光子晶体光纤

这说明了采用全固体结构设计具有高保偏性能且制造工艺简单的保偏光子晶体光纤是可行的。

In a word , the all-solid structure design and simple fabrication with good polarization maintaining capability has proved the feasibility of polarization maintaining PCF .

因此，这种双芯光子晶体光纤把高双折射和高的耦合强度成功的结合在一起，双折射度达到10-2量级，这对于微型光子器件的研制具有重要意义。

Therefore , the kind of dual-core PCF combines the high birefringence and high coupling degree together successfully . The birefringence reaches 10-2 order of magnitude .

基于ARM的光子晶体光纤端面图像采集系统

Image gathering system of photonic crystal fiber section based on ARM

光子晶体光纤（photoniccrystalfibers，PCF）是基于光子晶体技术发展起来的新一代光纤。

Photonic crystal fibers ( PCF ) are a new kind of fibers with photonic crystal structures .

光子晶体光纤（photoniccrystalfiber，PCF）由于具有结构可控的灵活性和新颖的传输特性而成为近年来国内外研究的热点。

Photonic Crystal Fiber ( PCF ) becomes Research hotspot because of its flexibility of the controllable structure and novel transmission characteristics recently .

光子晶体光纤的问世，使得光子晶体保偏光纤（Polarizationmaintainedphotoniccrystalfibers，PM-PCF）的研究一直是光通信领域的研究热点。

The coming out of photonic crystal fibers makes the research of polarization maintained photonic crystal fibers become a hotspot in the field of optical communication .

而在孔距∧确定的情况下，光子晶体光纤的波导色散的零点、极小值点位置与f在所讨论的波长范围内存在线性关系。

When the pitch Λ is fixed , the zero and the extremum positions of the waveguide dispersion are linear with f in prefer wavelength range .

在理论模拟的基础上，采用光纤的后处理技术，对原有常规光子晶体光纤进行加工，经过选择性堵孔和熔融拉锥，制作出了一段W型光子晶体光纤。

A W-type photonic crystal fiber is created by using the post-processing techniques of the PCF , including controlled hole collapse and taper . 4 .

由于光子晶体光纤结构的多样性和相关器件研究的需要，对光子晶体光纤的CD进行精密测量就显得尤为重要。

Due to the diversity of PCFs ' structure and study of its relevant devices , the precision measurement of PCFs ' CD is particularly important .

PBG光子晶体光纤中空气导光条件的研究

A Study on the Air Guiding Condition of Lightwave in Photonic Bandgap Fibers

近年来，光子晶体光纤（PCF）技术取得很大的进展。

In recent years , the photonic crystal fiber ( PCF ) technology has made great progress .

用平面波展开法对光子晶体光纤中电磁场的Maxwell方程组进行了求解。

The Maxwell equations for the propagation of electromagnetic waves in photonic crystal fibers are solved with plane wave method .

基于高非线性光子晶体光纤Sagnac环形镜的全光开关

A all-optical switching based on highly nolinear photonic crystal fiber Sagnac loop mirror

本文应用平面波法和光子晶体光纤（PCF）的全矢量超格子叠加模型，分析了光子晶体光纤的模式及二次模截止特性。

Plane wave method and a full vector model based on supercell lattice method are applied for modeling photonic crystal fibers .

光子晶体光纤（photoniccrystalfibre，简称PCF）是一种近些年提出的、沿光纤截面存在二维周期性介电结构的光纤。

Photonic crystal fibre ( PCF for short ) is a recent proposed optical fibre , in which there exists a periodic dielectric structure in the cross-section of the fibre .

光子晶体光纤（PCF）是一种具有特殊包层结构的光纤，它是利用光子禁带效应（PBG）来导光的。

The photonic crystal fiber ( PCF ) with a special envelop structure induces the light by photonic bandgap ( PBG ) effect .

光子晶体光纤激光器可标定kW级的输出功率，可使高功率工作的掺稀土光纤激光器产生变革。

The photonic crystal fiber lasers should be scalable the kilowatt lever of output , they have the potential to revolutionize rare-earth-doped fiber lasers in high-power operation .

光子晶体光纤（photoniccrystalfiber，简称PCF）是近年来提出的一种光纤，它沿界面存在二维周期性的介电结构，是基于光子晶体技术发展起来的新一代光纤。

Photonic crystal fiber ( PCF ) is proposed as a new generation of fiber which based on development of photonic crystal technology in recent years , it has two-dimensional periodic dielectric structure along the interface .

由于在光通信领域的美好应用前景，具备一些新奇性质的光子晶体光纤（PCF）近年来引起人们越来越多的重视。

Due to the promising application in optical communication , photonic crystal fiber ( PCF ) with some unique properties arouses more and more attentions recently .

光子晶体光纤（POF）与普通光纤在光纤结构、单模特性、色散特性和非线性特性等方面有着显著的差别。

Photonic crystal fibers ( PCF ) are quite different from standard optical fibers in fiber structure , mode property , dispersion and nonlinearity .

在充分研究了常规W型光纤和普通光子晶体光纤的基础上，提出了一种新型的W型光子晶体光纤，用有限元法对该种光纤进行了仿真。

Based on the study and analysis of the W-type fiber and the common photonic crystal fiber , this paper presents a new type of W-type photonic crystal fiber . And it is simulated by using the finite element method .

800nm附近具有平坦色散的光子晶体光纤的计算与设计

Calculation and design of photonic crystal fibers with flattened dispersion at 800 nm

利用光子晶体光纤（PCF），在10Gb/s光传输系统中、20nm宽带范围内完成了色散补偿传输实验，得到了很好的色散补偿效果。

The experiment on dispersion compensation of 10 Gb / s pulses using photonic crystal fiber ( PCF ) within 20 nm bandwidth is reported .

作为一类特殊的光波导，光子晶体光纤（PCF）以其传统波导所不具有的一系列特殊的性质而被广泛的研究。

As a special class of optical waveguides , photonic crystal fibers ( PCFs ) have been extensive-ly studied because of their many unique properties which are not available in traditional waveguides .

应用光子晶体光纤（PCF）的本地正交基函数模型，对PCF的模式特征进行了详尽的数值研究，包括模式特性、传输常量、模场分布、模场面积、功率限制特性等。

The mode characteristics of the photonic crystal fiber ( PCF ) are investigated in detail using the orthogonal functions , including the propagation constant , mode-field distribution , effective power confinement factor .

为提高普通布里渊激光器的输出功率和激光效率，提出一种基于小纤芯光子晶体光纤（PCF）的环形腔布里渊光纤激光器。

To improve the output power and the laser efficiency compared with common fiber Brillouin lasers , a small core photonic crystal fiber ( PCF ) based ring-cavity Brillouin fiber laser was presented .

光子晶体光纤（PCF），又称为多孔光纤（HF）或微结构光纤（MF），是一种单一介质，并由波长量级的空气孔构成微结构包层的新型光纤。

Photonic crystal fibers ( PCFs ), also called holey fibers ( HFs ) or microstructure fibers ( MFs ), are a new class of single-material optical fibers with wavelength-scale air holes running down the entire length .

光子晶体光纤（PCF）由于其深刻的物理背景和重要的应用价值而受到广泛关注，成为光纤光学研究领域的一个新热点。

The Photonic crystal fiber ( PCF ) has called more and more attentions for its profound physic background and important applications , and it has become a new focus of the optical research domain .

分类讨论了光子晶体光纤中的三阶非线性效应，着重探讨了多个光波在PCF中相互作用所引起的四波混频及四波混频中相位匹配等问题。

The three-order nonlinear effects in PCFs are discussed . Four-wave mixing effects generating from the interaction of several optical waves in PCF and phase matching in four wave mixing are mainly investigated . 3 .

采用矢量有效折射率方法设计了在800nm附近具有平坦色散的光子晶体光纤。

A vectorial effective index method is used to design photonic crystal fibers with flattened dispersion around 800 nm .