FR2652165A1 - Device for the coupling of an optoelectronic component to an optical transmission means - Google Patents

Abstract

This device for the coupling of an optoelectronic component (10) to an optical transmission means (1), with an intermediate optical element (12), includes, on the one hand, mechanical parts for gripping and/or for adjusting the position of these elements according to criteria for relative separation and alignment of these elements, the said parts being capable of being moved in relation to each other in a direction (Z) called the axial direction or in lateral directions (X, Y) for the purpose of seeking an optimum optical coupling position between the optoelectronic component and the optical transmission means and, on the other hand, means for allowing the relative movement in the axial direction of at least one (16) of the said parts, called the intermediate mechanical part, integrally with the mechanical part or parts (15) which can be moved laterally in relation to this intermediate part, and the relative movement in the lateral directions of the intermediate mechanical part, integrally with the mechanical part or parts (17) which can be moved axially in relation to this intermediate part, while at the same time stabilising said intermediate mechanical part, and the parts thus rendered integral with the latter, respectively in the axial direction during the relative movement in the lateral directions, and in the lateral directions during the relative movement in the axial direction.

Description

 The present invention relates to a device for coupling an optoelectronic photoemitter or photodetector component to an optical transmission means such as an optically removable and interchangeable optical fiber.

 Such a device makes it possible to give these two elements a relative position ensuring optimum optical coupling between them. This relative position can be identified by criteria of alignment and determined distance from these two elements. This relative position is determined during prior adjustments, so that such a device is essentially formed of mechanical parts capable of ensuring a grip and / or an adjustment of these elements, said adjustments consisting in moving these parts in relation to the others in the axial direction of the transmission means and in two lateral directions, in order to determine the relative position of these elements ensuring optimum optical coupling between them, position in which these parts are then fixed.

 The optical fiber used for these adjustments, connected for example using an optical connector, can then be disconnected. An active optical module is thus obtained which can subsequently be connected according to the needs of the users, so that when reference is made to a device for coupling an optoelectronic component to an optical transmission means, it is understood that this device does not necessarily include the optical transmission means.

 In the case where the coupling uses an optical system between these two elements, the device must be adapted to this additional element.

 French patent 2,418,941 discloses a coupling device between a light source, more particularly a light-emitting diode, and an optical fiber, with an intermediate optical element, in which the mobility of the gripping and / or adjusting parts is ensured. by sliding in the axial direction of the gripping part of the intermediate optical element and of the light-emitting diode relative to a fixed part, and in the lateral directions of the gripping part of the optical fiber relative to said fixed part.

 The main drawback of this device is that the adjustments in the axial and lateral directions are carried out independently of each other, and the positioning precision in these directions being linked to the machining tolerances of the parts sliding on each other, any adjustment or fixing operation carried out relative to the axial direction is accompanied by a large parasitic displacement along the lateral plane, and conversely, parasitic displacements which cannot be corrected effectively without new parasitic displacements being generated. there follows an imprecision on the final positioning which may be acceptable in the case where the optoelectronic component is a light-emitting diode, but not when it is a laser diode taking account of the larger positioning tolerances in the first case than in the second.

 The present invention relates to a coupling device particularly applicable to the case where the optoelectronic component is a laser diode, making it possible to avoid this drawback, by mastering the adjustment process.

 Such a device is then optimized, all the more so since the parasitic micro-displacements which could nevertheless occur during the adjustment or fixing operations can be immediately compensated for, and this before any fixing and without furthermore that of new parasitic displacements are not generated.

 A device according to the invention, for coupling an optoelectronic component to an optical transmission means, with an intermediate optical element, comprising mechanical parts for gripping and / or adjusting the position of these elements according to alignment criteria and relative distance from these elements, said parts being able to be displaced with respect to each other in a so-called axial direction or in lateral directions in order to seek an optimum optical coupling position between the optoelectronic component and the means of optical transmission, is essentially characterized in that it comprises means for authorizing the relative displacement in the axial direction of at least one of said parts, called intermediate mechanical part, integrally with the mechanical part or parts which can be moved laterally relative to this part intermediate, and the relative displacement according to the dir lateral ections of the intermediate mechanical part integrally with the mechanical part or parts movable axially with respect to this intermediate part, while stabilizing said intermediate mechanical part and the parts thus made integral with it, respectively in the axial direction during movement relative in the lateral directions, and in the lateral directions during the relative displacement in the axial direction.

 Other objects and characteristics of the present invention will appear more clearly on reading the following description of exemplary embodiments, made in relation to the attached drawings in which - Figure 1 is a sectional view of a device coupling according to the invention, along a YZ plane, in a system of orthogonal axes XYZ as shown in this figure, where Z denotes the axial direction, and X and Y the lateral directions.

- Figure 2 shows an alternative embodiment of a coupling device according to the invention, along the same plane YZ.

 Figure 1 is a sectional view of a coupling device according to the invention, along a plane YZ, in a system of orthogonal axes XYZ as shown in this figure, where Z denotes the axial direction, and X and Y the lateral directions.

This coupling device makes it possible to optically couple an optoelectronic component 10, particularly a laser diode, to an optical transmission means, particularly an optical fiber 1, intended to be connected to this coupling device by means of a guide sleeve 11 and with a half-connector 11 'equipping this coupling device, and by means of a complementary half-connector (not shown) equipping this means of transmission.

 The laser diode 10 is housed in a housing 13 with a glass window, provided with pins 14 for connection to a source of electrical energy.

 Optical coupling also uses an intermediate focusing lens 12 placed between the laser diode and the optical fiber.

 The coupling device comprises a first mechanical part 15 fixed to the sleeve 11 in which the optical fiber 1, here surrounded by a ferrule 3, is inserted with its end 2 placed in a determined position.

 The part 15, the sleeve 11 and the half-connector 11 'being secured, the assembly formed by these three elements will subsequently be reduced to the part 15.

 This coupling device also comprises a second and a third mechanical part, respectively 16 and 17, respectively carrying the focusing lens 12 and the housing 13 and mechanically adjusted so as to be able to slide relative to one another along their axis of symmetry parallel to direction Z.

The parts 16 and 17 are slid relative to each other in order to place the emitting area of the laser diode 10 at a distance p1 from the main object plane of the lens 12 such that 11 end of the fiber core optic 1, located at a distance p2 from the main image plane of this
1 1 1 lens, satisfy the conjugation equation + - p1 satisfy the conjugation equation P1 p2 f where f denotes the focal length of the focusing lens.

 Parts 15 and 16 are machined to be able to slide against each other in the two lateral directions X and Y so as to place the image of the emitting area of the laser diode on the end of the core of the optical fiber .

To allow adjustments in the X directions,
Y, Z, which are performed in dynamics, the part 15 is held in a first clamp (not shown) which can move in the directions X and Y, and the piece 17 is held in a second clamp (not shown) which can move in the Z direction.

 A spring 18 is moreover arranged along the axis of symmetry of the parts 16 and 17, in the interior volume delimited by these parts fitting into one another, and resting on these two parts by planes perpendicular to this axis of symmetry, that is to say in the direction Z.

 The displacements sought in the direction Z are obtained in one direction by compression and in the other direction by decompression of the spring 18.

 The displacement in the direction Z of the second clamp ensures the sliding of the part 17 on the intermediate part 16, the intermediate part 16 being made integral with the part 15 during this movement thanks to the spring 18 which presses them one against the other and ensures stabilization of the relative positions of the parts 15 and 16 in the lateral directions X, Y during this movement in the axial direction Z.

 The displacement in the lateral directions X, Y of the first clamp ensures the sliding of the part 15 against the intermediate part 16, the intermediate part 16 being made integral in X, Y with the part 17 during this displacement thanks to the cylindrical adjustment of these two parts and to the bearing force of the spring on these two parts, and integral in Z thanks to the compression of the spring 18 which ensures stabilization of the parts 16 and 17 in the axial direction Z during this movement .

 In the settings which have just been described, it is the part 17 which is moved in the direction Z, and the part 15 which is moved in the directions X and Y. Of course, the displacements in the directions X, Y, Z to be carried out to achieve optimal coupling are relative displacements, which allows adjustments to be made in each direction by indifferently moving the part 15 and / or the part 17, the intermediate part 16 being integral, in the 'embodiment of the coupling device of Figure 1, of the part 15 when moving in the direction Z of one or the other of the parts 15 and 17, and of the part 17 when moving in the directions X and Y from either of parts 15 and 17.

 Furthermore, the movement in the direction Z of the part 15 or of the part 17 can be obtained without the part in question being held by a clamp, simply by applying a bearing force on this part. in the direction Z, exerted for example by an external spring.

The spring 18 also allows, if a measurable force is used to ensure the adjustment in the direction
Z, to know, by this applied force, the displacement carried out in this direction, which is of interest in the event of automation of the adjustments.

 This coupling device may also include, as shown in FIG. 1, eyelets such as 19, 19 ′ allowing it to be fixed to a support, not shown in this figure.

 An adjustment method using this coupling device advantageously comprises the following steps - simultaneous adjustment in the directions X, Y, Z, - fixing the position in the direction Z, that is to say fixing the part 16 to the part 17, as well as fixing of the positions in the directions X, Y, that is to say fixing of the part 15 to the part 16.

These attachments are advantageously carried out by laser
YAG. The attachment of the parts 16 and 17 is also advantageously carried out on two attachment levels along the direction Z.

 The spring 18 also makes it possible to maintain the optimum coupling position during the operation of fixing parts 16 and 17 to each other by the fact that it permanently maintains these parts at constant distance from one of the 'other during attachment, and during the attachment operation to one another of the parts 15 and 16 by the fact that they remain pressed as initially against one another.

 The spring also makes it possible to maintain the optimum coupling position after the operation of fixing parts 16 and 17 to each other by its stiffening effect which makes it possible to limit the deflection of part 17 relative to the part. 16.

 The presence of the focusing lens between the source and the fiber can lead to variant embodiments of this coupling device. Indeed, this lens leads to distinguishing four ways of carrying out the adjustments in the directions Z and X, Y - that is to say a position adjustment in the directions X, Y and Z of the emissive zone of the laser diode relative to the lens-fiber assembly, - or an adjustment of the position in the X, Y directions of the emitting area of the laser diode relative to the lens-fiber assembly, and an adjustment of the position in the Z direction of the end of the fiber relative to the lens-laser diode assembly, - or an adjustment of the position in the X, Y directions of the end of the fiber relative to the lens-laser diode assembly, and an adjustment of the position along the direction Z of the emitting area of the laser diode relative to the lens-fiber assembly; this is the case of the embodiment described above, - either an adjustment in the directions X, Y and Z of the end of the fiber relative to the lens-diode laser assembly.

 Given the magnification G of the image relative to the object, which is advantageously chosen to be greater than 1, it is advantageous to act on the position in the directions X, Y of the end of the fiber relative to to the lens-laser diode assembly rather than to the position along the X, Y directions of the emitting area of the laser diode with respect to the lens-fiber assembly. Indeed in the last case, a lateral movement of the adjustment gives a lateral movement of the amplified factor G image while in the first case the effect is direct and is not amplified.

 Given the magnification, it is also advantageous to adjust the position in the Z direction of the end of the fiber relative to the lens-laser diode assembly rather than the position in the Z direction of the emissive region of the laser diode by compared to the lens-fiber assembly.

However, the latitude of adjustment is less critical than in the case of position adjustment along the directions X, Y and a practical aspect of assembly can lead to retaining the assembly described in FIG. 1.

 In Figure 2 is shown an alternative embodiment of the coupling device for adjusting the position in the directions X, Y, Z of the end of the fiber relative to the lens-laser diode assembly. In this device, the laser diode 10 is housed in a housing 13 ′ comprising a base 130 and a cover 131 with focusing lens 12 ′, electrically welded to the base, which fixes the position of the laser diode relative to the lens. . The housing 13 'and the sleeve 11 are carried respectively by two mechanical parts 20 and 22. The sleeve 11 and the part 22 being secured, the assembly formed by these elements will subsequently be reduced to the part 22. The part 20 thus that an intermediate adjustment part 21 are mechanically adjusted so as to be able to slide one against the other in the directions X, Y, and the parts 21 and 22 are mechanically adjusted so as to be able to slide one over the other in the direction Z, a spring 23 being moreover placed along the axis of symmetry, parallel to the direction Z, of the parts 21 and 22, in the interior volume delimited by these parts and bearing on the parts 21 and 22 by planes perpendicular to this axis of symmetry c that is to say in the direction Z. This spring allows, by pressing them one against the other, to secure the intermediate piece 21 to the piece 20 in the relative displacements of the pieces 20 and 22 according to the directi on Z, while then stabilizing the parts 20 and 21 in the lateral directions X, Y, and likewise securing the intermediate part 21 to the part 22 in the relative displacements of the parts 20 and 22 in the directions X, Y, all by then stabilizing the parts 21 and 22 in the direction Z. The displacements thus sought are for example controlled by a first and a second clamp holding respectively the part 22 and the part 20 and ensuring the respective displacement of these parts in the directions Z and X, Y.

 We have described a particular example of the coupling device according to the invention as well as an alternative embodiment, but it is obvious that the invention is not limited to the particular embodiments described. In particular, the spring 18 or 23 could be replaced by another means such as for example an elastic seal or a bellows.

Claims (4)

Claims 1 / Device for coupling an optoelectronic component (10) to an optical transmission means (1), with an intermediate optical element (12, 12 '), device comprising mechanical parts for gripping and / or adjusting the position of these elements according to criteria of alignment and relative distance of these elements, said parts being able to be moved relative to each other in a direction (z) called axial or in lateral directions (X, Y) in view of finding an optimum optical coupling position between the optoelectronic component and the optical transmission means, characterized in that it comprises means for authorizing the relative displacement in the axial direction of at least one (16,21) of said parts , said intermediate mechanical part integrally with the mechanical part or parts (15, 20) movable laterally with respect to this intermediate part and the relative displacement s following the lateral directions of the intermediate mechanical part integrally with the mechanical part or parts (17, 22) axially movable relative to this intermediate part, while stabilizing said intermediate mechanical part and the parts thus made integral with it, respectively according to the axial direction during the relative movement in the lateral directions, and in the lateral directions during the relative movement in the axial direction. 2 / Device according to claim 1, characterized in that said means for authorizing the movement comprise elastic means (18, 23). 3 / Device according to claim 2 characterized in that said elastic means (18, 23) comprise a spring disposed axially, and bearing by one of its ends on the intermediate piece and by another end on another of these pieces (17 , 22) axially movable relative to the intermediate piece (16. 21). 4 / Device according to one of claims 2 and 3, characterized in that, said mechanical parts being, after determination of said optimum optical coupling position, fixed to each other in this position, said elastic means (18, 23) are kept during and after this fixing operation.