光电探测器暗电流宽温拟合算法研究

袁国振; 任海兰

doi:10.13756/j.gtxyj.2025.230148

您当前的位置：

首页 >

文章列表页 >

光电探测器暗电流宽温拟合算法研究

光电器件研究与应用 | 更新时间：2025-02-17

- 光电探测器暗电流宽温拟合算法研究
- Study of Wide-temperature Fitting Algorithm for PD Dark Current
- 光通信研究 2025年第1期
- 作者机构：
  
  1.武汉邮电科学研究院，武汉　 430074
  2.武汉莫仕通讯技术有限公司，武汉　 430070
- 作者简介：
  
  袁国振（2001－），男，湖北武汉人。硕士，主要研究方向为光模块掺铒光纤放大器。
  任海兰，教授。E-mail：464864919@qq.com
- 基金信息：
- DOI：10.13756/j.gtxyj.2025.230148
  中图分类号： TN256
- 纸质出版日期：2025-02-10，
  
  收稿日期：2023-09-21，
  
  修回日期：2023-10-18，
- 稿件说明：
移动端阅览
袁国振，任海兰. 光电探测器暗电流宽温拟合算法研究[J]. 光通信研究，2025(1): 230148.

Yuan G Z, Ren H L. Study of Wide-temperature Fitting Algorithm for PD Dark Current [J]. Study on Optical Communications, 2025(1): 230148.
袁国振，任海兰. 光电探测器暗电流宽温拟合算法研究[J]. 光通信研究，2025(1): 230148. DOI： 10.13756/j.gtxyj.2025.230148.

Yuan G Z, Ren H L. Study of Wide-temperature Fitting Algorithm for PD Dark Current [J]. Study on Optical Communications, 2025(1): 230148. DOI： 10.13756/j.gtxyj.2025.230148.

摘要

【目的】

为了消除光电探测器（PD）内正负（PN）结固有暗电流物理特性的影响，在提升探测器功率探测范围和扩宽探测器工作环境温度范围的同时提高PD探测精度，文章设计了一套在标定PD时应用的暗电流补偿算法。

【方法】

首先，通过分析光电二极管物理特性及PD内的硬件电路设计，建立光生电流与光功率间的数学模型，基于数学模型修正光功率与光生电压模数转换（ADC）值的曲线关系，实现在具体温度点下去除暗电流功率影响并补偿功率；其次，研究暗电流的温度特性，计算出少数温度条件下所需补偿暗电流的功率大小，利用少数温度点拟合扩展至宽温范围实现暗电流温度补偿；最后，搭建温控测试平台，利用光开关（OS）控制光电二极管入光功率大小，通过光功率探测仪记录PD实时入光功率大小，测试在不同温度条件以及入光功率下的PD精度值。

【结果】

实验表明，利用算法标定PD后，工作温度范围可从－5～55 ℃扩宽至－40～80 ℃，最低探测功率从－40下降至－68 dBm。在上述工作温度和探测范围下，软件算法计算上报的光功率与实际探测光功率的精度误差在±1 dB以内。

【结论】

采用文章所提算法对PD校准后能消除暗电流及噪声的影响，在宽温范围下能提高探测功率范围及探测精度。

Abstract

【Objective】

In order to eliminate the influence of the physical characteristics of the intrinsic dark current of the Positive-Negative (PN) junction in the Photoelectric Detector (PD)

the detection accuracy of the PD can be improved at the same time of enhancing the detection range of the detector power and widening the detector working environment temperature. In this paper

a set of dark current compensation algorithms is designed to calibrate the PDs.

【Methods】

Firstly

we analyze the physical characteristics of the photodiode and the hardware circuit design of the PD to establish a mathematical model between the photogenerated current and the optical power. Then we correct the curve relationship between the optical power and the Analog Digital Convert (ADC) value of the photogenerated voltage through the mathematical model

so as to achieve the power compensation by removing the influence of the dark current power at the specific temperature point. Next

by studying the temperature characteristics of dark current

we calculate the power required to compensate for dark current under a limited number of temperature conditions. By fitting these few temperature points

we extend the compensation to a broader temperature range

thereby achieving dark current temperature compensation. Lastly

a temperature-controlled testing platform is established

utilizing an Optical Switch (OS) to regulate the incident optical power on the photodiode. The real-time incident optical power on the PD is recorded through an optical power meter. This setup allows for testing the accuracy of the PD under various temperature conditions and incident optical power levels.

【Results】

The experiments show that the working temperature can be widened from －5～55 ℃ to －40～80 ℃ and the minimum detection power can be reduced from －40 to －68 dBm by using the algorithm to calibrate the photo-detector. Under the aforementioned operating temperature and detection range

the software algorithm calculates the accuracy error between the reported optical power and the actual detected optical power to be within ±1 dB.

【Conclusion】

After calibrating the PD with this algorithm

the effects of dark current and noise can be eliminated

and the detection power range and detection accuracy can be improved in a wide temperature range.

关键词

Keywords

references

甘文祥 . 红外焦平面器件读出电路技术 [J ] . 红外 , 2003 ( 9 ): 1 － 8 .

Gan W X . Infrared Focal Plane Device Readout Circuit Technology [J ] . Infrared , 2003 ( 9 ): 1 － 8 .

陈冬琼 , 王海澎 , 秦强 , 等 . InAsSb势垒阻挡型红外探测器暗电流特性研究 [J ] . 红外与毫米波学报 , 2022 , 41 ( 5 ): 810 － 817 .

Chen D Q , Wang H P , Qin Q , et al . Research on Dark Current Characteristics of InAsSb Barrier-blocking Infrared Detector [J ] . Journal of Infrared and Millimeter Waves , 2022 , 41 ( 5 ): 810 － 817 .

She L F , Jiang J K , Chen W Q , et al . Mid-wave Infrared p＋-B-n InAs/InAsSb Type-II Superlattice Photodetector with an AlAsSb/InAsSb Superlat-tice Barrier [J ] . Infrared Physics & Technology , 2022 , 121 : 104015 .

张露漩 , 袁媛 , 李敬国 . 背景暗电流抑制的红外探测器读出电路输入级设计 [J ] . 激光与红外 , 2021 , 51 ( 1 ): 69 － 73 .

Zhang L X , Yuan Y , Li J G . Input Stage Design of IR Detector Readout Circuit with Background Dark Cur-rent Suppression [J ] . Laser & Infrared , 2021 , 51 ( 1 ): 69 － 73 .

葛张峰 , 余晨辉 , 陈鸣 , 等 . AlGaN日盲紫外雪崩光电探测器暗电流研究 [J ] . 红外与激光工程 , 2018 , 47 ( 9 ): 0920003 .

Ge Z F , Yu C H , Chen M , et al . Research on Dark Current of AlGaN Solar-blind Ultraviolet Avalanche Photodetectors [J ] . Infrared and Laser Engineering , 2018 , 47 ( 9 ): 0920003 .

马晓凯 . 光通信波段光探测器的暗电流抑制与宽谱高速及大功率响应特性的研究 [D ] . 北京 : 北京邮电大学 , 2019 .

Ma X K . Research On Dark Current Suppression and Wide-Spectrum, High-Speed and High-Power Re-sponse Characteristics of Photodetectors within Wavelength Region of Optical Communications [D ] . Beijing, China : Beijing University of Posts and Telecommunications , 2019 .

徐雨欣 , 罗向东 , 徐佳斌 , 等 . 一种光敏二极管的暗电流补偿电路：中国， CN202210301344.0 [P ] . 2022-07-01 .

Xu Y X , Luo X D , Xu J B , et al . A Dark Current Compensation Circuit for a Photodiode : China, CN202210301344.0 [P ] . 2022-07-01 .

徐孟军 . 光电感烟火灾探测器原理及标定方法 [J ] . 科技创新与应用 , 2015 ( 20 ): 26 .

Xu M J . Principle and Calibration Method of Photoelectric Smoke Detector [J ] . Technology Innovation and Application , 2015 ( 20 ): 26 .

李颖 , 林洪生 . 基于相对误差的曲线最小二乘拟合 [J ] . 沈阳师范大学学报(自然科学版) , 2012 , 30 ( 3 ): 338 － 342 .

Li Y , Lin H S . Relative Error based Curve Fitting for Least Square Method [J ] . Journal of Shenyang Normal University (Natural Science Edition) , 2012 , 30 ( 3 ): 338 － 342 .

殷亚详 , 邵云峰 , 张光宇 , 等 . 半导体光电传感器暗电流的校正方法和系统：中国， CN202211672220.X [P ] . 2023-03-03 .

Yin Y X , Shao Y F , Zhang G Y , et al . Semiconductor Photoelectric Sensor Dark Current Correction Method and System : China, CN202211672220.X [P ] . 2023-03-03 .

浏览量

下载量

CSCD

CNKI被引量

文章被引用时，请邮件提醒。

提交

工具集

关联资源

四象限InGaAs APD探测器的研究

基于对数转换器的暗电流测试系统

具有高量子效率、低暗电流、高可靠性的平面InGaAs　PIN光电二极管