星载激光器电源遥控遥测系统的设计与实现

宋博; 郑伟; 李明山; 冯文

doi:10.3788/IRLA201645.1020003

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星载激光器电源遥控遥测系统的设计与实现

宋博, 郑伟, 李明山, 冯文

文章导航 > 红外与激光工程 > 2016 > 45(10): 1020003-1020003(7)

宋博, 郑伟, 李明山, 冯文. 星载激光器电源遥控遥测系统的设计与实现[J]. 红外与激光工程, 2016, 45(10): 1020003-1020003(7). doi: 10.3788/IRLA201645.1020003

引用本文:

宋博, 郑伟, 李明山, 冯文. 星载激光器电源遥控遥测系统的设计与实现[J]. 红外与激光工程, 2016, 45(10): 1020003-1020003(7). doi: 10.3788/IRLA201645.1020003

Song Bo, Zheng Wei, Li Mingshan, Feng Wen. Design and realization of remote control and telemetry system of space-borne laser power supply[J]. Infrared and Laser Engineering, 2016, 45(10): 1020003-1020003(7). doi: 10.3788/IRLA201645.1020003

Citation:

Song Bo, Zheng Wei, Li Mingshan, Feng Wen. Design and realization of remote control and telemetry system of space-borne laser power supply[J]. Infrared and Laser Engineering, 2016, 45(10): 1020003-1020003(7). doi: 10.3788/IRLA201645.1020003

星载激光器电源遥控遥测系统的设计与实现

doi: 10.3788/IRLA201645.1020003

1.
北京空间机电研究所,北京 100094

详细信息

作者简介:
宋博(1987-),男,工程师,硕士,主要从事激光信息处理领域的研究。Email:bobosongmm@126.com

中图分类号: TN249

Design and realization of remote control and telemetry system of space-borne laser power supply

1.
Beijing Institute of Space Mechanics & Electricity,Beijing 100094

摘要: 星载激光测距通过发射机射出稳定度较高的脉冲激光实现对目标物的距离测量，其中涉及到激光器的设计与应用，尤以激光器电源功能和性能的实现最为重要。因此，实现星载激光器电源的外部控制和实时状态量的采集变得尤为重要。在基于FPGA技术基础上，利用AC/DC电源组件、遥控遥测组件和显示控制组件，设计出一种可以对激光器电源提供外时统信号、调Q信号、AD/DA控制信号，从而实现激光器电源状态量的实时遥测和LD电流信号、调Q信号的实时调节控制的系统，该系统可以设置激光重频和控制激光出射时刻，也可以实时显示激光脉冲次数和激光器电源的相关遥测量，同时对该系统涉及到的设计与实现进行了详细阐述，并对高可靠性的激光器电源遥控遥测系统性能和功能的进一步提升提出了改进方案。
- 激光器电源 /
- 遥控遥测系统 /
- FPGA
Abstract: Space-borne laser ranging could measure the distance between laser range finder and detection target through the transmitter emitted by a high degree of stability of laser pulse, which related to the design and application of laser. In particular, in order to achieve the function and performance of laser power supply was the most important. Therefore, the realization of the external control and real-time status of the amount of the acquisition become particularly important in space-borne laser power supply. Based on FPGA technology, by use of AC/DC power supply module, remote telemetry components and display control module, a system was designed to provide external signal, Q-signal and AD/DA control signal of the laser power supply, in order to achieve the real-time telemetry of the status of amount of laser power supply, and the real-time adjustment and control of LD current signal and Q-signal. The system could be set to control the laser repetition rate and laser emission times, can also be related to real-time display of the number of the laser repetition rate and laser emission times, could also be related to real-time display of number of the laser pulses and the remote measurement of the laser power supply. At the same time, the design and implementation of the system which involved in laser power supply were described in details, and they would further propose the improvement program of high reliability performance and functionality, in order to enhance remote control and telemetry system of the laser power supply.
- laser power supply /
- remote control and telemetry system /
- FPGA

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星载激光器电源遥控遥测系统的设计与实现

doi: 10.3788/IRLA201645.1020003

1. 北京空间机电研究所,北京 100094

作者简介:
宋博(1987-),男,工程师,硕士,主要从事激光信息处理领域的研究。Email:bobosongmm@126.com

收稿日期: 2016-02-15
修回日期: 2016-03-15
刊出日期: 2016-10-25

中图分类号: TN249

关键词:

摘要: 星载激光测距通过发射机射出稳定度较高的脉冲激光实现对目标物的距离测量，其中涉及到激光器的设计与应用，尤以激光器电源功能和性能的实现最为重要。因此，实现星载激光器电源的外部控制和实时状态量的采集变得尤为重要。在基于FPGA技术基础上，利用AC/DC电源组件、遥控遥测组件和显示控制组件，设计出一种可以对激光器电源提供外时统信号、调Q信号、AD/DA控制信号，从而实现激光器电源状态量的实时遥测和LD电流信号、调Q信号的实时调节控制的系统，该系统可以设置激光重频和控制激光出射时刻，也可以实时显示激光脉冲次数和激光器电源的相关遥测量，同时对该系统涉及到的设计与实现进行了详细阐述，并对高可靠性的激光器电源遥控遥测系统性能和功能的进一步提升提出了改进方案。

English Abstract

Design and realization of remote control and telemetry system of space-borne laser power supply

1. Beijing Institute of Space Mechanics & Electricity,Beijing 100094

Received Date: 2016-02-15
Rev Recd Date: 2016-03-15
Publish Date: 2016-10-25

Keywords:

Abstract: Space-borne laser ranging could measure the distance between laser range finder and detection target through the transmitter emitted by a high degree of stability of laser pulse, which related to the design and application of laser. In particular, in order to achieve the function and performance of laser power supply was the most important. Therefore, the realization of the external control and real-time status of the amount of the acquisition become particularly important in space-borne laser power supply. Based on FPGA technology, by use of AC/DC power supply module, remote telemetry components and display control module, a system was designed to provide external signal, Q-signal and AD/DA control signal of the laser power supply, in order to achieve the real-time telemetry of the status of amount of laser power supply, and the real-time adjustment and control of LD current signal and Q-signal. The system could be set to control the laser repetition rate and laser emission times, can also be related to real-time display of the number of the laser repetition rate and laser emission times, could also be related to real-time display of number of the laser pulses and the remote measurement of the laser power supply. At the same time, the design and implementation of the system which involved in laser power supply were described in details, and they would further propose the improvement program of high reliability performance and functionality, in order to enhance remote control and telemetry system of the laser power supply.