FR2586305A1 - Bidirectional coupler for fibre-optic linkage - Google Patents

Abstract

Bidirectional coupler for fibre-optic linkage. It comprises an optical fibre, a bidirectional coupler of which, for fibre-optic linkage, comprising an optical fibre whose end is cut with a bevelled plane face, a light-emitting (photoemission) diode 4 and a light-receiving (photoreception) diode 5. In a plane containing the axis XX' of the fibre and the normal NN' to the bevelled plane face, the angle a made by the line, in the said plane, of the said bevelled plane face with the axis XX' of the fibre is between 35 degrees 12 minutes and 35 degrees 48 minutes.

Description

Bidirectional coupler for fiber optic connection
The present invention relates to a bidirectional coupler for connection by optical fibers.

 There is known an active bidirectional coupler comprising a beveled optical fiber at one of its ends to which are optically coupled a light emitting diode emitting a light signal of a wavelength said to go intended to be transmitted in one direction by the fiber and a light-emitting diode of a light signal of a so-called return wavelength transmitted in the other direction by the fiber, the light-emitting diode being positioned spatially with respect to the bevelled end of the fiber so that the light signal at the wavelength to go is coupled to the fiber as much as possible.

 An object of the present invention is to define the values of the angles between the axis of the fiber and the axis of the light-emitting and light-receiving diodes to obtain the best coupling conditions.

 Another object is to produce a coupling box to allow the rapid installation and at optimal angles of the emitting and receiving diodes.

 The subject of the invention is a bidirectional coupler for optical fiber connection comprising an optical fiber the end of which is cut along a bevelled flat face, a light emitting diode and a light receiving diode, characterized in that in a plane containing the axis of the fiber and the normal to the bevelled flat face, the angle (a) formed by the trace in said plane of said bevelled flat face with the axis of the fiber is between 35 degrees 12 minutes and 35 degrees 48 minutes, l angle formed by the emission axis of the light emitting diode with the fiber axis is between 19 and 23 degrees, the emission axis being located in the acute angle formed by the fiber axis and the trace of the flat face of the bevel, the angle formed by the receiving axis of the photoreceptor diode being between 3 and 7 degrees, the receiving axis and the emission axis being located in the same quadrant formed by the axis of the fiber and its normal.

 The invention also relates to a bidirectional coupler for optical fiber connection, comprising a fiber the end of which is cut along a bevelled planar face, a light emitting diode and a light receiving diode characterized in that, in a plane containing the axis of the fiber and the normal to the bevelled flat face, - the angle formed by the trace in said plane of the bevelled flat face with the axis of the fiber is between 311 degrees 30 minutes and 35 degrees 6 minutes, - l angle formed by the emission axis of the light emitting diode with the normal to the fiber is between 26 and 30 degrees, this angle being counted relative to the normal to the fiber so that the emission axis is on the side of the fiber with respect to the bevelled flat face, - the angle formed by the receiving axis of the light-receiving diode is between 26 and 30 degrees, the receiving diode being placed in the acute angle formed by the axis of the fiber and the trace of the bevelled flat face.

 The invention also relates to a bidirectional coupler for optical fiber connection, comprising an optical fiber, a light emitting diode and a light receiving diode, characterized in that it comprises a parallelepipedic housing having an upper face, a lower face and four lateral faces, said housing having a cavity opening on the upper face and in communication by three passages with respectively three lateral faces, the first passage receiving an element traversed by an optical fiber whose beveled end is in the cavity? the second passage, of circular section, receiving a light emitting diode enclosed in a partially spherical room, the third passage being of circular section and opening on a lateral face adjacent to that where the second passage opens, and receiving a photoreceptive diode enclosed in a room partially spherical, the upper face of the housing being provided with a groove communicating, through holes, with the two passages with circular sections and extending up to the fiber-carrying element, the fiber being oriented parallel to the upper faces and bottom of the housing and to two of its lateral faces, the angle formed by the axis of the second passage with the axis of the fiber being close to 21 degrees, the angle formed by the axis of the third passage with the normal to the fiber being close to 5 degrees, the angles being counted so that the axes make an angle of 64 degrees between them and that the diodes are on either side of the plane of the bevel of the fiber.

 The invention also applies to a bidirectional coupler for fiber optic connection, comprising an optical fiber, a light emitting diode and a light receiving diode, characterized in that it comprises a parallelepipedic casing having an upper face, a lower face and four lateral faces, said housing having a cavity opening on the upper face and in communication by three passages with three of the lateral faces, the first passage receiving an element traversed by an optical fiber whose beveled end is in the cavity, the second passage, of circular section, receiving a light emitting diode enclosed in a partially spherical part, the third passage being of circular section and opening on a side face adjacent to that where the second passage opens, and receiving a photoreceptive diode enclosed in a partially spherical part, the upper face of the shoemaker being provided with a groove communicating by holes with the two passages with circular sections and extending to the fiber-carrying element, the fiber being oriented parallel to the upper and lower faces of the shoemaker and to two of its lateral faces, the angle formed by the axis of the second passage with the axis of the fiber being close to 28 degrees, the angle formed by the axis of the third passage with the normal to the fiber being close to 28 degrees, the angles being counted so that the axes form a 90 degree angle and the diodes are on either side of the plane of the fiber bevel.

 The invention will be better understood from the description below made with reference to the appended drawing in which - FIG. 1 is a schematic view of a coupler according to the invention favoring transmission, - FIG. 2 is a schematic view of 'a coupler according to the invention, favoring reception, - Figure 3 is a perspective view of a housing for coupler according to the invention, of the type favoring transmission, - Figure 4 is a top view of the housing of Figure 3, - Figure 5 is a sectional view of the coupler of Figures 3 and 4 provided with its diodes, - Figure 6 is a top view of a housing for coupler favoring reception, - Figure 7 is a sectional view of the housing of Figure 6, showing the diodes with which it is provided.

 To obtain the best coupling, the angles between the axis of the optical fiber and the emitting diodes must have a precise value, within a given range of adjustment.

 It is possible to privilege either the emission or the reception.

 When a coupler is used to equip a user station, reception is encouraged. If on the contrary the coupler equips a central, it promotes the emission.

 FIG. 1 is a coupler diagram for a central office, in which the transmission is considered to be preponderant compared to the reception. In the figure, reference 2 designates an optical fiber comprising a core-cladding assembly 2A and a protective cladding2B.

The end of the fiber is stripped and cut at a bevel at an angle a with the normal NN 'to the axis XX' of the fiber. The plane of the drawing in FIG. 1 is a plane passing through the axis of the fiber and containing the normal No to the section plane of the fiber.

 The emission is ensured by means of a light-emitting diode 4 emitting in a direction, which in the plane of the drawing, makes an angle b with the axis XX '.

 The reception is ensured by a photoreceptor diode whose axis makes in the plane of the drawing, an angle c with the normal to the axis of the fiber.

According to the present invention, the angle a is 350 30 '+ 18'
b is 210 + 20
c is 50 + 20
The angle b is counted in such a way that the direction of emission is located in the acute angle formed by the direction XX 'and the trace of the bevel.

 The angle c is chosen so that the direction R of reception is in the same quadrant formed by the lines NN 'and XX' as the direction E.

 Figure 2 is a block diagram of a coupler used in a subscriber installation where reception is preferred over transmission.

 The same elements have been given the same reference numbers. The bevel made with the normal NN 'to the axis XX' of the fiber, an angle a 'equal to 340 48' t 18 '. The axis E 'of the emitting diode makes an angle b' with the normal NN 'to the axis XX' of the fiber, equal to 280 - 2 '.

 The angle b 'is counted with respect to the straight line NN' normal to the axis of the bevel and passing through the center of the bevel so that the emitting diode is on the side of the fiber with respect to the plane of the bevel.

 The axis R 'of the receiving diode 5A makes with the axis XX' an angle c 'equal to 280 + 20.

 The angle c 'is measured so that the receiving diode is in the acute angle formed by the trace of the bevel and the axis XX'.

 To easily implement the aforementioned diagrams and in particular to position the various constituent elements simply but precisely, a box such as that shown in Figures 3 to 5 is used. The box shown in Figures 3 to 5 is a boftier intended for equipping a central office.

 The case is a molded parallelepipedic block (either in metal such as aluminum, or in a plastic material).

 The housing 1 has an upper face 2, a bottom 3, two large lateral faces 4 and 5 and two small lateral faces 6 and 7. A cover 7 is provided for covering the upper face 1 and being fixed there by screwing or gluing.

 The housing has a cavity 10 which opens on the upper face 2.

 This cavity 10 also opens on the face 6 by a passage 9 receiving a cubic part 11 pierced through and through to allow the passage of an optical fiber 12 held by means of a protective sleeve 13. The fiber crosses the block along a straight line joining the center of two opposite faces of the cube.

 The passage has a well-erected square section so that, after the cubic element 11 has been put in place, the fiber is rigorously pependicular to the face 6 of the housing.

 A passage 14, of circular section, communicates the face 7 of the shoemaker with the cavity 10. This passage serves as a housing for a light emitting diode 15, the emission of which is received on the bevelled end of the fiber.

 The passage has an axis E parallel to face 1 and making an angle b to 210 with the axis of the fiber (as indicated with reference to FIG. 1).

 The diode is partially coated in a part 15A in the form of a portion of a sphere or ball joint, of diameter equal to that of the passage.

 An easy adjustment of the angular positioning of the diode relative to the fiber is thus possible, within the range indicated above.

 A second passage 16, of axis R1, of circular section, opens on one side into the cavity 10 on the other on the face 4 of the housing 1.

 This passage is intended to receive a receiving diode 17 also provided with a ball joint 17A.

 The angle that the axis R1 makes with the normal to the axis of the fiber is equal to 5 degrees. The ball joint allows a deflection of t 2 degrees around this value. The axes E and R1 thus form between them an angle close to 64 degrees, the transmission and reception axes being on either side of the trace of the plane of the bevel.

 The face 2 of the housing is provided with a groove 20. The cube is also provided with grooves on its faces not crossed by the optical fiber.

These grooves are referenced 11A, 11B, 11C.

 The groove 20 communicates by a passage 21 with the passage 14 and by a passage 22 with the passage 16.

 The housing is used in the following manner - after placing the fiber, suitably bevelled and oriented in the cube 11, the cube is inserted in the notch of the bolier, - the diodes are placed in the respective passages and they are oriented to obtain the best coupling, - the cover 8 is placed on the face 2 of the housing, - the cube and the diodes are immobilized in position by running, through the hole 8A of the cover into the groove 20, a very fluid adhesive such as '' a cyanoacrylate which sets quickly and without shrinkage.

 The adhesive travels along the groove 20 and will immobilize the diode 15 through the passage 21, the diode 17 through the passage 22 and the cube 11 by flowing along the grooves 11B and 11C.

 The excess of glue can be eliminated by passing through the hole 24 connecting the cavity 10 to the face 3 of the housing.

 The bonding operation is carried out either under vacuum or in an atmosphere of neutral gas such as nitrogen.

 Figures 6 and 7 relate to a user coupling box.

 The elements common to these figures and to Figures 3 to 5 have been given the same reference numbers.

 In these housings, a passage 24 contains a receiving diode 25 provided with a ball joint 25A.

 The axis R'1 of passage 24 is made with the axis of the fiber at an angle equal to 28 degrees. The housing contains another passage 26 for receiving a transmitting diode 27 provided with a ball joint. The axis of this passage makes with the normal to the axis of the fiber an angle equal to 28 degrees. The axes E 'and R'1 thus form an angle close to 90 degrees between them.

 The mode of use of the box is the same as before.

 The coupler of the invention is of simple and economical construction, the adjustment of the elements is very easy and very safe.

 The tightness of the housing guarantees a long service life of the coupler.

Claims (7)

1 / Bidirectional coupler for optical fiber connection comprising an optical fiber whose end is cut along a bevelled flat face, a light emitting diode (4) and a light receiving diode (5), characterized in that in a plane containing the axis (XX ') of the fiber and the normal (NN') to the bevelled flat face, the angle (a) formed by the trace in said plane of said flat beveled face with the axis (XX ') of the fiber is between 35 degrees 12 minutes and 35 degrees 48 minutes, the angle (b) formed by the emission axis (E) of the light emitting diode (4) with the fiber axis is between 19 and 23 degrees , the emission axis (E ') being located in the acute angle closed by the fiber axis and the trace of the flat face of the bevel, the angle (c) formed by the reception axis ( R) of the photoreceptor diode (5) being between 3 and 7 degrees, the reception axis (R) and the emission axis (E) being located in the same quadrant constituted by the axis (XX ') fiber and its normal (NN ') . 2 / Bidirectional coupler for connection by optical fiber, comprising a fiber the end of which is cut along a bevelled flat face, a light emitting diode (4A) and a light receiving diode (5A) characterized in that, in a plane containing the axis (XX ') of the fiber and the normal (NN') to the bevelled flat face, - the angle (a ') formed by the trace in said plane of the beveled flat face with the axis (XX') of the fiber is between 34 degrees 30 minutes and 35 degrees 6 minutes, - the angle (b ') formed by the axis (E') of emission of the light emitting diode (4A) with the normal (NN ') at the fiber is between 26 and 30 degrees, this angle being counted relative to the normal (NN ') to the fiber so that the emission axis is on the side of the fiber relative to the bevelled flat face, - the angle (c ') formed by the axis (R') - of reception of the photoreceptive dipod (SA) is between 26 and 30 degrees, the receiving diode being placed in the acute angle formed by the axis of the fiber and the tra this from the bevelled flat face. 3 / Bidirectional coupler for connection by optical fiber, comprising an optical fiber, a light emitting diode and a light receiving diode, characterized in that it comprises a parallelepiped housing (1) having an upper face (2), a lower face (3) and four side faces (4, 5, 6, 7), said housing having a cavity (10) opening onto the upper face and in communication by three passages with respectively three side faces, the first passage (9) receiving an element traversed by an optical fiber (12) whose beveled end is in the cavity (10), the second passage (14), of circular section, receiving a light emitting diode (15) enclosed in a part (15A) partially spherical, the third passage (16) being of circular section and opening on a lateral face (4) adjacent to that (7) where the second passage opens, and receiving a photoreceptor diode (17) enclosed in a part (17A) partially spherical, the upper face ( 2) of the case being provided with a groove (20) communicating, through holes (21, 22), with the two passages with circular sections and extending to the fiber-carrying element, the fiber being oriented parallel to the faces upper (2) and lower (3) of the housing and two (4, 5) of its lateral faces the angle formed by the axis (E) of the second passage (14) with the axis of the fiber being close to 21 degrees, the angle (R1) formed by the axis of the third passage (16) with the normal to the fiber being close to 5 degrees, the angles being counted so that the axes make an angle of 64 degrees between them and that the diodes are on either side of the plane of the bevel of the fiber. 4 / Bidirectional coupler for fiber optic connection, comprising an optical fiber, a light emitting diode and a light receiving diode, characterized in that it comprises a rectangular housing (1) having an upper face (2), a lower face (3) and four side faces (4, 5, 6, 7), said housing having a cavity (10) opening onto the upper face (2) and in communication by three passages with three of the side faces, the first passage (9) receiving a element (11) through which an optical fiber (12) passes, the beveled end of which is in the cavity (10), the second passage (26), of circular section, receiving a light emitting diode (27) enclosed in a part (27A) partially spherical, the third passage (24) being of circular section and opening on a lateral face (7) adjacent to that (4) where the second passage opens, and receiving a photoreceptor diode (25) enclosed in a part (25A) partially spherical, the upper face (2) d u housing being provided with a groove (10) communicating through holes (21, 22) with the two passages with circular sections and extending to the element (11) carrying the fiber, the fiber being oriented parallel to the faces upper (2) and lower (3) of the housing and two (4, 5) of its lateral faces, the angle formed by the axis (E ') of the second passage (26) with the axis of the fiber being close to 28 degrees, the angle formed by the axis (R'1) of the third passage (24) with the normal to the fiber- being close to 28 degrees, the angles being counted so that the axes form a 90 degree angle and the diodes are on either side of the plane of the fiber bevel. 5 / Coupler according to one of claims 3 and characterized in that the first passage (9) opens on the upper face of the housing and has a square section, the element (11) fiber holder being substantially cubic. 6 / coupler according to claim 5, characterized in that the cube carries grooves (11A, 11B, 11C) for the flow of the adhesive for its bonding in the bottom of the first passage (9). 7 / coupler according to one of claims 3 to 6, characterized in that the housing has a cover (8) provided with a hole (8A) coming in line with the groove (20) and used to introduce glue.