FR2581204A1 - Mechanically-controlled 1-by-N optical selector for multimode fibres - Google Patents

Abstract

A selector of the invention comprises N fibres 1 arranged in a circle C and a central fibre 3 at the centre of the circle. A total-reflection prism 5, which can move about an axis X passing through the centre of the circle, reflects a light ray and enables, by rotation, one of the N fibres 1 to be selected. In one embodiment, the prism has its hypotenuse face 9 parallel to the plane of the circle and arranged radially, the N fibres and the central fibre being perpendicular to the plane of the circle. The prism 5 is rotated by a stepping motor.

Description

1-by-N optical selector with mechanical control, for multimode fibers
The invention relates to optical switching devices for connecting a channel to another channel chosen from N possible channels. Such devices are particularly used in the switching, concentration and distribution functions of broadband signals carried by multimode optical fibers.

 In the state of the art, two different methods have been developed to achieve optical switching between multimode fibers.

The first method consists in physically bringing the optical fibers together so as to optimize their optical coupling. Among the many systems using this method we can cite; - the 1 x 93 switch produced by OGIWARA & Co, Optical and
Quantum Electronics Vol. 12. NO 1, Dec. 1980, P.87-90: "Fiber switch of 1 x 93: an experimental trial".

- The switch described in French patent 2521735.

 The use of a displacement of optical fiber however has two drawbacks: on the one hand a lower reliability as a consequence of the embrittlement of the moving fiber (it often undergoes a curvature during the switching operation), and on the other hand, a lower reproducibility of the optical losses between the different channels of the switch because of the precision necessary for the relative positioning of the fibers (in particular the tolerance on the spreading of the fibers which is difficult to achieve simultaneously and without prohibitive cost for a large number of fibers. ).

The second method consists in collimating the beam from the fibers and performing a deflection of this beam of light which has become almost parallel before focusing it on the selected fiber. This method has given rise to numerous embodiments using mechanical switching means; we can cite as examples - an 8 x 8 matrix using retractable pentagonal prisms
MINOWA & Cd, Electronics Letters, Vol 16, NB 11, May 1980, p. 422, 423: "Non-blocking 8 x 8 optical matrix switch for fiber optic communication" - French patent 2,475,343.

- The article by YAMAMOTO & Co, Journal of optical communications 1, 1980, 2, p.74-79 "Large-scale and low-loss optical switch matrix, for optical switching systems".

These devices have the advantage of limiting the mechanical tolerances during the movement of the deflectors since they process parallel beams. However, limitations to their use have appeared, mainly due to their very large geometric size (greater than 12 cm x 12 cm for the 8 x 8 switch of
MINOWA).

 On the other hand, the difficulty of having coupling lenses adapted to all possible optical paths leads to random losses during the cascading of the devices (the diffraction being not negligible, the coupling optics used is a compromise so that the optical losses depend on the couple of fibers chosen). On the other hand, the sensitivity to external disturbances (vibrations for example) of these devices becomes prohibitive for matrices of reasonable size.

 The invention aims to eliminate the main faults of devices using the second method mentioned above, and to allow the production of a 1 x N selector that can be industrialized and mounted in large series.

 The subject of the invention is a 1 x N optical selector with mechanical control, for multimode fibers, for establishing selective couplings between a first optical fiber and a second optical fiber selected from a set of N optical fibers, characterized by the fact that the N optical fibers are arranged in a circle, the first optical fiber being arranged in the center of said circle, each fiber having at the end a lens, and that it comprises means of reflection movable around an axis passing through the center of the circle and perpendicular to a plane containing said circle, and arranged opposite the first optical fiber to reflect on the one hand a light ray leaving the first optical fiber and intended for a second optical fiber and to reflect on the other hand towards said first optical fiber a light beam coming from said second optical fiber.

 The optical selector of the invention has the following advantages: all the optical fibers are fixed, the optical path is minimal and identical for all the positions of the selector, the compactness of the selector is obtained by the use of lenses integrated into the optical fibers, the optical adjustments are made during manufacture.

 The invention will be better understood from the following description of examples of embodiments illustrated by the appended figures in which - Figure 1 schematically represents a first embodiment of an optical selector of the invention, - Figure 2 shows, in elevation and in section, an optical selector in accordance with FIG. 1, - FIG. 3 illustrates a means of optical detection of the position of the selector in FIGS. 1 and 2, for controlling the angular positioning of the selector, - the 4 shows, in elevation and in section, a second embodiment of an optical selector of the invention, - Figure 5 shows, in elevation and in section, a third embodiment of an optical selector of the invention, - Figure 6 shows, in elevation and in section, a variant of the third embodiment of an optical selector.

 FIG. 1 schematically illustrates a first embodiment of an optical selector of the invention, consisting of a set of N optical fibers 1 arranged in a circle C, a central optical fiber 3 arranged in the center of the circle C and a prism 5 with total reflection.

 Each of the N optical fibers 1 as well as the central optical fiber 3 have a lens 2 at their end. The N optical fibers and the central optical fiber are arranged perpendicularly to a plane containing the circle C. The prism 5 is of section in the shape of an isosceles right triangle; it has two isosceles faces and a hypotenuse face 9 parallel to the plane containing the circle C, and arranged along a radius of the circle; one end of the hypotenuse face is facing the central optical fiber 3 and another end facing the circle C, therefore facing an optical fiber 1 when the latter is selected. The prism 5 is movable around an axis X perpendicular to the plane containing the circle C and passing through the center of said circle.

 The selection of an optical fiber 1 from the set of N optical fibers is done by rotation of the prism 5 which ensures an optical path of the light between said selected optical fiber and the central optical fiber, by reflection on its two isosceles faces, this path being minimal and identical whatever the optical fiber selected and whatever the direction of propagation of the light.

 FIG. 2 represents, in elevation and in section, an optical selector in accordance with FIG. 1. The N optical fibers 1 and their lenses 2 are arranged in a circle on a fixed support 6, the central optical fiber 3 and its lens being arranged at center of the circle.

The optical fibers 1 and 3 and the lenses 2 are arranged perpendicular to the upper face 4 of the fixed support 6. A mobile support 7 in the form of a hollow cylinder closed at one end by a base 8, has its axis of revolution coincident with the axis X passing through the center of the circle along which the N optical fibers 1 are arranged.

The cylinder has an inner diameter greater than the diameter of the circle and is placed above the fixed support 6, its open end facing the upper face 4 of the fixed support. The distance between the cylinder and said upper face 4 is of the order of a few tenths of a millimeter, so that there is no contact between the fixed and mobile supports. As an indication, a selector 1 by 16 has a diameter of 16 millimeters; it is therefore very compact.

 The prism 5 is fixed on the base 8 of the mobile support 7, its hypotenuse face 9 being parallel to the upper face 4 of the fixed support 6, above the N optical fibers 1 and of the central fiber 3. An optical path of a light beam between the central optical fiber 3 and any optical fiber 1 is established through the prism 5.

Whatever the direction of this light ray, it enters the prism perpendicular to the hypotenuse face 9, is reflected successively by the two isosceles faces and leaves perpendicularly to the hypotenuse face.

 The base 8 of the mobile support 7 comprises a cylindrical hole 10 in which is mounted an axis of a motor, not shown, of the stepping type, which ensures the rotation of the mobile support 7; the axis of the motor coincides with the axis of the mobile support 7 itself coincident with the axis X perpendicular to the plane of the circle, this plane being that of the upper face 4 of the fixed support 6. The mobile support 7 drives the prism 5 in its rotation which allows the selection of an optical fiber 1 from all of the N optical fibers, these preferably being distributed regularly over the circle.

 The selection of an optical fiber is therefore made by an angular positioning of the prism, positioning produced by the motor. The precision on the angular positioning of the prism relative to the selected optical fiber can be obtained without special device in the case where the precision of the motor corresponds to the characteristics of optical fibers 1 and 3. Indeed according to the envisaged applications the optical loss is minimal if - the output fiber has a numerical aperture at least equal to that of the input fiber, - the output fiber has a core diameter at least equal to that of the input fiber.

 FIG. 3 illustrates a means of optical detection of the position of the optical selector in FIG. 2 for an angular servo-control of said optical selector.

 For this purpose an optical semiconductor detector 11, such as a photodiode, is bonded to one of the reflecting faces of the prism 5 at the place where the reflection of the light ray takes place; these reflecting faces are the isosceles faces of the prism.

 When the prism has turned and is above the selected fiber, the light flux received by the photodiode is maximum; the current delivered by the photodiode is used to control the motor, this current being maximum when the light flux received by the photodiode is itself maximum.

 FIG. 4 shows, in elevation and in section, a second embodiment of an optical selector of the invention. In this figure we find the fixed support 6, the mobile support 7, the central optical fiber 3, and the N optical fibers 1 arranged in a circle on the fixed support 6 dt Figure 2. A prism 15, with total reflection, of section in the form of an isosceles right triangle is bonded, on each of the lenses 2 of the N optical fibers, by an isosceles face; its other isosceles face is on the one hand perpendicular to the plane containing the circle, that is to say to the upper face 4 of the fixed support 6, and on the other hand perpendicular to one. plane passing through the X axis and through the optical fiber 1 on the lens from which said prism 15 is bonded.

The X axis is, as in Figure 2 Irax passing through the center of the circle and perpendicular to the plane containing said circle.

 A prism 16 with total reflection, of section in the shape of an isosceles right triangle, is fixed on the base 8 of the mobile support 7 so that an isosceles face of the prism is parallel to the upper face 4 of the fixed support 6 and opposite of the central fiber 3. The selection of an optical fiber 1 is made by rotation of the movable support 7 driven, as in Figure 2, by a stepping motor.

When an optical fiber 1 is selected, a light ray emitted by the central optical fiber 3 penetrates into the prism 16 perpendicular to the isosceles face opposite said central fiber, is reflected by the hypotenuse face of the prism, comes out perpendicularly from the another isosceles face of said prism 16, penetrates into the prism 15 of the selected optical fiber perpendicular to an isosceles face of said prism, is reflected by the hypotenuse face and exits perpendicularly through the other isosceles face of said prism 15, glued to the lens 2. A light ray emitted by the selected optical fiber 1 follows the reverse optical path.

 FIG. 5 shows, in elevation and in section, a third embodiment of an optical selector of the invention. As in the previous figures, the N optical fibers 1 are arranged in a circle on a fixed support 20 and the central optical fiber 3 is arranged in the center of said circle. In FIG. 5, the fixed support 20 has the shape of a hollow cylinder closed by a base 21; the N optical fibers 1 with their lenses 2 are arranged in the wall of the hollow cylinder in a circle and the central optical fiber is arranged in the base 21, at the center thereof, that is to say along the axis X of the circle-, this axis also being that of the hollow cylinder.

 A mobile support 23, in the form of a disc, has its axis of rotation coincident with the axis X and covers the end of the cylinder of the fixed support 20 without, however, being in contact with said cylinder. A prism 16 is fixed on the disc 23, as in FIG. 4, so as to have an isosceles face parallel to the upper face 24 of the base 21 of the fixed support 20, and facing the central fiber 3. The disc 23 has a hole 10 for fixing the axis of a motor ensuring the rotation of the movable disc 22.

 A light ray emitted by the central optical fiber 3 enters the prism 16 through the isosceles face parallel to the upper face 24, is reflected by the hypotenuse face, and exits perpendicularly to the other isosceles face of the prism 16 in the direction of the lens. 2 of the selected optical fiber 1. A light ray emitted by the selected optical fiber 1 follows the reverse path.

 FIG. 6 represents, in elevation and in section, an alternative embodiment of the third embodiment of an optical selector illustrated by FIG. 5. In this FIG. 6, the N optical fibers 1 and the central optical fiber 3 are arranged, as in Figure 5 on the fixed support 20; the prism 16 is fixed on a base 28 of a movable support 27 in the form of a hollow cylinder having its axis conducted with the axis X, but the outside diameter of the hollow cylinder is less than the inside diameter of the hollow cylinder of the fixed support 20, so that the end of said hollow cylinder of the mobile support 27 comes opposite the upper face 24 of the fixed support 20. The base 28 of the mobile support 27 has one end 29 which projects beyond the wall of the cylinder and extends above the end of the hollow cylinder of the fixed support 20. The path of the light rays is the same as in FIG. 5, however a hole 30 is made in the wall of the cylinder of the mobile support 27 in order to allow the light ray coming from the central fiber 3 to reach the lens 2 of the selected optical fiber 1, and vice versa.

 This embodiment of FIG. 6 allows, with respect to the embodiment of FIG. 5, better protection of the prism 16.

 This third embodiment, FIGS. 5 and 6, only has a rotating prism 16, as in the case of the first embodiment (FIGS. 1 and 2), which limits the adjustments with respect to the second embodiment ( FIG. 4) which requires an adjustment of each of the prisms 15 bonded to the lenses of the N optical fibers 1.

 In FIGS. 4, 5 and 6 it is possible to use an optical detector, as in the embodiment of FIG. 2, glued to the reflecting face of the movable prism around the axis X.

In FIGS. 4, 5 and 6, this reflecting face is the hypotenuse face of the prism 16.

 The invention is in no way limited to the embodiments described and shown, in which any means can be replaced by equivalent means. Thus, in FIGS. 4, 5 and 6, each prism can be replaced by a mirror arranged along the hypotenuse face of the prisms, since said hypotenuse face is the reflecting face.

Claims (6)

1/1 x N optical selector with mechanical control, for multimode fibers, for establishing selective couplings between a first optical fiber and a second optical fiber selected from a set of N optical fibers, characterized in that the N optical fibers (1 ) are arranged in a circle (C) the first optical fiber (3) being arranged in the center of said circle, each fiber comprising at the end a lens (2), and that it comprises reflection means (5) movable around an axis (X) passing through the center of the circle and perpendicular to a plane containing said circle, and arranged opposite the first optical fiber (3) to reflect on the one hand a light ray coming out of the first optical fiber and intended for a second optical fiber (1) and to reflect on the other hand towards said first optical fiber (3) a light ray coming from said second optical fiber (1). 2 / optical selector according to claim 1, characterized in that the first optical fiber (3) and the N optical fibers (1) are arranged perpendicular to the plane containing said circle, and that said reflection means are constituted by a prism ( 5) with total reflection, of section in the form of an isosceles triangle having two isosceles faces and a hypotenuse face (9) parallel to the plane containing said circle, said hypotenuse face having an end situated opposite the first optical fiber (3) and a another end opposite the circle, said prism establishing an optical path between the first and second optical fibers by reflection of light rays on its two isosceles faces. 3 / optical selector according to claim 1, characterized in that the reflection means consist of a prism (16) with total reflection, of section in the shape of an isosceles right triangle, having two isosceles faces and a hypotenuse face, that an isosceles face of said prism is parallel to the plane containing said circle and opposite the first optical fiber (3), that the first optical fiber (3) and the N optical fibers (1) are arranged perpendicular to said plane, which it comprises second reflection means on each of the lenses (2) of the N optical fibers (1), said second means being constituted by prisms (15) with total reflection, of section in the form of an isosceles triangle, having two isosceles faces and one face hypotenuse, and that each prism (15) of said second means is glued to a lens (2) by an isosceles face and to its other isosceles face perpendicular on the one hand to the plane containing said circle and on the other hand to a plane passing through said axis (X) and through the optical fiber (1) on the lens from which it is glued, an optical path between the first and second optical fibers being established by reflection of light rays on the hypotenuse faces of the prisms of the first and second means of reflection. 4 / optical selector according to claim 1, characterized in that the N optical fibers (1) are arranged radially in the plane containing said circle, that the first optical fiber (3) is arranged perpendicular to said plane below the latter , and that the reflection means consist of a prism (16) with total reflection, of section in the shape of an isosceles right triangle, having two isosceles faces and a hypotenuse face, said prism having an isosceles face parallel to said plane and located between said plane and said first optical fiber (3) facing the first optical fiber, said prism establishing an optical path between the first and second optical fibers by reflection of light rays on its hypotenuse face. 5 / optical selector according to one of claims 1, 2, 3 and 4, characterized in that the reflection means are driven in rotation by a stepping motor having an axis of rotation coincident with the axis (X) around which said reflection means are mobile. 6 / optical selector according to one of claims 2, 3 and 4, characterized in that an optical detector (11) is stuck on a reflecting face of the prism constituting the reflection means, said optical detector being constituted by a photodiode and used for positioning said reflection means when selecting one of the N optical fibers, and receiving a maximum light flux when the positioning is correct.