磁性材料及器件
磁性材料及器件
자성재료급기건
JOURNAL OF MAGNETIC MATERIALS AND DEVICES
2014年
6期
1-4,19
,共5页
陈心怡%武保剑%文峰%袁浩
陳心怡%武保劍%文峰%袁浩
진심이%무보검%문봉%원호
有源非线性光纤%磁光效应%磁光光纤%2R再生器%功率转移函数%自相位调制
有源非線性光纖%磁光效應%磁光光纖%2R再生器%功率轉移函數%自相位調製
유원비선성광섬%자광효응%자광광섬%2R재생기%공솔전이함수%자상위조제
active nonlinear fiber%magneto-optical effect%magneto-optical fiber%2R regenerator%power transfer function%self-phase modulation
利用有源非线性光纤的磁光效应可实现智能的光纤信息处理,完成光信号的同时放大和整形。根据导波光脉冲的磁光非线性耦合模方程,采用分步傅里叶算法计算了增益分布对自相位调制频谱展宽的影响,计算结果与OptiSystem仿真一致。研究表明,基于自相位调制的再生器输入饱和功率随增益泵浦功率、光纤长度以及铒离子浓度的适当增加而减小,从而提高再生器的饱和增益。在有源非线性光纤轴向施加磁场,可提高再生器输入“传号”光脉冲的幅度抖动容限,还可以通过调节磁场改变自相位调制频谱展宽的大小,使再生器的功率转移函数与输入劣化信号特性灵活匹配。
利用有源非線性光纖的磁光效應可實現智能的光纖信息處理,完成光信號的同時放大和整形。根據導波光脈遲的磁光非線性耦閤模方程,採用分步傅裏葉算法計算瞭增益分佈對自相位調製頻譜展寬的影響,計算結果與OptiSystem倣真一緻。研究錶明,基于自相位調製的再生器輸入飽和功率隨增益泵浦功率、光纖長度以及鉺離子濃度的適噹增加而減小,從而提高再生器的飽和增益。在有源非線性光纖軸嚮施加磁場,可提高再生器輸入“傳號”光脈遲的幅度抖動容限,還可以通過調節磁場改變自相位調製頻譜展寬的大小,使再生器的功率轉移函數與輸入劣化信號特性靈活匹配。
이용유원비선성광섬적자광효응가실현지능적광섬신식처리,완성광신호적동시방대화정형。근거도파광맥충적자광비선성우합모방정,채용분보부리협산법계산료증익분포대자상위조제빈보전관적영향,계산결과여OptiSystem방진일치。연구표명,기우자상위조제적재생기수입포화공솔수증익빙포공솔、광섬장도이급이리자농도적괄당증가이감소,종이제고재생기적포화증익。재유원비선성광섬축향시가자장,가제고재생기수입“전호”광맥충적폭도두동용한,환가이통과조절자장개변자상위조제빈보전관적대소,사재생기적공솔전이함수여수입열화신호특성령활필배。
Active nonlinear fibers with magneto-optical effects are useful for intelligent fiber information processing, especially the realization of both amplifying and reshaping functions. According to the magneto-optical nonlinear coupled-mode equations for guided optical pulses, the influence of power gain distribution on self-phase-modulation (SPM)-induced spectrum broadening is calculated by using the split-step Fourier method and the calculation results are in good agreement with the OptiSystem simulations. The saturation input power of the SPM-based regenerators is reduced with the increase of gain pump power, fiber length, or erbium ion density, and then leads to the improvement of the saturation gain. Under the applied magnetic field along the axis of the active fibers, the resulting regenerators have a larger tolerance to the amplitude fluctuation for input mark pulses, and the power transfer function of regenerators can flexibly match with the input degraded signals due to the magnetic control mechanism of SPM-induced spectrum broadening.
