超辐射发光二极管数值仿真模型

Numerical simulation model of superluminescent diodes

导出

摘要采用谱分割方法和分段模型对1.5μm波段的超辐射发光二极管(SLD)进行了仿真。为减小分段模型的分段数目和计算时间,对文献中常采用的计算每小段平均光功率(平均光子数密度)的3种主要方法进行了对比分析,结果表明:积分平均的方法具有显著的优势。与商用器件的测试结果相比,数值计算的输出光谱和电流-输出功率曲线基本相符。对高功率SLD的数值仿真表明:在有源区长度大于1mm后,输出功率的增长出现明显的饱和现象,纵向空间烧孔(LSHB)效应限制了增加有源区长度对输出功率增长的贡献。此外,对高功率SLD,使用忽略LSHB效应的单段模型计算输出功率可产生数倍的误差,因此,采用分段模型计入LSHB效应是必要的。 The spectrum slicing technique and the subsection model were used to simulate a 1.5 μm superluminescent diode（SLD）.In order to reduce the subsection number in the model and the consumed time,three different average optical power（average photon density） calculation methods,which were commonly used in reference,were compared.It is found that the integral average method has remarkable superiority for SLD performance simulation.The results obtained from the simulation are compared with a commercial device,and reasonable agreement has been achieved for the optical power spectrum and P-I relationship.For high power SLDs,numerical results demonstrate that the output power begins to saturate notably when the length of the active region is beyond 1 mm.The longitudinal spatial hole burning（LSHB） effect limits the output power increasing with the length of the active region.In addition,the negligence of the LSHB effect in the single section model results in an incorrect prediction of the output power that is several times larger than it is supposed to be for the high power SLDs;therefore,it becomes necessary to adopt the subsection model and take into account the LSHB effect.

作者陈俊黄德修黄黎蓉张新亮

机构地区华中科技大学光电子科学与工程学院武汉光电国家实验室

出处《红外与激光工程》 EI CSCD 北大核心 2010年第1期51-56,共6页 Infrared and Laser Engineering

基金国家自然科学基金资助项目(60777019)

关键词超辐射发光二极管纵向空间烧孔效应放大的自发辐射 Superluminescent diodes Longitudinal spatial hole burning Amplified spontaneous emission

分类号 TN36 [电子电信—物理电子学]

引文网络
相关文献

参考文献13

1杨远洪,申彤,郭锦锦.光纤陀螺技术及应用[J].红外与激光工程,2007,36(5):626-631. 被引量：27
2SONG J H,KIM K,LEEM Y A,et al.100 mW high-power broadband superluminescent diode using selective area growth at 1.5-μm wavelength[C]// OFC,2008,JWA44.
3PARK S,WEIA J,HU Y,et al.100 mW high power depolarized superluminescent diode at 1550 nm wavelength[C]//SPIE,2006,6134:61340E.
4ALPHONSE G A,GILBERT D B,HARVEY M G,et al.High power superluminescent diodes[J].IEEE J Quantum Electron.1998,24(12):2454-2457.
5FEHR J N,DUPERTUIS M A,HESSLER T P,et al.Direct observation of longitudinal spatial hole burning in semiconductor optical ampfifies with injection[J].Appl Phys Lett,2001,78:4079.
6GIULIANI G,D'ALESSANDRO D.Noise analysis of convent-ional and gain-clamped semiconductor optical amplifiers[J].J Lightwave Technol,2000,19(9):1256-1263.
7ZHURAVLEVA O V,KURNOSOV V D,KURNOSOV K V,et al.Study of the spectral and power characteristics of supeduminescent diodes[J].Quantum Electron,2004.34:15-19.
8ADAMS M J,COLLINS J V,HENNING I D.Analysis of semiconductor laser optical amplifiers[J].Inst Elec Eng,Proc-Part J,1985,132(1):58-63.
9COLDREN L A,CORZINE S W.Diode Lasers and Photonics Integrated Circuits[M].NewYork:Wiley.1995.
10CONNELLY M J.Wideband semiconductor optical amplifier steady state numerical model[J].IEEE J Quantum Electron,2001,37:439-447.

二级参考文献10

1杨远洪,王峥,伊小素,张惟叙.基于掺铒超荧光光纤光源的高精度光纤陀螺[J].北京航空航天大学学报,2005,31(11):1159-1162. 被引量：13
2VAL I V,SHORTHILL R W.Fiber ring interferometer[J].Applied Optics,1976,15:1099-1100.
3LEFEVRE H.The Fiber-Optic Gyroscope[M].London:Artech House,1993.
4WANDNER K.Low noise fiber optic gyroscopes for the sofia project[C]//Symposium Gyro Technology,1999.
5SHUPE D M.Thermally induced nonreciprocity in the fiberoptic interferometer[J].Applied Optics,1980,19(5):654-655.
6WILLEMENOT E,et al.Very high performance fog for space use[C]//Symposium Gyro Technology,2002.
7ADAMS G.Evolution of precision[C]// ION 57th Annual Meeting and the CIGTF 20th Biennial Guidance Test Symposium,2001.
8YANG Yuan-hong,MA Jing,ZHANG Wei-xu,et al.Fail selfdiagnosing technique in closed-loop I-FOG and its application in redundant strapdown inertial measure unit[C]//Proceedings of SPIE,Fiber Optic Gyros:20th Anniversary Conference,1996,2837.
9PAVLATH G A.Fiber Optic Gyro Evolution Concept to Product[R].AIAA-92-4415-CP.
10VALERI R,et al.Development of a small precision FOG IMU[C]//ION 57th Annual Meeting/CIGTF,2001.

共引文献26

1徐小斌,伊小素,张春熹.超辐射发光二极管参数建模及其补偿技术[J].红外与激光工程,2008,37(2):352-354. 被引量：4
2张小跃,张春熹,宋凝芳.基于组合导航技术的光纤捷联系统在线标定[J].航空学报,2008,29(6):1656-1659. 被引量：23
3陈淑英,赵晶晶,马静.光纤陀螺加速退化试验的可行性[J].中国惯性技术学报,2008,16(5):623-626. 被引量：6
4朴春慧,范振江,刘春姣.基于光纤陀螺的转台角速度检定系统[J].计算机工程与设计,2009,30(20):4751-4753.
5莫军,王光辉,赵海军.基于海流数据库的Kalman滤波在水下导航中的应用(英文)[J].舰船科学技术,2010,32(4):51-56. 被引量：3
6杨远洪,段玮倩,叶淼,杨明伟.光子晶体光纤陀螺技术[J].红外与激光工程,2011,40(6):1143-1147. 被引量：14
7晁代宏,马静,陈淑英,张春熹.基于性能退化的卫星用光纤陀螺可靠性评估[J].红外与激光工程,2011,40(9):1763-1767. 被引量：16
8王维强,刘军,鲁军.三轴光纤陀螺的分时复用闭环控制技术[J].红外与激光工程,2011,40(11):2195-2200. 被引量：4
9王子南,王翠云,王玉杰,王大量,孙月,徐连宇,李正斌.基于多点耦合内切的光纤谐振环慢光系统转动传感理论[J].红外与激光工程,2011,40(12):2492-2496. 被引量：1
10马学文,刘洁瑜,张志警.光纤陀螺电磁干扰试验分析[J].压电与声光,2012,34(2):218-221. 被引量：1

1黄家云.光模块灵敏度自动化测试方案[J].电子制作,2013,21(5X):53-53.
2杨定新,胡茑庆,温熙森.双稳系统数值仿真模型的稳定性分析[J].系统仿真学报,2005,17(10):2338-2340. 被引量：4
3韩威,陈国鹰,安振峰,花吉珍,赵润,孟桂超.1.55μm DFB LD光栅结构的优化设计[J].半导体光电,2006,27(4):390-392.
4张冶金,朱林,高志国,陈明华,董毅,陈维友,刘式墉,谢世钟.Investigation of Mode and Modulation Responses in Semiconductor PS-DFB Lasers:Use of a Vector-Newton Method[J].Journal of Semiconductors,2002,23(9):935-940.
5陈晓鹏,王亚非.4.25Gb/s光收发模块性能研究[J].光通信技术,2006,30(7):27-29. 被引量：4
6解军,范毅,陈鹤鸣.偏振模色散的波片级联仿真模型的比较[J].光子技术,2004(4):221-224. 被引量：2
7陈俊,刘应开,杜雷鸣.半导体光放大器宽带ASE噪声谱数值模型[J].云南师范大学学报（自然科学版）,2003,23(5):29-33.
8于丽娟,金潮渊,芦秀玲,黄永箴.1.55μm偏振不灵敏光放大器结构材料的生长[J].半导体光电,2003,24(4):274-275.
9徐荣青,常春耘,兰信钜,陈培锋.连续Nd:YAG激光器输出功率曲线双峰结构的理论与实验研究[J].激光杂志,2000,21(6):12-14.
10徐荣青,王建华,倪晓武.连续Nd∶YAG激光器输出功率曲线双峰结构的消除[J].激光与红外,2000,30(1):33-35.

红外与激光工程

2010年第1期

浏览历史

内容加载中请稍等...

超辐射发光二极管数值仿真模型

参考文献13

二级参考文献10

共引文献26

相关作者

相关机构

相关主题

浏览历史