透明纤维折射率的快速测量方法

IF 0.1 Q4 INSTRUMENTS & INSTRUMENTATION
Mykola Kokodii, A. Natarova, I. Priz, O. Biesova
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引用次数: 0

摘要

本文提出了一种测量透明光纤主要光学参数之一的折射率的简便方法。该方法利用了这种纤维所具有的圆柱形透镜的聚焦特性。对于光纤制造商和光通信系统设计者来说,能够准确测量光纤的壳芯直径、数值孔径、折射率分布、损耗和色散等特性同样重要,他们应该选择最符合他们要求的光纤。几乎所有的测量方法都使用光线在介质界面处的折射。要做到这一点,应该制作给定形状和大小的样品,每个测量仪器都是单独的。所建议的方法考虑到这样一个事实,即当光照射在折射圆柱体(玻璃棒,玻璃纤维)上时,聚焦发生在垂直于其轴的焦点区域,其中光线会聚。在这个区域后面,光线再次发散。焦点区域的位置由圆柱体的折射率决定。它可以在气缸内,气缸外,或气缸表面。在用显微镜观察纤维时,人们可以看到,穿过纤维的光在其背面形成一条明亮的带,背景是黑暗的。带宽取决于光纤的折射率。利用几何光学的方法进行了计算。这些方法可以应用于很宽的纤维直径范围。利用严格的衍射理论公式,计算了光纤及其周围辐射能量的分布。对得到的图形进行了数字分析。分析结果与用几何光学方法得到的结果一致。提出了一种确定折射率的算法。提供了人造纤维和天然纤维的折射率测量值,如玻璃纤维、纤维网和人的头发(金发、棕发、白发)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Express method for measuring the refractive index of transparent fibres
An express method for measuring the refractive index, which is one of the main optical parameters of transparent fibres, is suggested. The method uses focusing properties of a cylindrical lens, which such a fibre is. The possibility to accurately measure such characteristics of optical fibres as the shell and core diameters, numerical aperture, refractive index profile, loss, and dispersion is equally important for fibre manufacturers and designers of optical communication systems who should choose the fibre that meets their requirements best. Almost all measurement methods use the refraction of light rays at the interface between the media. To do this, one should make samples of given shape and size, which are individual for each measuring instrument. The suggested method takes into account the fact that when light strikes upon a refractive cylinder (glass rod, fibreglass), the focusing occurs perpendicular to its axis with a focal region where light rays converge. Behind this region, the rays diverge again. The position of the focal region is determined by the refractive index of the cylinder. It can be inside the cylinder, outside it, or on the surface of the cylinder. During the observation of the fibre using a microscope, one can see that the light, which has passed through the fibre, forms a bright band on its backside against a dark background. The bandwidth depends on the refractive index of the fibre. The calculations using the methods of geometric optics were carried out. These methods may be applied over a wide range of fibre diameters. Using strict formulas of diffraction theory, the distribution of radiation energy in the fibre and its vicinity was calculated. A digital analysis of the resulting pattern was carried out. The results of the analysis coincided with the results obtained using the methods of geometric optics. An algorithm for determining the refractive index was worked out. The measurements of the refractive indices of artificial and natural fibres like fibreglass, webs and human hair (blonde-haired person, brown-haired person, grey hair) were provided.
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来源期刊
Ukrainian Metrological Journal
Ukrainian Metrological Journal INSTRUMENTS & INSTRUMENTATION-
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