EP0495865A1

EP0495865A1 - Mounting optical components

Info

Publication number: EP0495865A1
Application number: EP90915503A
Authority: EP
Inventors: Robert William Fieldings Main Road Musk
Original assignee: BT& D TECHNOLOGIES Ltd; BT&D Technologies Ltd
Current assignee: BT& D TECHNOLOGIES Ltd; BT&D Technologies Ltd
Priority date: 1989-10-13
Filing date: 1990-10-12
Publication date: 1992-07-29
Also published as: AU6602690A; JPH05501313A; GB8923135D0; WO1991006022A1; KR920704164A; IE903680A1; CA2066040A1

Abstract

Monture (1) pour lentille optique miniature (6). Elle se compose d'un châssis (2, 3) capable de déformation plastique dans et parallèlement à son plan principal (U-D & L-R). L'on peut aussi obtenir des mouvements hors de ce plan (B-F). Grâce à ce système, on peut parfaire le réglage de l'alignement de la lentille optique une fois le montage effectué.Frame (1) for miniature optical lens (6). It consists of a frame (2, 3) capable of plastic deformation in and parallel to its main plane (U-D & L-R). We can also obtain movements outside this plane (B-F). Thanks to this system, it is possible to perfect the adjustment of the alignment of the optical lens once the assembly has been carried out.

Description

MOUNTING OPTICAL COMPONENTS

This invention relates to optical components and optical componen mounts. The invention finds an important application in mountin miniature lenses in optical devices of the kind used for optica communications technology.

Taking as an example an optical fibre communications system, man of the devices used in such a system transmit light between thei components in the form of a light beam travelling through free space. Th distance over which the light travels as a beam is typically a fe micrometres, but may be up to several millimetres and more.

Whatever the distance, accurate and stable alignment between th starting and finishing points of the beam is an obvious necessity if couplin losses are to be kept low. Often, the beam will pass through a lens which i provided to relax particular alignment constraints. In a transmitter, th lens will typically focus the light output of a light source such as a laser for example, onto the end of an optical fibre; in a receiver, the ligh emerging from a fibre end may be collimated by a lens to be incident on photodetector such as a PIN photodiode, for example.

An optical transmitter in which light emerging from a laser i focused by a spherical lens onto the end of an optical fibre is described i published international patent application WO88/10018 ("Optical Devices"

BT&D Technologies Ltd.).

The previously mentioned need for good optical alignmen constitutes one of the recurrent problems in the manufacture of optica devices for use in optical communications systems and the like. Adequat alignment present difficult problems owing to the smallness of th components themselves; the high accuracy required of the alignment typically just a few micrometres or less; and to the need to ensure tha alignment will remain stable for the device lifetime of 25 years or more. The present invention is concerned with providing a mounting arrangement for optical devices that provides good long term alignment at a relatively low manufacturing cost.

According to a first aspect of the present invention, a mounting arrangement for optical components comprises a support member capable of plastic deformation in and parallel to its major plane, the support member being provided with means to mount one or more optical components thereon.

According to a second aspect of the present invention, a mounting arrangement for miniature optical lenses comprises a support member capable of plastic deformation in and parallel to its major plane, the support member being provided with means to mount one or more optical components thereon.

Preferably the support member is plastically deformable also in a direction normal to said major plane.

According to a third aspect of the present invention, a lens mount for a miniature optical lens comprises a support member capable of plastic deformation in and parallel to its major plane. Movement out of the plane may also be provided for.

The support member according to the present invention preferably comprises a frame structure.

The frame structure defines an essentially enclosed space with mounting locations for optical components being conveniently locate within this space. For example, the frame structure may be provided wit an optical component mount projecting into the interior of the spac defined by the frame structure. If desired, mounting locations for optica components may instead, or additionally, be provided on the exterior o the frame structure.

The frame structure may be open towards its associated base; that i to say, an essentially enclosed space is defined only once the fram structure has been mounted on its base. Such an open frame structure often enables the mounted optical components to be closer to the base than would be the case for a corresponding closed frame structure.

The support member may comprise two or more relatively rigid portions which are linked by relatively deformable portions. Instead, however, the support member may be of similar deformability substantially throughout

Where the support member is of a frame structure having corners, the corners may provide deformable zones.

The material which forms the deformable portions of the support member needs to have low resilience so that the shape imposed by an adjustment is retained.

The afore-described arrangements according to the present invention allow adjustments, such as re-alignment of optical lenses, for example, to be performed after assembly.

The present invention will now be described further by way of example only with reference to the accompanying drawings, of which:-

Figure 1 is a perspective schematic view of a lens mount in accordance with the present invention, with Figure la illustrating the adjustability of the lens mount of Figure 1;

Figure 2 shows a schematic view of an optical device assembly comprising a plurality of optical components;

Figures 3a to 3c and Figure 4 are schematic front views of embodiments illustrating various modifications over Figure 1;

Figures 5 is a sectional view taken along line V-V of Figure 3aι

Figure 6 illustrates a practical arrangement for supplying lens mounts attached to a feeder strip; and Figure 7 illustrates further modifications of the present invention.

Referring now also to the figures, Figure 1 shows a lens mount 1 comprising an approximately diamond shaped frame portion 2 and integral therewith a straight foot section 3. Projecting into the interior of the frame from its corner opposite the foot section 3 is a lug 4. The lug 4 has an aperture 5 which makes a press fit with a lens 6.

As illustrated in Figures 3a to 3c_, for example, the aperture 5 may be of any suitable shape which makes a push fit with the lens 6. The lens 6 is a spherical lens, although other forms of lens may be used such as, for example, a graded index rod lens (not shown).

Figure la is a schematic presentation of the manner in which the frame 1 of Figure 1 can be adjusted to position the lens 6 of Figure 1 in the appropriate position. As illustrated by the arrows, the lens can be moved up or down (U<— >D), left and right (L<— >R) and forwards and backwards (F<— >B). In general, most practically performed adjustments will be made up of a combination of movements in two or, possibly, all three directions described here. It should be noted that the up-down movement and left-right movement lie generally within the plane defined by the frame, while the front-back movement is arc-like in a direction approximately normal to that plane.

To adjust the position of the lens 6, the frame 1 is deformed by applying an external force by means of a suitable tool (not shown). The deformation of the frame 1 may occur, essentially, in one of two ways: either the frame as a whole distorts, or distortion is restricted to dedicated portions of the frame, such as the hinge points indicated by empty circles in Figure la. Such hinge points may be points of lower material strength, for example, or be regions of high stress concentration under an applied load. Since self-deformation under operating conditions is clearly undesirable, the material strength of the frame needs accordingly to be chosen such that deformation requires the application of a tool. Figure 2 shows the lens mount 1 mounted on a block 12 together with a light source 13 and an optical fibre 11. The frame 1 and the block 12 are mounted on an intermediate base 10. The frame 1 is affixed to the block 12 by means of two spaced spot welds 7. In order to enable spot welds to be made, the foot section 3 of the frame 1 extends beyond the corners of the frame 1 itself. Brazing, soldering or organic adhesives may replace the spot welds in appropriate circumstances.

The procedure to align the light source 13, the optical fibre 11 and the lens 6 in the lens mount 1 is, essentially, a trial and error method. Thus, affixing a lens mount 1 proceeds as follows:- The light source 13 is switched on and the lens mount 1 is positioned to achieve the desired alignment between it, the source 13, and the fibre 11. In this position, the lens mount 1 is attached to the block 12, in the manner described above. The procedure of affixing the lens mount 1 on the block 12 will tend to disturb the previously achieved alignment, especially so in the case of spot welding. Any such misalignment occurring during that procedure is then corrected, with the light source 13 still under power, by deforming the lens mount 1 with a suitable tool (not shown) until the desired optical alignment is obtained. The necessary degree of accuracy in obtaining alignment and hence the exact procedure for obtaining it will largely depend on the particular application. A greater degree of alignment accuracy will normally be required for a single mode fibre than for a multimode fibre, for example.

Figures 3a to 3c. show three different embodiments of the approximately diamond shaped frame of Figure 1. The frame of Figure 3a is substantially identical with that of Figure 1, save that its lens is push-fit mounted in a hexagonal aperture 35.

The frame of Figure 3b differs from that of Figure 3a primarily in that the centre section of the foot section 3 has been removed, leaving two side portions 33 of the foot section 3. This enables the lug 4 depending from the top of the frame to be longer than in Figure 1 which, in turn, enables the lens to be mounted in a lower position relative to the foot section 3 than would be possible with the frame of Figure 3 . The frame of Figure 3c has a short foot section 38 which would be used in situations where the frame is to be affixed to the front rather than the top of the base 10 of Figure 2. In addition Figure 3c illustrates an approximately square aperture, with rounded corners, where the lens is held in place by the four straight sides of the aperture.

The individual characteristics of the three examples 3a to 3c can obviously be combined in various ways to form frames of the kind shown in Figure 1.

Another embodiment of the invention is shown in Figure 4. The frame shown in Figure 4 is, essentially, an inverted T shape in which the aperture 5 for mounting the lens is located at the far end of the stem 42 of the T, and in which the foot section 43 is formed by the crossbar of the T. Nearest the crossbar, the stem 42 is weakened by two offset slots 47 and

48, to form the bridge 44 which is a zone of mechanical weakness. As will be readily appreciated, slot 47 and 48 permit left to right movement by bending deformation of the bridge 44. Up and down movement of the portion 42 causes shear deformation of the bridge 44, while movement to the back and the front causes a torsional deformation of the bridge 44.

Additional zones of weakness may be provided, e.g. with the aid of additional slots (not shown), to obtain a greater range of adjustability.

Figure 5 is a section along the line V-V of Figure 3a and illustrates in greater detail the position of the lens 6 within the frame 1. As shown, the lens 6 makes a push fit with the sides of the aperture 35 in the lug 4.

In order to reduce unwanted reflections, the lens 6 is provided with an anti-reflection coating 67. The anti-reflection coating 67 is preferably applied to the lens only after the lens has been inserted into the frame 1.

Indeed, it is one of the advantages of using a frame such as that provided by the present invention, that the frame 1 can be used as a convenient clamp for holding the lens 6 during anti-reflection coating and, of course, thereafter. Referring now specifically to Figure 6, the frames, shown here with lenses 66 inserted, are conveniently formed along a strip 67 and attached to the strip along a break line 68.

In use, lenses are inserted into the apertures of frames 61 and are then anti-reflection coated. Subsequently each frame 61 is snapped off the strip 67 along the break line 68, and attached to a base such as base block 10 in Figure 2.

A further modified form of the present invention is shown in Figure

7. The frame shown there is modified to permit mounting thereon an assembly of a photodiode and a lens , such as is described, for example, in published international patent application WO89/05467 ("Light Sources", BT&D Technologies Ltd).

The frame 71 Figure 7 is an open frame having a central section 76 depending on each end via a strip 74 from a support arm 72, 73, whereby the outer ends of the support arm provide the foot section 73 for securing the frame 71 to a base (not shown) such as base 10 of Figure 2.

The material of the frame is preferably chosen to closely match the expansion coefficient of the base to which the frame is to be secured. Often the base will form the heat sink for an active device such as a laser or light emitting diode. If the base is a diamond heat sink the frame is preferably made of Invar™. If the base is copper, the material for the frame may be nickel; and in the case of a silicon base, Kovar™ is a material with a suitably matched expansion coefficient

Depending on the required size and the material of the frame, the frame can be formed by methods such as mechanical stamping, photo etching, machining, spark erosion, or laser cutting. The aperture for accommodating the lens can be similarly formed.

In all the afore-described cases the material thickness, stiffness, deformability and other material parameters are chosen, for a given design of frame, such that in use the frame resists deformation even when subject to moderate shocks, while being sufficiently pliable to be deformed with the aid of an adjustment tool. Where the frame is designed to have clearly defined deformation zones, the dimensions etc. of its deformable zones will be chosen accordingly.

Claims

1. A mounting arrangement for optical components comprising support member capable of plastic deformation in and parallel to its maj plane, the support member being provided with means to mount there one or more optical components.

2 A mounting arrangement for miniature optical lenses comprises support member capable of plastic deformation in and parallel to its maj plane, the support member being provided with means to mount there one or more optical lenses.

3. An arrangement according to claim 1 or claim 2, wherein t support member is plastically deformable also in a direction normal to sa major plane.

4. An arrangement according to any preceding claim, wherein t support member comprises two or more relatively rigid portions whi are linked by relatively deformable portions.

5. An arrangement according to any of claims 1 to 5, wherein t support member is of similar deformability substantially throughout.

6. An arrangement according to any preceding claim, wherein t support member comprises a frame structure.

7. An arrangement according to any preceding claim, wherein t support member comprises a frame structure provided with an optic component mount projecting into the interior of the space defined by t frame structure.

8. An arrangement as claimed in any preceding claim 7, wherein t the frame structure is open on the side designed to face its associated base.

9. A lens mounting arrangement for a rniniature optical lens as claimed in any preceding claim.

10. An optical component including a mounting arrangement as claimed in any preceding claim.