘要
半导体激光器的输出波长和功率随温度变化而变化, 为了确保激光器工作性能, 须对其进行恒温控制。采用脉冲宽度调制功率驱动器DRV595驱动半导体制冷器的方法, 设计了一种双向大电流输出的高精度温度控制系统。在S域对系统进行了建模分析, 搭建经典比例-积分-微分控制器, 采用桥式采样电阻, 纯硬件电路实现, 结构简单, 省掉了数字控制器的复杂软件编写。在常温试验中取得了±0.03℃的控制精度, DRV595集成脉冲宽度调制和双向MOSFET, 输出电流最大为±4A。双向电流驱动半导体热电制冷器, 实现了无死区控制。结果表明, 脉冲宽度调制方式驱动和低输出级电阻大大降低了功率耗散。该系统工作稳定、功耗低、控制精度较高, 具有实用价值。
Abstract
The output wavelength and power of a semiconductor laser varied with the temperature. In order to ensure the performance of laser, constant temperature must be controlled. A high precision temperature control system of bidirectional high current output was designed by using pulse width modulation power driver DRV595 to drive the semiconductor cooler. In the S domain, the system was modeled and analyzed, and the classical proportional-integral-differential controller was built. The bridge type sampling resistor was adopted to realize the pure hardware circuit. The structure was simple, and the complex software of the digital controller was omitted. After normal temperature test, the control accuracy of ±0.03℃ was achieved. Pulse width modulation and bidirectional MOSFET were integrated in DRV595. The biggest output current was ±4A. No-dead-time control was realized by using bi-directional current to drive semiconductor cooler. The results show that pulse width modulation mode drive and low output stage resistor greatly reduce power dissipation. The system has the advantages of stable operation, low power consumption, high control accuracy and practical value.
郭凤玲, 徐广平, 黄宝库. 基于DRV595的激光器恒温控制系统[J]. 激光技术, 2017, 41(5): 734. GUO Fengling, XU Guangping, HUANG Baoku. Constant temperature control systems for semiconductor lasers based on DRV595[J]. Laser Technology, 2017, 41(5): 734.