FR2580411A1 - Fibre-optic coupling and splitting device - Google Patents

Abstract

A body 1 having a hollow internal volume 4 has a first wall 2 having means for receiving and for holding the outermost part terminated by an outermost face 3 of optical fibres F1, F2, etc., one F1 of which is an input fibre whereas the opposite wall 5 contains a plurality of mirrors or concave spherical mirror fractions 6A, 6B which each form an image of the first fibre F1 on a respective second fibre F2, F3.

Description

invention relates to a device whose role
+ neck @ lar at least a first optical fiber leading u @ light beam to several other optical fibers between which the G beam is divided
We know in this field, from document USA 4 329 917. a coupling device between optical fibers @@@ @ Le mede @@@@. In this device, the essential part is an @ oc of solid, transparent material, with an index of
an eraction similar to that of the revau of optical fibers. These are introduced over a shallow depth into the block @ @ p @ ir from one of its faces and the opposite face is insurved like the face d 'a spherical mirror. In addition, this
@@@ @@ c spherical monk can be made to present @cnteurs with spherical surface similar to parts of
that is to say starting from a central point of the face.

 They have different centers of curvature so that the image @@ your end face of an incoming fiber is formed by a respective corresponding @@@ eur on the end face of an output fiore. As we said, this block is a d @ @n block and it must be made of material identical from the point of view o ical to that CU fiber core.

 Document USA 3 883 223 also discloses a coupling device composed of a hollow body having a plane face in which are arranged all the end faces of the fibers and an opposite face constituted by a mirror, preferably spherical. The latter forms on all of the end faces of the fibers the image of the end face of any fiber considered to be the incoming fiber. It is recommended that the volume of the hollow body be filled between the faces of the optical fibers and the mirror of a flunde with a suitable index.

 In a coupling device comprising a hollow body with a first wall provided with receiving means ex for holding in position an end part of a bundle of more than two optical fibers each terminated by an end face and a second wall opposite to the first wall, according to the invention, this second wall contains several mirrors or fractions of concave, spherical mirror, each mirror or fraction of mirror forming the image of the end face of at least one first fiber on the end face of at least one second corresponding fiber.

 The invention engLobe the case where the number of mirrors or mirror fractions is equal to the number of second fibers, each mirror or fraction of mirror forming the image of the end face of your first fiber on the end face of a single corresponding respective second fiber.

 The mirror fractions are sectors when the neutrality of the modal device is sought; they are segments when, on the contrary, it is desired to produce a filtering effect on the modes of propagation of the beam coming from the first fiber.

In a particular case of realization, to distribute with a filtering effect on the modes a beam
Luminous coming from a first fiber on several second fibers, the second wall carries several circular concave spherical mirrors of decreasing diameters arranged one inside the other with their vertices aligned on the axis of the light beam coming from the first fiber. The radii of curvature of these mirrors are provided and their axes are oriented so that each of them forms the image of your end face of the first fiber on the end face of one or more second fibers.

In this case, it is equivalent to using spherical concave mirror fractions which are annu
Laires arranged around a common vertex located on the axis of the light beam from a first fiber.

 The invention also covers the case of a body with multiple cavities, each provided with their means for receiving the fiber terminations and with their spherical mirrors or fractions, thus constituting an optical terminal block for the applications, ie distribution of the luminous signaL requiring upgradeable connectivity.

 IT is planned, as part of the invention, to interpose between the first wall and the second wall of the body an auxiliary element acting on the Light, a prism of small angle for example, allowing to operate from the first fiber a progressive transfer of the luminous flux between a group of second fibers to another group of waves, thus re-reading a progress switch, or, in other words, a coupler with adjustable partition coefficients by displacement of the element deviator.

 It is also possible to use as an auxiliary element interposed between the first wall and the second wall of the body, an attenuating element or a diaphragm with variable opening so as to influence the level of optical power transmitted to the second fibers. A variable attenuation is thus produced on the internal channel (s) of the coupler.

We will now give, without limiting intention and without excluding any variant, a description of several preferred embodiments. Reference is made to the accompanying drawings in which
- Figure 1 is a sectional view through a longitudinal plane of a spherical mirror device divided into fractions according to the invention;
- Figures 2, 3, 4, 5 are front views of spherical mirror fractions showing various arrangements of these fractions;
- Figures 6 and 7 are respectively simplified side and front views of an exemplary embodiment of a coupler with several mirrors having a filtering effect
- Figure 8 is a perspective view of a body with multiple cavities each with their means for receiving and holding the optical fibers and their spherical mirror fractions, thus constituting an optical terminal block for optical signal distribution applications requiring evolving connectivity;
- Figure 9 is a view similar to Figure 1 without the body of the device, showing The use of an auxiliary element interposed between the wall carrying mirror fractions and the wall carrying the ends of the fibers;
- Figures 9a and 9b are similar front views showing spherical mirror fractions and an auxiliary element;
- Figures 10 to 12 are views analogous to Figure 9 but showing in perspective other auxiliary elements,
Figure 13 is a front view of an auxiliary element placed in front of a concave spherical mirror;
- Figure 14 illustrates a practical embodiment of a coupling device according to the invention.

 Reference will first be made to FIG. 1 to describe the simplest example of embodiment of a device according to the invention; one can see a device which body takes a body 1 having a first wall 2 in which are provided channels or grooves, or equivalent means for receiving and holding an end portion of several optical fibers F1, F2, F3 , ... which each end with an end face 3. These end faces 3 are arranged in the same plane transverse to the longitudinal dimension of the fibers, inside a hollow volume 4 formed in the body 1. The wall 2 could be partially removable or opening to facilitate the establishment and fixing of the optical fibers F1 to F3.

 Opposite the first wall 2, the body 1 has a second wall 5 which contains two fractions 6A, 6B of a concave spherical mirror whose concavities are turned towards the end faces 3 of the optical fibers. Each mirror fraction 6A, 6B is arranged and oriented for / image of the end face 3 of a first fiber F1 considered as input fiber on the end face 3 of a second corresponding fiber respectively F2, F3 considered as fiber of exit. Consequently, the mirror fractions 6A, 6B are not arranged with a single common optical axis but they have different optical axes.

 Figures 2 to 5 show that fractions 6A, 6B, 6C, 6D can be equal (Figures 2 and 3) or different (Figures 4.5): in addition, the mode of dividing the mirror into fractions can be done in two great ways piffé rentes.

 The fractionation according to rays giving sectors with common point centered on the axis of the light beam coming from a first optical fiber respects the natural symmetry of the modes of propagation in the modal mufti fibers; a coupling device free of modal effect is then obtained for this type of fibers; in other words, the sharing coefficients of the light beam between the various second starting fibers are the same for all the propagation modes whatever the order.

 On the contrary, the splitting according to strings, illustrated by FIG. 5, introduces an intentional filtering effect. The fraction 6B of the mirror of this FIG. 5 reflects and transfers in a preferential manner to the second fiber with which it is associated the high order modes only.

 Consequently, the device of the invention has the advantage of having the same transfer efficiency for all the propagation modes whatever the order, but it also makes it possible to easily modify certain parameters of the light beam during its transfer, like optical power, the phase of single-mode beams, the modal content of multimode beams.

 FIG. 6 relates to another aspect of the invention according to which the second wall 5 contains several whole spherical mirrors. A first main concave spherical mirror 6 'contains a second smaller concave spherical mirror 6 "which still contains a third even smaller concave spherical mirror 6"'. These three mirrors 6 ', 6 ", 6"' are placed in each other with their vertices S1, S2, S3 located on the same straight line but their optical axes are not confused. Each mirror receives the incoming optical beam by the end face of a first incoming fiber F1, the mirror 6 'returns the image of this end face on the end face of a second starting fiber F3, the mirror 6 "returns it to the end face d 'another second starting fiber F2, the mirror 6 "' returns it to the end face of another second starting fiber F4.

 We thus succeed in obtaining a filtering effect of the propagation modes in addition to the transmission and the distribution of the light beam arriving by the first central incoming fiber F1.

 As Figure 7 suggests, it would be equivalent to use Instead of these mirrors contained one inside the other mirror fractions which would be annular fractions arranged around a common vertex SO located on the axis of the beam from of the first F1 fiber.

 In the spirit of the invention, iL is intended to use, as Figures 9, 9a, 9b, 10 to 13 show, a body 1 having in a side wall an opening through which one can slide an auxiliary element in order to interpose it in an adjustable way on the path of the optical beam.

FIGS. 9, 9a and 9b show the example, as an auxiliary element, of a small angle prism 9 which varies according to its position the distribution between the second starting fibers of the beam returned by a fraction of mirror 6. FIGS. 9a , 9B show that the prism 9 is used with several fractions 6A, 6B, 6C of a concave spherical mirror.

In this example, the planes of separation of the fractions of the mirror are perpendicular to the edge of the apex of the prism 9.

The device of the invention then behaves like a coupler with a variable partition coefficient without causing appreciable additional losses. The device can be a Leur blow in Y at an arrival fiber F1 and two departure fibers F2, F3 (Figure 9) or a Leur blow in star at an arrival fiber and four departure fibers.

It is then possible by moving the prism 9 to gradually switch the light beam from a first group of starting fibers to a second group of starting fibers.

 The auxiliary element interposed between the mirror (s) and the fibers, may be a photometric wedge 10 (FIG. 10) whose attenuation in decibels is a linear function of its displacement in transverse direction as indicated by a double arrow F.

 The auxiliary element adjustable in position can be a diaphragm of the plate type with an opening of increasing width II (FIG. 11), displaceable gradually by translation or by rotation depending on whether this plate is tangent or circular. In this case, it is the attenuation in power which is a linear function of its displacement in the direction of the bisector of its acute angle at the top. The two equal sides 12A, 12B of the triangle can be deformed to produce compensation for the non-uniform distribution of the optical power density on the mirror 6.

 The auxiliary element can be a zains diaphragm 13 (FIG. 12) allowing in another way the attenuation in optical power of the light beam. This attenuation can be combined with a selection of the starting fibers.

 Figure 13 shows that in front of mirror fractions one can interpose an auxiliary element such as The prism 9 of Figure 9 and a diaphragm 14 having a louver ture whose edge profile has been determined to establish a desired law of variation of the beam distribution coefficient as a function of the displacement of this prism 9.

 Instead of being rectilinear and moving on a rectilinear path, the auxiliary element could be circulated Lary and it could be moved by rotation around an axis.

 A coupler and divider device in accordance with the invention is simple, easy to construct from common elements. It is estimated that, without special precautions, it can be the cause of a loss of less than 30 X (- 1.5 dB); if it is manufactured with care, using treated elements (anti-reflection treatment of the ends of the optical fibers, treatment of the metallization of the mirrors) assembled with precision, the loss would be approximately 10 x (-0.5 dB).

 Figure 14 illustrates a practical embodiment of a device according to the invention.

 The body 1 is divided over a fraction of its length into a main part 1A and into two secondary parts 1B, 1C. In the secondary part 1C is dug approximately half of a part of the volume 4; The other half of this part is hollowed out in the main part 1A and the rest of the volume 4 is hollowed out in the fraction of the main part of the hollow body which is not divided. This volume 4 opens out through an opening 4A in the end face of the fraction not divided in two of the main part 1A.

In this opening 4A can be introduced and fixed, for example by bonding, fractions of plugs 16, 17 which each have a stop shoulder 18. Each fraction of plug 16, 17 carries a fraction of mirror 6A, 6B. In contrast, the volume 4 is followed, in the main body 1A only, by a U-shaped channel 19 able to contain just the extreme parts of the optical fibers F1, F2, F3 ... This channel 19 is closed by the part secondary 1B when this has been installed on the main part 1A. The U-shaped channel 19 opens into a half-housing 20 which corresponds in the secondary part 1B to an identical half-housing 21. These half-housings 20, 21 are intended to contain the end part of the sheath which surrounds the optical fibers.

 When the fibers F1, F2, F3 ... have been placed in the U-shaped channel 19 and immobilized by the installation of the secondary part 1B, the position of the mirror fractions 6A, 6B is adjusted by observing the position of the point luminous reflected by these mirror fractions on the extreme faces of optical fibers. An adhesive thickness of a few tenths of a millimeter is sufficient to allow, before it is hardened, the desired orientation corrections of the half-caps 16, 17. After the glue has hardened, the secondary part 1C is put in place.

 Returning to FIG. 8, one can see an optical terminal block 22 comprising a body 23 having at least one row of successive cavities 24 capable of each containing an end part of a device such as the one in FIG. 14. In this example , to each device arrives a first arrival fiber F1 which conducts an optical beam transmitted to two second departure fibers F2, F3.

Claims (12)

 1. Device for coupling and dividing a beam between a first optical fiber and at least two second optical fibers, having a hollow body (1) with a first wall (2) provided with means for receiving and holding in position a end part of several optical fibers (F1, F2 ...) each terminated by an end face (3), and a second wall (5) opposite to the first wall (2), providing an empty volume between them (4), characterized in that this second wall (5) contains several mirrors (6 ', 6 ", 6"') spherical concaves or fractions (6A, 6B, 6C ...) of spherical concave mirror facing the end faces of said optical fibers , each mirror or fraction of mirror forming the image of the end face (3) of at least one first fiber (F1) on the end face (3) of at least one second fiber (F2'F3 ...) .  2. Device according to claim 1, characterized in that the mirror fractions (6A, 6B, 6C ...) are sectors with a common point centered on the axis of the Light beam coming from the first fiber (F1), providing thus sharing coefficients independent of the modal content of the beam from this first fiber (F1).  3. Device according to claim 1, characterized in that the mirror fractions (6A, 6B, 6C ...) are segments of a sphere, which accentuates the dependence of the sharing coefficients of the coupler with respect to The order of the modes of propagation of the beam from the first incoming fiber (F1) and provides a modal filtering effect. The beam axis from the first fiber (F1).  4. Device according to claim 1, characterized in that The fractions (6 ', 6 ", 6"') are annu Lary fractions arranged around a common vertex (SO)> located on  5. Device according to claim 1, characterized in that the second wall (5) carries several concave spherical mirrors (6A, 6B, 6C ..) of decreasing diameters, including The vertices (S1, S2, S3 ...) are aligned, each mirror forms the image of the extreme face (3) of a first arrival fiber (F1) on the extreme face of one of the seconds starting fibers (F2, F3, F4 ...) in order to produce an intentional modal filtering effect on the light beam from the first fiber (F1).  6. Device according to claim 1, characterized in that it comprises a body (23) with several cavities (24) each capable of containing a device according to any one of claims 1 to 5.  7. Device according to one queLconque of claims 1 to 6 characterized in that the body (1) has a side wall having an opening through which is introduced at an adjustable position an auxiliary element such as a photometric wedge (10) straight or circular causing variable attenuation simultaneously on all of the coupler's output channels.  8. Device according to any one of claims 1 to 6, characterized in that the body (1) has in its side wall an opening through which is introduced at an adjustable position a deflecting element. Light, such as a prism (9), of small angle, whose bisecting plane is perpendicular to the axis of the beam coming from the first fiber (F1), making it possible to gradually switch the light beam from a first group of seconds starting fibers to another group of second fibers, each of these groups being composed of a single second fiber.  9. Device according to any one of claims 1 to 6, characterized in that an adjustable opening diaphragm is interposed between the wall (5) carrying the mirrors (6 ', 6 ", 6"') or fractions of mirror (6A, 68.6C ...) and the end faces (3) of the filters.  10. Device according to claim 9, characterized in that the diaphragm is of the iris type C13) centered on the axis of the light beam coming from the first fiber (F1) allowing any desired simultaneous attenuation of the beam directed onto the second fibers .  11. Device according to claim 9, characterized in that the diaphragm (11) is of the opening type (12A, 12B) of increasing width gradually displaceable allowing a selection of the second fibers.  12. Device according to claim 1, characterized in that the hollow body (1) is divided over a fraction of its length into a main part (1A) and into two secondary parts (1B, lC), in the secondary part (1C ) is dug about half a part of the volume The other half of said part is dug in the main part (1A) and the rest of the volume (4) is dug in the fraction of the hollow body (1) which is not divided, this volume (4) opening into The end face of this fraction not divided by an opening (4A) closable by plug fractions (16,17) each intended to carry a mirror fraction (6A, 6B),