FR2590369A2 - Fibre-optic coupler and splitter device - Google Patents

Abstract

The optical fibres F1, F2, F3, have an end portion F'1, F'2, F'3 each having an axis 25, 26, 27 and these axes are in the same plane P, whereas the mirror 6 is split into parts 6A, 6B, each having at least one transverse edge 28, 29 on the side of the optical fibres; these transverse edges 28, 29 are parallel to the plane P, which has the effect of orienting, perpendicularly to this plane P, the diffraction patterns of the light beam which are produced by the transverse edges 28, 29.

Description

 The main patent relates to a device which makes it possible to couple at least a first optical fiber conducting a light beam to several other optical fibers between which this beam is divided using a fractional mirror.

 The present invention relates to improvements made to this coupling device with the aim on the one hand of greatly reducing if not completely eliminating the risk of undesirable return of light on the end end face of the optical fiber or fibers. arrival of the light beam, on the other hand to facilitate the optical switching between the arrival fiber or fibers of the light beam and the output fiber or fibers of this beam.

 In a coupler and divider device comprising a first optical fiber and at least two second optical fibers, with these optical fibers each terminated by an end part with an end end face, also comprising a spherical concave mirror divided into at least two parts each having at least a transverse edge, the end portions of the fibers being arranged with their respective axes situated in the same plane with their end end faces placed opposite the mirror for the realization of an optical connection between them by means of this mirror, according to l invention the transverse edges of said parts of the mirror are arranged parallel to the plane containing the axes of the end parts of the fibers.

 Preferably, the mirror is divided into two substantially equal parts.

 As described in the main patent, a coupler and divider device can comprise a prism movable in position which can be interposed between the fractional mirror and the fibers in order to modify the distribution of the beam between the first optical fiber and the second optical fibers. .

 According to the present invention, it is particularly advantageous to mount this prism with the possibility of pivoting around a pivot perpendicular to the plane containing the axes of the end portions of the optical fibers.

 When the mirror is split into two parts with the transverse edges of the latter parallel to the plane containing the axes of the end parts of the fibers, as defined above, the pivot then has a position orthogonal to these transverse edges.

 However, it is understood that the pivoting mounting of the prism using a pivot perpendicular to the plane of the axes of the fibers can also be used with a mirror divided into two parts whose transverse edges are not parallel to this plane, or divided into more than any two parties.

A description will now be given of several exemplary embodiments of the present invention. Reference is made to the accompanying drawings in which
FIG. 1 is a simplified general perspective view of a coupler and divider device with a mirror divided into two parts according to the invention,
FIG. 2 is a view of the terminal end faces of the fibers of the device in FIG. 1 used to explain the advantages of the invention,
- Figures 3 to 5 are simplified general side views of a coupler and divider device with movable prism by pivoting according to the invention with different positions of the prism and with two different lengths of this prism.

 The device shown in Figure 1 has been schematically drawn so that the characteristic of the invention is more clearly visible there. For a more complete representation of the device one can refer to Figure 1 and, even better, to Figure 14 of the main patent.

In this FIG. 1, the device comprises three optical fibers F1, F2, F3 in which a first fiber F1 and two second fibers F2 can be distinguished,
F3. These three fibers each have an extreme part F'1, F'2,
F'3 respectively with a respective end end face 3. These three extreme parts F'1, F'2, F'3 each have a geometric axis, 25, 26, 27 respectively. These axes 25, 26, 27 are contained substantially in the same plane P symbolized by a rectangle drawn in phantom.

 This device also comprises a spherical concave mirror 6 divided into two equal parts 6A, 68 on either side of a transverse plane which preferably passes through the apex S of the mirror 6 before it is cut into two parts. This mirror 6 is arranged in the device in regard to the end end faces 3 to ensure their optical connection. On the side of these end faces 3 each mirror part 6A, 6B has a transverse edge 28, 29 respectively.

These two transverse edges 28, 29 are arranged parallel to the plane P. It will be noted that this arrangement is obtained when the two parts 6A, 68 of the mirror are contiguous, the edges 28, 29 being practically merged together in the plane P. It is obtained also when these edges 28, 29 are merged together outside of the plane P, or when the two parts 6A, 6B are spaced from each other on either side of the plane P, at symmetrical or non-symmetrical positions compared to the latter.

The invention does not require that the mirror 6 be
splits into two equal parts 6A, 68. The parts of the mirror can be unequal in size. In addition, the mirror may be split into more than two parts; The invention is also applicable in this case provided that the planes of separation of the various parts are parallel planes; the same part can then have two transverse edges on the side of the optical fibers. All the transverse edges are arranged parallel to the plane P defined above.

The arrangement defined above of the transverse edges 28, 29 has the effect of orienting the diffraction pattern of the light beam produced by these transverse edges 28, 29. The orientation is made perpendicular to the transverse edges 28, 29, therefore perpendicular to the plane P as it has been drawn at 30 and 31 in FIG. 2, in relation to the terminal end faces 3 of the second fibers F2,
F3. In this way, it is avoided that the diffraction figures 30, 31 encroach on the end end face 3 of the first fiber F1. One therefore eliminates a possible cause of light returning to the first optical fiber F1 which is assumed here to be the incoming fiber of the light beam. The same orientation effect would play with respect to the starting fiber F1 by protecting the fibers F2, F3 if these were the arrival fibers of the light beam.

Figures 3 and 4 show a mirror 6, which can be split into two parts as in Figure 1, arranged opposite the end faces 3 of optical fibers 1 FZ, F3. This device is used to switch between one or
The other of the fibers F2, F3 a fraction of a light beam which arrives through the fiber F1. A deflecting prism 9 is pivotally mounted near the mirror 6 using a pivot 32 which is orthogonal to the plane (not shown in FIGS. 3 to 5, which contains, as in FIG. 1, the axes of the end parts fibers F1, F2, F3.

 The deflecting prism 9 is movable by pivoting between an inactive position (Figure 3) and an active position (Figure 4). At the inactivity position of the prism 9, the light beam is reflected by the mirror 6 from the fiber F1 to the fiber F2. At the position of activity of the prism 9, in which it extends in front of the mirror 6 over half the width of the latter, a fraction of the light beam, coming from the fiber F1 and reflected by the mirror 6, is deflected to F3 fiber.

 In FIG. 5, the deflecting prism 9 ′ is pivotally mounted around a pivot 32 as in the case of FIGS. 3 and 4 but it has a length equal to the width of the mirror 6.

When it occupies its inactive position (shown in phantom), the entire beam coming through the fiber F1 is returned by the mirror 6 on the fiber F2. When the prism 9 'is put in its activity position where it is drawn in solid lines, the entire light beam is deflected on the fiber F3.

 The useful length of the deflecting prism 9 or 9 'can be chosen, relative to the mirror 6, to a value which is less than or equal to the width of the latter depending on the size of the fraction of the light beam which it is desired to modify. the path. In the example illustrated in FIG. 3, the device acts as a simple connector between the fibers F1 and F2 since the prism 9 is not used. In the example of FIG. 4, it plays the role of Thres hit in Y between the fibers F1, F2 and F3. In the example of FIG. 5, the device is an optical switch which makes it possible to completely transfer the light beam between one and the other of the fibers F2, F3.

Claims (4)

 1. An optical beam coupler and divider device according to claim 1 of the main patent comprising a first optical fiber (F1) and at least two second optical fibers (F2, F3), each terminated by an end part (F'1, F'2, F'3) with end end face (3), said three end parts having their respective axes (25, 26, 27) located in the same plane (P), a spherical concave mirror (6) at least split in two parts (6A, 68) each having on the side of the fibers (F1, F2, F3) at least one transverse edge (28, 29), characterized in that the transverse edges (28, 29) of the parts (6A, 68 ) of the mirror (6) are arranged parallel to the plane (P) containing the axes (25, 26, 27) of the end portions (F'1, F'2, F'3) of the optical fibers.  2. Device according to claim 1 characterized in that the mirror (6) is divided into two substantially equal parts (6A, 6B) arranged opposite three optical fibers (F1, F21 F3).  3. Device according to claim 8 of the main patent comprising a movable prism between a position of inactivity and a position of activity, characterized in that this prism (9, 9 ') is pivotally mounted around a pivot (32 ) perpendicular to the plane (P) containing the axes of the extreme parts of the optical fibers (F1, F21 F3).  4. Device according to claim 3 characterized in that the pivoting prism (9, 9 ') has a useful length which is between a lower value and a value equal to the width of the mirror (6).