共查询到19条相似文献,搜索用时 156 毫秒
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新型大模场光子晶体光纤传输系统及其传输特性分析 总被引:1,自引:0,他引:1
通过在多模光子晶体光纤的两端分别连接一根单模光子晶体光纤,对其选择合适的参数,形成一种可以实现低弯曲损耗、大模场单模传输的光纤传输系统。运用数值仿真,分析了该传输系统在模场面积、弯曲损耗、连接损耗等方面的特性。研究结果表明,多模光子晶体光纤与单模光子晶体光纤所组成的系统可实现有效的单模传输;工作波长为1064nm时,多模光子晶体光纤在直波导状态时的基模模场面积可达1593μm2;在弯曲半径低至10cm时,多模光子晶体光纤仍然可以保持低损耗传输。经过对多模光子晶体光纤结构参数的优化,其与单模光子晶体光纤的连接损耗降低至0.085dB。 相似文献
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提出了一种复合结构的光子晶体光纤,采用多极法对其双折射、限制损耗、基模模场以及色散特性进行了数值模拟.研究表明,该光纤在1 550 nm处可获得1.56×10-2的双折射,限制损耗为7.31×10-3 dB/km,负色散达-320 ps/(nm·km),且损耗在1 300~1 600 nm范围内基本稳定. 相似文献
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单模光纤是在给定的工作波长中只传输单一基模的光纤,它不存在模式色散,所以具有相当宽的传输频带,运用于长距离大容量的传输.单模光纤的纤芯直径只有8~10 μm,包层直径为125 μm,可以制作得很长,但是为了制造、运输与施工的方便,通常光缆的出厂长度为1~6 km.单模光纤的传输损耗现低达0.2 dB/km(1.55 μm),光缆接续长度不宜小于2 km. 相似文献
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介绍了一种新型非光子晶体结构弯曲不敏感单模光纤的设计与制备。采用数值计算方法分析了光纤的下陷型波导结构,通过PCVD(等离子体化学气相沉积法)工艺获得了1 310nm波长的模场直径为4.3μm、1 550nm波长的模场直径为5.4μm的光纤样品,与G.652D光纤的双点接续损耗低至0.15dB,满足普通跳线的接续要求。该样品在2.5mm弯曲半径条件下弯曲10圈,其1 550nm波长的弯曲损耗优化至0.01dB,可适用于任何苛刻的FTTx应用环境,并有替代铜缆成为消费电子中理想传输介质的潜力,同时还可用于各种光电器件中。 相似文献
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设计了一种新型结构的光子晶体光纤,建立了对应的数学模型并采用全矢量有限元法对该结构的模场强度、有效折射率、双折射、色散特性和限制损耗进行了分析。研究表明,该光纤在1 550nm处可以获得高达7.66×10-3的双折射和低至12ps/(nm·km)的色散值,同时在800~1 600nm波长范围内,始终保持1.498×10-6 dB/m以下的极低限制损耗,可用于制造极低色散值的保偏光纤。 相似文献
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提出了一种新型掺锗芯低弯曲损耗光子晶体光纤。通过调整结构参数,实现了单模低弯曲损耗传输,与标准单模光纤有较好的适配性。仿真结果表明,波长1550nm处,弯曲半径为5mm时,基模损耗为0.014dB/km;弯曲半径为4mm时,基模损耗为0.42dB/km,能承受的弯曲半径小。显示了光子晶体光纤具有成为光纤到户"最后一公里"主要通信介质的性能优势。 相似文献
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设计了一种椭圆空气孔正方形点阵单偏振单模光子晶体光纤,并以聚甲基丙烯酸甲酯为基材,利用基于棱边/节点混合元的全矢量有限元法对该光纤进行了数值模拟。结果发现,其偏振模场、快轴模和慢轴模截止波长完全依赖于光纤的结构参数;通过优化光纤的结构参数,发现该光纤传输基模的一个偏振态(慢轴模)在0.62μm至0.70μm可见光波长范围内;若调整该光纤结构具有9圈椭圆空气孔时,其偏振模约束损耗在波长0.65μm处可以降至0.13dB/m。该聚合物基低损耗单偏振单模光子晶体光纤可以有效消除传统保偏光纤固有的偏振串扰和偏振模色散。 相似文献
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全固高非线性低色散斜率光子晶体光纤设计 总被引:1,自引:0,他引:1
提出了利用掺氟同心圆环的光纤结构来提高光子晶体光纤(PCF)的非线性,所需控制的参量仅有两个。设计了三种具有高非线性、低色散斜率和低限制损耗的全固光子晶体光纤。这三种光纤分别具有正常色散、双零色散点和零色散点恰好在1.55 μm波长处的色散曲线特性。所设计的零色散点恰好在1.55 μm波长处的光子晶体光纤色散斜率值为5.12×10-4 ps/(km·nm2),这比传统的高非线性光纤的色散斜率小了2个数量级。同时,该光纤在1.55 μm波长处的非线性系数为31.5 W-1·km-1,限制损耗为9.62×10-5 dB/km。 相似文献
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A new type ultraflattened dispersion square-lattice photonic crystal fiber with two different air-hole diameters in cladding region is proposed and the dispersion is investigated using a compact 2-D finite difference frequency domain method with the anisotropic perfectly matched layers (PML) absorbing boundary conditions. Through numerical simulation and opti- mizing the geometrical parameters, we find that the photonic crystal fibers proposed can realize ultraflattened dispersion of 0±0.06 ps/(km·nm) in wa... 相似文献
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损耗是传统光纤和光子晶体光纤得以实用化的重要参量之一,降低损耗是光子晶体光纤制备的首要问题.折射率引导型光子晶体光纤的损耗由1999年的240 dB/km降至0.28 dB/km(1550 nm波长处),光子带隙型光子晶体光纤的损耗也降低到1.2 dB/km(1620 nm波长处).在对比传统石英光纤损耗来源基础上,阐述了光子晶体光纤的损耗机理,并说明了损耗降低的主要途径. 相似文献
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A new large core (0.5-1.0 mm) graded-index polymer optical fiber was proposed to solve the connection problem of the single-mode silica fiber indoor use for high speed multimedia network. The bending loss for 10-mm bending diameter was dramatically decreased from 20 dB to less than 1 dB by preparing the high numerical aperture graded-index polymer optical fiber. The bandwidth was 585.2 MHz km which was one hundred times larger than that of any existent step-index polymer optical fibers, and the attenuation was 150 dB/km at 650-nm wavelength 相似文献
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采用矢量光束传输法(VBPM)对小纤芯光子晶体光纤(PCF)的色散特性进行了数值分析,研究发现通过调节光子晶体光纤的结构参数可以灵活的对其色散补偿值进行调整,能够实现C L波段(1 530~1 565 nm)的宽带色散补偿功能,并且对标准单模光纤的色散斜率有很好的补偿.在∧=1.0μm,d/∧=0.7时,1 550 nm处的色散值可以达到-339.1 ps/(km×nm),相关色散斜率(RDS)可以达到0.003 2 nm-1,能够有效的对标准单模光纤进行色散斜率补偿. 相似文献
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Imoto N. Kawana A. Machida S. Tsuchiya H. 《Quantum Electronics, IEEE Journal of》1980,16(10):1052-1058
Characteristics of dispersion free single-mode fibers in the wavelength regions 1.5 and 1.3 μm are compared experimentally and theoretically. We consider the influence of the refractive index profile on dispersion, the tolerance limits of structure parameters for minimum dispersion, attainable fiber bandwidth, and transmission loss including splicing and bending losses. For a fiber designed for minimum dispersion at 1.5 μm, the measured fiber loss was less than 1 dB/km and bandwidth was 250 GHz. km. nm. The achievable minimum loss estimation shows the advantage of dispersion free fibers at the 1.5 μm wavelength over dispersion free fibers at 1.3 μm. 相似文献
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Shuqin LOU Shujie LOU Tieying GUO Liwen WANG Weiguo CHEN Honglei LI Shuisheng JIAN 《中国光电子学前沿》2009,2(2)
Our recent research on designing microstruc-tured fiber with novel dispersion properties is reported in this paper. Two kinds ofphotonic crystal fibers (PCFs) are introduced first. One is the highly nonlinear PCF with broadband nearly zero flatten dispersion. With introducing the germanium-doped (Ge-doped) core into highly non-linear PCF and optimizing the diameters of the first two inner rings of air holes, a new structure of highly non-linear PCF was designed with the nonlinear coefficient up to 47 W-1·km-1 at the wavelength 1.55 μm and nearly zero flattened dispersion of ±0.5 ps/(km·nm) in telecom-munication window (1460-1625nm). Another is the highly negative PCF with a ring of fluorin-doped (F-doped) rods to form its outer ring core while pure silica rods to form its inner core. The peak dispersion - 1064 ps/(km·nm) in 8 nm full width at half maximum (FWHM) wavelength range and -365ps/(km·nm) in 20nm (FWHM) wavelength range can be reached by adjusting the structure parameters. Then, our recent research on the fabrication of PCFs is reported. Effects of draw parameters such as drawing temperature, feed speed, and furnace temperature on the geometry of the final photonic crystal fiber are investigated. 相似文献
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Dispersion-flattened photonic crystal fiber with large effective area and low confinement loss 总被引:2,自引:0,他引:2
A photonic crystal fiber (PCF) can realize a flat dispersion over a wide wavelength range that cannot be realized with a conventional single-mode fiber. However, the confinement loss tends to increase in a conventional dispersion-flattened PCF (DF-PCF) that has uniform air holes. In this paper, a novel PCF that has two cladding layers with different effective indices is proposed. The authors numerically show that the proposed PCF can achieve an ultralow dispersion variation of less than 0.8 ps/nm/spl middot/km in all telecommunication bands, with both a large effective area greater than 100 /spl mu/m/sup 2/ and a low confinement loss less than 0.01 dB/km. 相似文献