NO774014L - PROCEDURE AND DEVICE FOR CORRECTING AN OPTICAL FIBER IN RELATION TO AN OPTICAL ELECTRONIC DEVICE - Google Patents

Description

■Method and device for aligning an optical fiber in relation to an optical electronic device.

The invention relates to a method and a device for aligning an optical fiber in relation to an optical electronic device such as light-emitting diodes, detectors and lasers. The invention is particularly applicable for aligning an optical fiber in relation to a light-emitting one. diode to achieve maximum efficiency with regard to optical connection or coupling.

Optical fiber communication systems currently have to be operated with limited power. Thus, e.g. a light-emitting diode limited emitted power. It is therefore desirable that the efficiency when connecting or coupling from the drive source to the fiber is as high as possible. To achieve practical contact, the effect that can be applied to the fibers should be at least 30% of that which can be provided by using direct micromanipulation of the fiber. Alignment of a fiber and the drive source using a micromanipulator is, however, a time-consuming and cumbersome operation if it is to be done separately by an operator who uses the manipulator.

A further difficulty is that the design of the contact should not lead to accelerated degradation of the emitting device and it may be required that encapsulation should lead to hermetic closure, resistance to corrosion and other properties.

The purpose of the invention is to provide a rapid alignment of fiber and drive source in a way that can be automated so that rapid alignment is achieved in contrast to previous methods where a micromanipulator had to be used, as direct binding of the fiber to the drive source or other device takes place.

This is achieved according to the invention by a first

optical electronic device is mounted on a carrier element in a ring-shaped element, that a bowl-shaped element is mounted in a movable element of an impact device which is movable back and forth in two mutually perpendicular axis directions X and Y, the bowl-shaped element having a bore that with exact fit encloses an optical fiber, that the bowl-shaped element is placed on . det., annular element, me d . a flange or abutment of the cup-shaped element in sliding contact with the ring-shaped element, that a second optical electronic device on the cup-shaped element flush with the bore that is located axially between both devices, one of these being a light-emitting device and the other is a light detector, that the devices are excited, that the detectors' output signal is supplied to operating circuits in the influencing device,

so that the impact device's moving element and that

.bowl-shaped element is displaced along the X- and Y-axis to a position in which the maximum level of the output signals from the detector

one is achieved, and that the bowl-shaped element is fixed in this position on the ring-shaped element.

Further features of the invention will be apparent from

requirements 2-11.

The invention will be explained in more detail below

reference to the drawing.

Fig. 1 shows an axial section through a mounted

fiber according to the invention.

Fig. 2 shows a section along the line II-II in fig. 1.

Fig. 3 shows an axial section through a part of the influencing device, the fiber, holding element and mounting device in a mutually offset state, in order to carry out the method according to the invention. Fig. 4 shows the same parts as in fig. 3 during the arrangement of the fiber in relation to a detector. Fig. 5 shows an axial section through another embodiment of a device according to the invention. Fig. 1 shows an assembled unit comprising one light-emitting diode 10 with a light-emitting area 11. The light-emitting diode or LED unit is coated with a coating 12.

It is placed on a carrier element_13 and is surrounded by a ring 14.

In the embodiment, the ring 14 consists of a ceramic

material but it may consist of another electrically insulating material. If one also isolates the leads to the device 10 e.g. by an insulating layer on the carrier element 14,

the ring may consist of electrically conductive material. A tube 15 is held by the end part 16 of a bowl-shaped projection 17 which rests on it. ceramic, r.ir.g.. ■. The part; 16 is placed on the ceramic ring, using e.g. a synthetic resin adhesive 18.

The pipe 15 is permanently connected to the part 16, e.g.

by means of soldering and has a bore into which the optical fiber is inserted with exact fit. In the embodiment, the pipe is pre-formed from a pipe with a larger diameter. using a mandrel. Such a tube has a bore with an exact fit around the fiber without plastic coating in that the larger bore 20 can provide an exact fit to the coated fiber and can be shrunk after the fiber has been placed in the tube. In fig. 1, the fiber 21 is provided with a coating 22. The cross-section of the shaped tube is shown in fig. 2. The end of the fiber 21 is aligned in relation to the light-emitting area 11 in the device 10.

The diameter of the light-emitting area 11 and the diameter of the light-transmitting core of the fiber 21 are. of the order of magnitude 0.75 y. Correct arrangement is therefore necessary for good efficiency of the coupling.

Fig. 3 and 4 show an embodiment for aligning

a pipe in relation to the device 10, where the individual parts in fig. 3 are axially offset in relation to each other and in fig. 4 assembled together. In fig. 3 is a movable element 30 in an impact device (not shown) which is movable in two angular

axis directions X and Y running right on top of each other, provided with a vacuum chuck 31 - This is designed to accommodate the part 16 and a pipe 15 caught in it. A detector 33 is placed on the element 30 above the chuck 31 by means of a hollow element 32. A vacuum connection 34 maintains a negative pressure behind the part 16

when this is located in the chuck 31. The ceramic ring 14 is located under the part 16 and the device 10 on the carrier element 13. Connection lines 35 from the detector are aligned flush with

the bore in the pipe 15.

On the fifth 4, the parts are brought together in a position to straighten the inner tube and the emitting area. The device 10 is excited to emit light from the area 11 and the detector is connected to the connecting device's control system. The directions of movement of the influence element are to the left and

right in fig. 4 as indicated by arrow A, and also movable forward

■ and back perpendicular to the plane of the drawing. At first, with... some light will enter the tube ' 15'-. from 'the emitting" area ll ':;;' and be detected by the detector. Signals from the detector are sent to the influencing device via wires 35 and the influencing device moves the element 30 automatically to find the position in which the maximum signal is received from the detector.', The influencing device stops in this position after which the part 16 which is brought by the influencing device to to move around the ceramic ring, is fixed, for example, by a synthetic resin being placed at 18 in Fig. 1. When the adhesive has hardened, the iron is depressed via the connection 34 and the mounted device can be removed.

In a similar way, a laser can be mounted, using a laser diode as the device 10 in the ceramic ring 14.

In another embodiment where a fiber is fitted to a detector, the same principle method is used with the exception that light is sent through the fiber in the tube to be detected by the detector. Such an embodiment is shown in fig. 5. The influencing device's element 30 holds the part 16 and the tube 15 as shown in fig. 4 and a short piece of the fiber 36 is placed in the tube. A light-emitting device, e.g. The LED unit 37 is placed on

the hollow element 32 and light from the unit 37 pass through the fiber 36 to the detector 38. The detector's active area is denoted by 39. The output signal of the detector 38 is supplied via wires 40 to the influencing device. This displaces the element 30 until a maximum signal is received from the detector 38. The part 36 is then fixed to the ceramic ring 14 after which the negative pressure is removed together with the detector, the part 16 and the tube. The fiber 36 can then be removed from the tube 15 and maintained in place.

The arrangement of the fiber 36 in relation to the LED unit 37 is not critical as the light emitting area of the unit 37 does not affect the arrangement of the tube 15 in relation to the active area of the detector 38

39. This procedure makes the previously cumbersome

facility operation can be automated without significant reduction in the efficiency of the facility. As an example, with three LED units, the best value for applied power using direct fiber micromanipulation was 32.30 yw, 28,

14 yw or 2.0 yw while with the help of the invention the values were 30.8 yw, 25.50 yw resp. 32.50 yw. This gives a reduction of 0.2 and 0-.4 dB for the first two. The LED units and an increase of . 0.06 dB for the third.'

Once the tube 15 has been placed and fixed it can

fibers are introduced at any time and will always be equally aligned. To provide proper axial placement of the fiber,

its introduction can be controlled. In the case of an LED unit, this can thus be excited and the light transmitted through the fiber 21 can be seen. When. the slys transfer, increases ..rapidly, the end of the fiber will be next to the LED unit in contact with the equalization layer

.12. The fiber can then be attached, e.g. by the pipe 15 part 20 being clamped together or in some other way. If that alternatively

if it is desired to produce a number of finished units that each have the same output power, then each fiber can be controlled when it is fed in until the same power level is achieved. The fiber is then fixed. Although the effect need not be the maximum possible, a number of EED fiber devices with the same specification can be provided.

There is no direct contact between

the fiber and the device. Such direct contact can lead to accelerated degradation of the device. In the present invention, the contact between the fiber and its holder and between the holder and the ring takes place using ceramic material.

The different parts can be designed in different ways

manner. Thus, the part 16 and the pipe 15 can be made as one unit. Different types of pipes can be used under that condition

that they have a bore that is precisely adapted to enclose the fiber and at least to a certain extent facilitate the introduction of the fiber, e.g. by having a conical part. The above-described embodiment of the tube is advantageous in that the conical guide part is formed when the tube is shaped. It is possibly possible to avoid the use of a ceramic ring 14 if the part 16 has a longer base part which is in direct contact with the support part 13.

Instead of a synthetic-resin-based adhesive

soldering or welding can be used if this is appropriate.

It is also possible to place a short piece of fiber in it

the narrow bore 19 as a permanent window. The device can be made by inserting the short fiber by pushing it in using a further piece of fiber to guide the insertion. The short fiber can then be fixed in position. ■ Then a fiber can be inserted until against the end surface of the short fiber. The contact between the two fibers takes place in the pipe's small-diameter bore.

Claims (10)

1. Method for aligning an optical fiber in relation to an optical electronic device, characterized in that a first optical electronic device (10, 38) is mounted on a carrier element (11) in an annular element (14), that a bowl-shaped element (16) is mounted in a movable element (30) of an impact device which is movable back and forth in two mutually perpendicular axial directions X and Y, the bowl-shaped element (16) having a bore (19) which with precise fit encloses an optical fiber (21, 36), that the bowl-shaped element (16) is placed on the ring shaped element (14) with a flange or abutment of the bowl-shaped element in sliding contact with the ring-shaped element, that a second optical electronic device (33,37) is placed on the bowl-shaped element (16) flush with the bore (19) which is axially between both devices, one (10,37) of which is a light-emitting device and the other (33»3 8) is a light detector, that the devices (10,33,37)38) are excited, that the detectors (33>3) 8) output signal is supplied to operating circuits in the impact device, so that the impact device's movable element (30) and the cup-shaped element (16) are displaced along the X and Y axes to a position in which the maximum level of the output signals from the detector (33,38) is achieved, and that the cup-shaped element (16) is fixed in this position on the ring-shaped element (14). 2. Method according to claim 1, characterized in that a pipe (15) is placed in the bowl-shaped element (16) and the forming bore (19). 3. Method according to claim 1 or 2, characterized in that the first optical electronic device is a light-emitting device (10) and that the light transmitted through the bore is measured, while the cup-shaped element (16) is displaced until a maximum output signal is achieved. 4. Method according to claim 3, characterized by . / åt-.en, optical ■fiber- f øres. into the drilling, (190. -.- so that the end of the fiber is at least close to the light-emitting device (10) and that the fiber is fixed in the bore. 5- Method according to claim 4, characterized in that the light transmitted through the fiber (21) when it is fed into the bore is regulated, and that the fiber is fixed when the light transmission reaches a predetermined value. 6. Device for aligning an optical.. fiber in , an optical electronic device during execution of the method according to one of claims 1-5, characterized by an on- action device with a movable element (30) which is movable in two mutually perpendicular axis directions X and Y, a device (14) for placing on the movable element (30) a carrier element (13) with a bore (19) which with exact fit encloses an optical fiber (21,36), a first optical electronic device (33,37) on the movable element (30) flush with the bore (19), a means for carrying a further optical electronic device (10, 38) flush with the bore (19) up to the opposite end thereof in relation to the first optical electronic device (33,37) 3, one (10,37) of the devices being a light-emitting device and the other (33,38 ) is a light detector, a device for electrically connecting the detector (33,38) to the influencing device, in that when the light-emitting device (10,37) is excited, light is transmitted through the fiber (21,36) to the detector (33,38), and the movable element (30) moves along the X and Y axes to a position in which maximum output angst signal from the detector (33,38) is obtained to align the fiber in relation to the further device. 7. Device according to claim 6, characterized in that a ring (14) surrounds the further device (10, 38), and that the support element (13) provided with a bore comprises a bowl-shaped element with a flange or abutment for sliding contact with the ring ( 14). 8. Device according to claim 7, characterized in that the support element provided with the bore comprises a cup-shaped element (16) and a tube (15) formed therein. 9. Optical electronic device, characterized by a carrier element (13), an optical electronic device (10, 38) on the carrier element (13) with an active area (11, 39) j an annular element. (14 ) .which. surrounds the device.... ... (10,38), a bowl-shaped element: (16) with a flange or abutment which rests against the ring-shaped element (14) and is placed on this, the bowl-shaped element (16) comprising a bore aligned flush with the active area (11,39), and the exact fit bore encloses the optical fiber, and an optical fiber (21,36) disposed in the bore. 10. Device according to claim 95 .. characterized in that the bore (19) comprises a shaped tube (15) in the bowl-shaped element (16). .1.1... Device according to claim 9 or 10, characterized in that the optical electronic device is a light-emitting device (10).