SU1531049A1 - Fibre-optics decoupler - Google Patents

Abstract

The invention relates to optical fibers, and more specifically to fiber optical fiber connections, and can be used in fiber-optic communication lines and sensors. The purpose of the invention is to reduce the size and simplify the design by reducing the requirements for the accuracy of the prism movement. The splitter contains input and output fibers that are optically interconnected through a light-reflecting prism in the form of a rectangular isosceles triangle, having a refractive index greater than 1.4 + A, where A is the numerical aperture of the input fiber, the prism leg is 0, 5 to 2 diameters of the light guide core of the input fiber, and the ratio of the radiation intensity of the output fibers is determined by the ratio given in the claims. 1 il.

Description

The invention relates to optical fibers, namely to fiber optical fiber connections, and can be used in fiber-optic communication lines and sensors.

The purpose of the invention is to reduce the size and simplify the design by reducing the requirements for the accuracy of the prism movement.

The drawing shows a fiber optic splitter, cross section.

The fiber-optic splitter contains input 1 and output 2 and 3 fiber light guides, aligned with each other, a light reflecting prism 4, molded in the housing 5, and the device (6, providing linear movement of the light reflecting prism.

The splitter works as follows.

Optical radiation from the source enters the input and propagates through the input fiber optic 1, exits its end with an angular divergence defined by the numerical aperture of the optical fiber used A. Part of the light falls directly on the end of the output optical fiber 2 and propagates through it. Since the distance between the ends of the optical fibers does not exceed two diameters of the light guiding cores of the optical fibers, the radiation loss is not high.

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Prince The radiation that enters the light-reflecting prism falls on its hypotone- nous face in the range of angles ± + L / n. Since the refractive index of a prism n exceeds the value 1, | + L, then all the rays that hit the prism experience complete internal reflection and fall on the end of the fiber of the light guide 3. Optical path: radiated from the end of the input fiber to the end of the fiber 3 also does not exceed two diameters of the leading core of the optical fibers and Consequently, the radiation losses in this channel are also small. The luminescence; the reflection of a light reflecting prism in a plane perpendicular to the optical axis of the input optical fiber, allows the light beam of the reflecting prism A is the variable part of the cross section of the light conducting core of the light guide 1. At the same time, the alignment of the output optical fibers 2 and 3 is not disturbed.

When using standard multimode optical fibers made of quartz glass with a core diameter of 50 μm, a cladding of 125 μm and a numerical aperture of 0.2, the proposed fiber optic splitter has overall dimensions and is approximately an order of magnitude smaller than the known one. In this case, the device design means

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adjustable intensity ratio of radiation in the output optical fibers.

Claims (1)

Invention Formula A fiber optic splitter containing input and output fiber optic fibers aligned relative to each other and optically interconnected through a light reflecting prism, having a rectangular isosceles triangle in cross section and attached to a drive ensuring its linear movement, characterized by that in order to reduce the size and simplify the design by reducing the requirements for the accuracy of the movement of the prism, the reflective prism is made of a material with a refractive index greater than 1, 4 + L, where A is the numerical aperture of the input fiber, the length of the leg in the prism section is 0.5-2.0 times the diameter of the light guide core d of the input fiber, and the offset h of the edge of the light reflecting prism adjacent to The optical axis of the input optical fiber, relative to this axis, is related to the ratio of the radiation intensity, in the output fibers, If / Ij I, / 1, (cf-sincf) - 1, where c 2arccos (2h / d).