掺铒光纤激光器反相位混沌同步及其编码

针对单模双环掺铒光纤激光器具有光耦合相互作用的非线性动力学特点,应用“交叉注入反相位双环对两环主动—被动”混沌同步方法,数值模拟实现了两组相互独立的单模单环掺铒光纤激光器激光分别和单模双环掺铒光纤激光器对应环激光混沌同步;提出并数值模拟了具有调制频率1kHz和15kHz的正弦信号的双环—两环的两路混沌隐藏编码保密通信系统,它们解码质量好,保密性能强,可以很好地应用在混沌多路保密通信中。     

光注入掺铒光纤激光器的混沌特性

对光注入情况下混沌光纤激光器的输出特性进行实验研究.混沌光纤激光器采用环形腔结构,利用光纤的非线性克尔效应产生混沌激光.主激光器产生的混沌激光通过光隔离器和光纤耦合器注入到混沌掺铒光纤激光器实现外光注入.将主激光器产生的不同功率的混沌信号注入从激光器,研究光注入后从激光器混沌信号时序、频谱、自相关以及稳定性与复杂度等特性.结果 表明,光注入后的混沌信号时序随机且幅度频数呈高斯分布,频谱无明显的周期特性,自相关特性优良.光注入掺铒光纤激光器混沌输出在保证混沌源高复杂度的同时提高了混沌源的稳定性.     

损耗调制型掺铒光纤环形激光器混沌现象的实验研究

报道了损耗调制型掺铒光纤环形激光器中的混沌现象.在单频损耗调制型掺铒光纤环形激光器中,改变调制频率或调制电压,观察到倍周期分岔和阵发两种进入混沌途径的共存现象,与抽运调制型掺铒光纤环形激光器的实验结果相一致.提出了一种采用两个正弦信号驱动的损耗调制型掺铒光纤环形激光器,在调制信号频率比近似等于黄金分割数和白银分割数时,增加调制电压,发现激光器通过准周期途径进入混沌.当调制信号两频率比不同时,发生转变所需的调制电压也不同. 关键词： 掺铒光纤环形激光器 混沌 倍周期分岔 准周期     

基于半导体纳米线和金属脊的混合表面等离子体波导模式特性分析

波长可开关光纤激光器可以选择多波长光纤激光器中的一个或多个波长输出,支持光网络中多个波长的动态分配,适应现代光纤通信系统信道数越来越多的波分复用和密集波分复用的发展方向.本文提出并实现了一种自激发多波长可开关掺铒光纤激光器.该激光器通过一个980 nm泵浦进行抽运,使用掺铒光纤作为增益介质,产生1 550 nm光谱,并通过一个环形结构返回,从而实现自激发的过程,降低了实验成本.实验使用一个含有两段保偏光纤的Sagnac环作为滤波器.通过调整Sagnac环形滤波器内偏振控制器的角度,改变Sagnac环形滤波器的腔内增益,可以让光纤光栅反射出来的波长选择性通过,从而实现波长的开关功能.实验证明,通过调整Sagnac滤波器的腔内增益而让多波长选择性通过,是一种有效的实现波长可开关功能的方法.     

自激发多波长可开关掺铒光纤激光器

波长可开关光纤激光器可以选择多波长光纤激光器中的一个或多个波长输出,支特光网络中多个波长的动态分配,适应现代光纤通信系统信道数越来越多的波分复用和密集波分复用的发展方向,本文提出并实现了一种自激发多波长可开关掺铒光纤激光器,该激光器通过一个980 nm泵浦进行抽运,使用掺铒光纤作为增益介质,产生1550 nm光谱,并通过一个环形结构返回,从而实现自激发的过程,降低了实验成本,实验使用一个含有两段保偏光纤的Sagnac环作为滤波器,通过调整Sgnac 环形滤波器内偏振控制器的角度,改变Sagnac环形滤波器的腔内增益,可以让光纤光栅反射出来的波长选择性通过,从而实现波长的开关功能,实验证明,通过调整Sagnac滤波器的腔内增益而让多波长选择性通过,是一种有效的实现波长可开关功能的方法.     

基于反馈参数调制的掺铒光纤激光器混沌同步

提出了一种基于反馈参数调制控制超混沌同步的方法，并应用于双环掺铒光纤激光器系统.针对此种方法所具有的相位模糊问题，设计出了自动消除反相位的电路，数值模拟表明只要适当选择反馈强度值，就能实现两双环掺铒光纤激光器系统的精确同步. 关键词： 超混沌同步 双环掺铒光纤激光器 反馈参数调制法 反相位     

多波长混沌掺铒光纤环形激光器实验研究

利用掺铒光纤环形激光器(EDFRL),基于光纤的非线性克尔效应,实验实现了多波长混沌激光输出。实验研究了EDFRL在时序上通过倍周期进入混沌的路径,并进行了理论分析,理论研究与实验结果一致。实验结果表明,随着抽运功率的增加,其光谱的输出呈现多波长,激光器最多可输出5个不同波长的混沌激光。采用光纤光栅进行滤波后,各个波长的输出均呈现混沌状态。     

可调谐环形腔掺铒光纤激光器

使用高掺杂掺铒光纤制成了低噪声的环形腔光纤激光器。通过对文献中报道的环形腔结构光纤激光器输出的分析,指出了其存在的问题,并提出了减小其输出背景噪声的改进方案。通过实验验证了改进后的环形腔结构的低噪声特点,从原理上进行了解释。用不同掺铒光纤长度、泵浦功率、光栅波长及光栅反射率进行了实验,得到它们对输出光的性能影响。这种环形腔结构的光纤激光器可实现1525nm~1565nm连续可调谐输出。     

一种新型自激发布里渊掺铒光纤激光器

利用级联的受激布里渊效应,自激发布里渊掺铒光纤激光器可以实现常温下的多波长激光输出。通过在自激发掺铒光纤激光器中引入一个高双折射萨尼亚克(Sagnac)环形滤波器,调节萨尼亚克环形滤波器的偏振控制器(PC),实现了可调谐多波长输出,同时在实验中观测到双布里渊多波长带的现象。研究了这种光纤激光器中萨尼亚克环形滤波器的带宽和980 nm抽运光功率对输出波长数的影响,在萨尼亚克环形滤波器的带宽为83.3 nm以及980 nm抽运光功率为260 mW时,得到了52个间隔为0.088 nm的多波长激光输出。     

基于互注入的双环掺铒光纤激光器的混沌控制及同步

根据双环掺铒光纤激光器互耦合的结构特点,提出利用互注入对其混沌进行控制的方法.基于互注入双环掺铒光纤激光器的理论模型,模拟了激光器的动态特性.通过适当的调节互注入强度和延迟时间,可以同时把两个双环掺铒光纤激光器从混沌态控制到多周期态,周期1或2,以及稳态,实现了两个光纤激光器混沌行为的动态的相互控制.在此模型基础上附加反馈,实现了二者的混沌同步,并定量的分析了互注入强度和延迟时间,以及参数失配对同步性能的影响.     

Study of the optical feedback-induced noise in semiconductor lasers and applications to the optic disc system

The dynamics and noise of semiconductor lasers under optical feedback (OFB) have been simulated. The study is performed as applied to an optic-disc system in which laser radiation is reflected by the disc surface and re-injected into the laser cavity. We examine the possibility of suppressing OFB-induced noise in the optic-disc system by the technique of superposition of high-frequency current. The study is based on numerical integration of the time-delay rate equations of semiconductor lasers under OFB. The laser noise is evaluated in terms of the spectral profile of relative intensity noise (RIN). It is shown that RIN is enhanced when states of chaos are generated, and attains minimum levels under continuous-wave operation just before the laser starts the route to chaos. The suppression of RIN in the low-frequency regime is achieved when the superposition-current frequency exceeds the laser resonance frequency by factors of 0.8, 1.0, and 1.1 and when the modulation depth exceeds 0.4.     

自旋激光器的动力学特性及应用研究进展

在半导体激光器中引入自旋极化载流子是实现室温自旋电子应用的新途径,其超越了常规的磁阻效应。自旋极化载流子的注入导致自旋激光器具有丰富的动力学行为并展示出包括高频偏振振荡和偏振混沌动力学等特性,使其在保密光通信、量子计算、光信息处理和数据存储、可重构光互联以及生物医学传感等领域具有巨大的应用潜力。梳理了近年来自旋激光器的动力学特性及其应用研究进展。介绍了自旋激光器丰富的动力学行为及混沌演变机制;随后分析了自旋激光器的高频振荡特性;归纳了基于自旋激光器动力学特性的最新应用研究进展。在此基础上,展望了自旋激光器的发展趋势和面临的挑战,为相关领域的研究和工程应用提供参考。     

Experiments on chaos synchronization in two separate microchip lasers

Synchronization of chaos generated in two Nd:YVO(4) microchip lasers is experimentally demonstrated with master-slave coupling schemes. For synchronization of chaos, precise locking of the sustained relaxation-oscillation frequency is required, as is optical frequency locking. One needs to match both the pump-modulation parameters for chaos generation and the laser parameters of the two lasers to generate perfectly synchronized chaotic spectra in the master-slave type I coupling scheme.     

链式互耦合半导体激光器的实时混沌同步

通过在互耦合外腔半导体激光器之间增加中继激光器,建立了一种链式互耦合半导体激光器混沌同步系统模型.理论分析了系统的实时混沌同步条件,数值研究了注入电流、互耦合条件、反馈条件等对系统实时混沌同步品质的影响,揭示了同步质量在反馈强度和互耦合强度二维参数空间的分布规律.结果表明:注入电流较大时,满足互耦合强度和反馈强度相同,互耦合延时和反馈延时相等,系统中所有激光器之间可同时实现稳定高品质实时混沌同步;中心激光器和边激光器之间的稳定实时混沌同步分布在在互耦合强度和反馈强度较小的区域以及互耦合强度和反馈强度相近的区域;边激光器之间由于同时接收到中心激光器实施的相同注入,能够较容易的实现稳定高品质的实时混沌同步.该系统可进一步扩展成为实现远距离的双向实时混沌同步或阵列激光器系统的实时混沌同步.     

Close-loop three-laser scheme for chaos-encrypted message transmission

In this paper, we numerically evaluate private data transmission using a three-laser scheme, consisting of a pair of twin semiconductor lasers, driven to chaos by delayed optical feedback in a short cavity, and optically injected by a third chaotic laser which forces them to synchronize. This laser is selected with different internal parameters with respect to the twin pair, so that the emissions of the synchronized, matched lasers, are highly correlated, whereas their correlation with the driver is low. The digital message modulates the emission of the transmitter, as in a standard Chaos Modulation scheme. Message recovery is then obtained by subtracting, from the transmitted chaos-masked message, the chaos, locally generated by the synchronized receiver laser. Simulations have been performed with the Lang-Kobayashi model, and, in view of application to private transmission, we have investigated the effect of the parameter mismatch, between transmitter and receiver, on message recovery. A preliminary experimental evaluation has been also performed using specially designed InP integrated modules.     

Parallel generation of 10 Gbits/s physical random number streams using chaotic semiconductor lasers

In this paper, we have realized experimentally, for the first time to our knowledge, a parallel generation scheme of high speed random numbers by using chaotic laser. In our setup, two broadband chaos signals are obtained experimentally from a mutually coupled semiconductor lasers system. The bandwidths of these signals are over 10 GHz. Next, by using such chaos signals as entropy sources, two 10 Gbits/s physical random number streams are generated concurrently and successfully pass the NIST statistical tests. Our system is scalable and the rate of random numbers could be further enhanced by simply adding more channels.     

Synchronization properties and effects of parameter mismatches in unidirectionally coupled chaotic vertical-cavity surface-emitting lasers

We numerically investigate the effects of parameter mismatches on chaos synchronization in vertical-cavity surfaceemitting lasers (VCSELs). We assume injection-locked chaos synchronization in a unidirectionally coupled and openloop optical feedback system. The accuracy of chaos synchronization is greatly affected by the mismatches of the device parameters and operation conditions between the two lasers. In particular, the oscillation frequency of the laser is one of the important parameters in a system of injection-locked chaos synchronization. However, the variations of the device characteristics of VCSELs are very large compared with those of other types of semiconductor lasers. We study the effects of parameter mismatches related to the oscillation frequency of VCSELs on chaos synchronization. We proved that mismatches in terms of the birefringence and the injection current play crucial roles for the quality of chaos synchronization.     

Feedback Induced Instability and Chaos in Semiconductor Lasers and Their Applications

Semiconductor laser with feedback is an excellent model for nonlinear optical system which shows chaotic dynamics. It is interesting not only from the fundamental physical study but also application standpoints of view. The dynamics of feedback induced instability and chaos, especially for optical feedback, and their applications are reviewed in this paper. The model of such a system is described by the laser rate equations. At first the dynamic behaviors of feedback induced instability and chaos in semiconductor lasers are discussed on the basis of the theory and experiments. Instability and chaos may be stabilized by the method of chaos control. Then we apply the method to suppress the noise induced by the feedback in a semiconductor laser. The synchronization of chaos between two similar systems is also an important issue in chaos applications and we discuss secure communications based on chaos synchronization. Some other examples of applications of feedback induced chaos are also described.     

Bandwidth-enhanced chaos synchronization in strongly injection-locked semiconductor lasers with optical feedback

Bandwidth-enhanced chaos synchronization in strongly injection-locked semiconductor lasers with optical feedback is numerically studied based on laser rate equations. The bandwidth of the chaotic carrier frequency in a semiconductor laser with optical feedback is expanded roughly three times by strong optical injection compared with the bandwidth when there is no optical injection. Using a bandwidth-enhanced semiconductor laser as a chaotic transmitter and receiver, we synchronized transmitter and the receiver lasers in a complete chaos synchronization scheme.