排序方式: 共有57条查询结果,搜索用时 431 毫秒
1.
2.
3.
研究了L-波段超荧光在光纤中的产生机理,设计了一种带光纤圈反射器的双级双程前向输出L-波段光源结构,通过对两级采用掺铒浓度不同的光纤并优化其长度及两级泵浦光功率,实验中获得了功率高达19.86mW(12.98dBm)、中心波长为1577.421nm的L-波段(1555-1620nm)超荧光光源。实现了低浓度掺铒光纤起诱导光及改善光谱的作用,高浓度光纤为主要发光源,采用光纤圈反射器提高了泵浦光的利用效率、光源的平坦度及稳定性。同时分析了结构中各个参量对光源各方面性能的影响,对光源的设计具有指导意义。 相似文献
4.
本文根据硬件线程的特征,为硬件线程调度建立了一个周期与非周期混合线程集的调度模型.在数学层面描述了硬件多线程调度中每个线程被成功调度的条件判据.并在此基础之上,提出一种以截止时间与最坏执行时间差为基本因子的DR-EDF算法,提供了一种实现这种DR-EDF算法的硬件多线程控制器的设计原理.最后用FPGA为载体,实现了一款硬件多线程处理器,通过实际测试的分析结果,得出这种面向硬件多线程的实时调度算法在不影响线程集错失率前提下,提高了嵌入式系统中紧急任务的可调度性. 相似文献
5.
针对光速可控情况下信息的传播速度问题,提出利用非解析点方法测量掺Er3+光纤(EDF)中慢光和超光速情况下的信息速度.实验结果表明,可以通过调节泵浦光功率来控制慢光或者超光速传播的群速度,由于信息的传递速度不受群速度的影响,在我们测量精度内,非解析点代表的信息速度不会超过真空中的光速. 相似文献
6.
7.
Wireless Local Area Networks have gained popularity at an unprecedented rate over the last few years. However, as the spectrum of applications they are called to support broadens, their inefficiency in meeting the diverse requirements of a wider range of applications becomes evident. Most existing access mechanisms cannot provide Quality-of-Service (QoS) assurances. Even those that are QoS aware can only provide relative service differentiation. In this work, we propose a dynamic priority medium access scheme to provide time-bounded services. By approximating an ideal Earliest Deadline First (EDF) scheduler, the proposed scheme can offer delay and delay jitter assurances while achieving high medium utilization. Analytical studies and simulation experiments document and confirm the positive characteristics of the proposed mechanism.
Orestis Tsigkas received his Diploma in electrical and computer engineering from the Aristotle University of Thessaloniki, Greece in 2002. He is currently working towards his Ph.D. degree in the same department. His research interests include medium access, as well as quality-of-service provisioning.
Fotini-Niovi Pavlidou received the Ph.D. degree in electrical engineering from the Aristotle University of Thessaloniki, Greece, in 1988 and the Diploma in mechanical-electrical engineering in 1979 from the same institution. She is currently a Professor at the Department of Electrical and Computer Engineering at the Aristotle University engaged in teaching for the under- and post-graduate program in the areas of mobile communications and telecommunications networks. Her research interests are in the field of mobile and personal communications, satellite communications, multiple access systems, routing and traffic flow in networks and QoS studies for multimedia applications over the Internet. She is being involved with many national and international projects in these areas (Tempus, COST, Telematics,IST) and she has been chairing the European COST262 Action on “Spread Spectrum Systems and Techniques for Wired and Wireless Communications”. She has served as member of the TPC in many IEEE/IEE conferences and she has organized/chaired some conferences like, the “IST Mobile Summit 2002”, the 6th “International Symposium on Power Lines Communications-ISPLC2002”, the “International Conference on Communications-ICT1998” etc. She is a permanent reviewer for many IEEE/IEE journals. She has published about 80 papers in refereed journals and conferences. She has served as guest-editor on special issues as: “Mobile Ad Hoc Networks (MANETs): Standards, Research, Applications” in the International Journal of Wireless Information Networks and “Power Line Communications and Applications” in the International Journal on Communications Systems. She is a senior member of IEEE, currently chairing the joint IEEE VT&AES Chapter in Greece. 相似文献
8.
新颖的双级双程输出C L波段高功率宽带光源 总被引:1,自引:0,他引:1
在分析了采用掺铒光纤(EDF)产生C波段和L波段光的基础上,进一步分析了双级双程结构实现C L波段宽带光源(BBS)的基本原理,优化设计后并通过实验用双级双程结构实现了高功率C L波段宽带放大的自发辐射(ASE)同时输出。其中,第1级采用双程前向可实现功率为19.2mW(12.93dBm),平均波长为1552.823nm的C L(1520~1610nm之间)ASE输出;第1级采用双程后向可实现功率为21.13mW(13.25dBm),平均波长为1552.925nm的C L(1524~1610nm之间)ASE输出,两级所用的光纤长度分别为7m(低浓度)和31m(高浓度)。对比分析两种结构输出光谱的抽运光利用效率、光滑平坦特性后,可得出第1级采用双程后向的双级双程是一种更为理想的实现C L波段高功率ASE输出的结构。 相似文献
9.
本文通过对常见的双级双程双泵浦光源进行实验研究,分析了两级掺铒光纤的长度以及两级泵浦的功率对光源输出光谱的功率大小、平坦度和平均波长的影响。根据实验分析结果,当EDF1和EDF2的长度分别为9 m和38 m,一级泵浦功率为65 mW,二级泵浦功率为115 mW时,光源输出功率为16.89 mW,平均波长为1 566.389nm,1 536nm-1 605nm波段范围内光谱的不平坦度±2dB。 相似文献
10.