SE470146B - Method of deflecting light signals from an optical waveguide - Google Patents

Description

15 20 25 30 47-0 146 z A second way of deflecting light signals is to bend the optical fiber without removing the sheath material. Thereby, the light signals can go out through the jacket and be captured by the detector.

In both cases, the deflection takes place permanently.

Another U.S. patent US 4,784,452 describes a method in which deflection takes place with a deflection device on an optical fiber.

This fiber consists of a light-conducting core and at least one sheath material. The deflection device, a probe, is an optical fiber, of the same type as the fiber from which the deflection is made.

This probe has a free end with a light-conducting core. To deflect light signals from the fiber, it must be stripped so that the core is exposed. Here the probe is used, the free end of which is placed on the stripped part of the fiber. To obtain the best possible deflection, the angle between the axis of the probe and the fiber must be adjusted. A coupling medium encloses the area at the probe and the stripped part of the fiber, and conducts light signals from the stripped part of the fiber to the probe.

The coupling medium, which is a solid and hard material, fixes the probe in relation to the fiber.

Through various experiments it has been shown that the light-conducting core can be made of polyimide. In the article "Dependence of Precursor Chemistry and Curing Conditions on Optical Loss Characteristics of Polyimide Waveguides" by C.P. Chien and K.K. Chakravorty at Boeing Aerospace and Electronics, Seattle, USA, SPIE vol 1323, Optical Thin Films III, New developments (1990), shows that polyimide is a good material for the core of the optical fiber.

Polyimide has good thermal stability and a dielectric value of 3.5, which is compatible with other IC materials. It is good for light transmission such as for optoelectric circuits in the frequency range of the size GHz. The advantage of the polyimide is that in the production of cores they can be packed tightly next to each other.

Additional data on the polyimide is that it has a refractive index (1.58-1.62) of approximately 1 dB / cm at UV exposure. index of 1.6 and optical losses in the core of 10 15 20 25 30 3 479 146 Experiments have been made with a silicone elastomer as an index-matching medium for the light-conducting core. In the article "Index-Matching Elastomers for Fiber Optics" by Robert. W. Filas, B.H.

Johnson and C.P. Wong at AT&T Bell Laboratories, N.J., USA in IEEE Journal, Proc. Electron. Compon. Cont., 39th, 486-9, shows that silicone elastomer is a good material for index matching of the core. Reflection of copolymer as a function of diphenyl content and temperature is obtained by measuring the reflection strength of a single-mode waveguide, the core of which is encapsulated by It is possible to obtain the same refractive index in a way using an elastomer. silicone rubber material as on the core. A silicone rubber is an interface between different components.

Another way is to use it as protection against, for example, moisture and dust.

Today, air is used as the refractive medium for the light-conducting core in the light-waveguide. The air has a significantly lower refractive index than the polyimide. The air has 1 as the refractive index, the polyimide has 1.6 as the refractive index and the silicone rubber has 1.5 as the refractive index.

A disadvantage of the previous solutions is that deflection of light signals from optical fibers takes place with permanently attached devices. This means that the deflection of light signals from the fiber takes place at a specific place where the sheath has been stripped. The previous solutions have several additional disadvantages. One of these disadvantages is that the light deflection can only take place on waveguides in the form of fibers, where the jacket must be peeled off at the place where the deflection is to take place. The deflection device must be attached to the optical fiber at the place where the jacket has been stripped.

Diversion in permanent branches results in losses that are far too great.

Disclosure of the Invention The object of the present invention is to eliminate the disadvantages of previous methods which deflect light signals from optical fibers. This invention relates to a method of deflecting a light signal with a light conducting probe directly on an optical waveguide having an elastic encapsulating material. The deflection can be done on two types of waveguides. In one case on a light waveguide lying on a substrate. In the second case on an optical fiber.

The method involves using the probe to enter and deflect light signals from the waveguide by allowing the probe to be inserted directly against a waveguide's light-conducting core and pick up light signals from its evanescence field, without peeling off the encapsulation material or bending the guide to deflect the light signals. The probe comprises an optical fiber, which is of the same type as the fiber from which the deflection is made. The fiber of the probe has a free fiber end.

The method relates to the following: In a first step, the fiber end of the light-conducting probe is lowered towards the encapsulated optical waveguide. In a second step, the fiber end of the probe is pressed into the encapsulating material 32 during an elastic deformation thereof, as long as the elastic properties of the material are allowed or the remaining deformation, the setting, does not become permanent. In a final step, the fiber end of the probe is angled towards the optical guide 23 so that a part of the light signal is received in the probe. The angle is for the probe to deflect a certain light signal. If the angle is changed, another light signal is obtained in the probe.

It should be noted that the fiber end of the light guide probe is as wide as the optical guide, in order to obtain the best possible deflection. Furthermore, the probe must be made of the same material as the light-conducting core or a material with an equal or greater refractive index.

The method also makes it possible to have the light-conducting probe permanently attached to the optical guide if desired.

After the deflection has taken place, the probe is removed and leaves no trace of it being there. When deflecting light waveguides, no further measures need to be taken in order for the deflection to take place 10 20 20 25 30 5 470 146.

Before the first step in the method for the optical fiber, it must be laid on a hard surface for deflection to take place. As the fiber is too flexible, it is not possible to insert a probe on the fiber without it lying on a hard surface.

The advantage of the invention is that it is possible to deflect the light signals without having to permanently attach the deflection device to a certain place on the optical waveguide. Another advantage is that it is possible to deflect the light signals from the light guide when it is attached to the substrate. Diversion from light waveguides on substrates has not been done before. It is thus easy to divert light signals from such a system. Additional advantages are that the deflection can be carried out temporarily if desired, and that the elastic encapsulation protects against external environmental influences such as dust, air and humidity during the light deflection.

Further objects and advantages of the invention will become apparent from the preferred embodiments described below and with reference to the accompanying drawings.

Figure description Figures 1-3 show a first embodiment and Figure 4 shows a second embodiment.

Figure 1 shows a light waveguide on a silicon wafer seen from above.

Figure 2 shows a part in enlarged cross-section A-A of the light guide on the silicon wafer of a method of deflecting light signals from the light waveguide, with a light-conducting probe.

Figure 3 shows a part in enlarged cross-section B-B of the light waveguide on silicon wafer of the method of deflecting light signals from the light waveguide, with a light-conducting probe.

Figure 4 shows in section a optical fiber, a method of deflecting light signals from the optical fiber, with a light-conducting probe. Preferred Embodiments The figures shown are not to scale but show only those parts which are essential for describing the inventive idea.

A first embodiment is shown in Figures 1-3.

Figure 1 shows a device 20, which consists of a substrate 21, a connector 25, a light waveguide 23 and an optical component 24 which emit or receive light.

Figure 2 is a section AA of the device 20 according to Figure 1 at the optical component 24. On the substrate 21 there is a very thin layer 40, which is to act as a refractive medium for a light-conducting core 30. Between one end of the core 30 and the component 24 there is a very narrow gap 31. The connector 25 is connected directly to the other end of the core 30. On top of the component 24 and the core 30 is an elastic encapsulating material 32. A circled area 34 shows a light conducting probe 35 which is pressed against the encapsulating material, 32 and deflects a light signal 33 from the core 30. The probe 35 receives an evanescence field which switches over the light signal 33 from the core 30. The light signal 33 received from the core 30 in the probe 35 forms a light signal 36, which corresponds to the light signal 33 but is much less energy-rich.

Figure 3 is an enlargement of the light waveguide 23 at the section BB in Figure 1. Figure 3 shows the light waveguide 23, which consists of the light conducting core 30, and the thin layer 40 on the substrate 21 and the encapsulating material 32. The encapsulating material has a lower refractive index than the core 30. The layer 40 lies on the substrate 21 and on top of the layer 40 lies the core 30. The encapsulating material 32 covers everything lying on the substrate 21. When the light-conducting probe 35 is pressed down against the core 30, a temporary deformation 41 occurs on the encapsulating material 32. When the probe 35 is depressed to its maximum position to obtain the best deflection capability, a very narrow distance 42 is formed between the probe 35 and the core 30. The substrate 21 shown in Figure 1 is a silicon wafer which is usually made of semiconductor. . Several light waveguides 23, components 24 and connectors 25 can be laid on the substrate 21.

The substrate 21 may also be made of a circuit board material, a glass material or any other material, only the substrate 21 has a lower refractive index than the core 30. It is important that the attenuation be as small as possible in the core 30.

In Figures 2 and 3, the light waveguide 23 consists of three different parts, the thin layer 40 which sits on the substrate 21, the core 30 and the encapsulation material 32. The layer 40 is of silica if the substrate 21 is of silicon. It must be of a lower refractive index than the core 30 in order not to emit light therefrom. In this case, the light conducting core 30 in Figures 2 and 3 is of multimode type, but can also be produced as single mode.

The encapsulation material 32 is a silicone elastomer, for example silicone rubber. It is there to be able to deflect light signals from the core 30. When it is elastic, the probe 35 can be pressed down against the core 30. The silicone rubber is optically conductive. One method of applying the encapsulating material 32 to the substrate 21 with the components 24 and 25 is when it is still moldable, then it cures and becomes elastic.

The device 20 described above is used for the method of deflecting light signals 33 with the light conducting probe 35 directly on the optical. the waveguide. By passing the probe 35 down through the encapsulating material 32, which is elastic, it is possible to get so close to the core 30 that the evanescence field around the core 30 can be taken up. This results in almost no losses in the core 30. It is important not to get too far down with the probe 35 because then the deformation 41 of the encapsulation material 32 can become permanent. If the probe 35 is not pushed far enough into the encapsulation material 32, it cannot take up the evanescence field. The distance between the probe 35 and the core 30 must be of the correct order of magnitude less than μm.

In order to obtain the same distance at each deflection, a measuring instrument can read that the correct distance is obtained.

The method comprises the following steps: 'That the fiber end of the light-conducting probe is lowered towards the encapsulated optical waveguide. That the fiber end of the probe 35 is pressed into the encapsulation material 32 during an elastic deformation 41 thereof, as far as the elastic properties of the material allow. That the fiber end of the probe 35 is angled towards the waveguide so that a part of the light signal 33 is taken up in the probe 35. The angle is for the probe 35 to deflect a certain light signal 33. If the angle is changed, another light signal is obtained in the probe 35.

It should be noted that the fiber end of the light conducting probe 35 should be as wide as the optical waveguide, in order to obtain the strongest possible light signal 33. Furthermore, the probe 35 should be made of the same material as the core 30 or a material with the same or greater refractive index. The probe 35 may also be made of a plastic fiber.

The method also makes it possible to have the light-conducting probe 35 permanently attached to the optical waveguide if desired.

After the deflection has taken place, the probe 35 is removed and no residual deformations of the probe 35 are present. When deflecting light waveguides 23, no further measures need to be taken in order for the deflection to take place.

A second embodiment of the device is shown in Figure 4. Figure 4 shows an optical fiber 1, which consists of a light-conducting core 2 and an encapsulating material 3, which is elastic. The core 2 has a larger refractive index than the encapsulating material 3. A probe 35 is pressed down against the core 2 by the encapsulating material 3, whereby a deformation 41 occurs on the encapsulating material 3. When the probe 35 is pressed down to its maximum position to obtain the best deflection ability, a very narrow distance is formed. 42 between the probe 35 and the light-conducting core 30. The core 2 is made, for example, of polyimide and is encapsulated by the elastic material, which is preferably silicone rubber. Because the material is elastic, the probe 35 "'x 10 15 can be inserted into the encapsulation material 3 and when the probe 35 reaches the evanescence field, deflection can take place. The device for the deflection is detachable if desired. Optical fibers are present between different telephone stations or e.g. different computers.It can be large distances and sometimes someone wants to go in and examine the traffic that is there.In this exemplary embodiment, the optical waveguide is not attached to any substrate but is a free-standing optical fiber 1.

The same method of light deflection on light waveguides 23 can be used for optical fibers. Before the first step in the method for the fiber, this must be laid on a hard surface for deflection to take place. As the optical fiber is too flexible, it is not possible to insert a probe on it without it lying on a hard surface.

Another advantage of using encapsulation material with elastic properties is that it is possible to depress a probe and deflect light signals. Another advantage is that it is cheap and easy to manufacture optical waveguides according to the above-mentioned embodiments. The method allows to temporarily divert light signals from optical guides.

The invention is of course not limited to the embodiments described above and shown in the drawings, but can be modified within the scope of the appended claims.

Claims (5)

10 15 20 25 30 470 'É46 10 PATENT REQUIREMENTS Method for deflecting light signals, from an evanescence field surrounded by an optical waveguide sheathed with an encapsulating material, by means of a light-conducting probe comprising an optical fiber whose fiber end is free, the deflection taking place without peeling off the existing encapsulation material or interrupting the optical waveguide, and the deflection taking place with minimized attenuation loss, characterized by the steps that the fiber end of the light conducting probe is lowered towards the encapsulated optical waveguide, that the fiber end of the light conducting probe is pressed into the encapsulating material during elastic deformation thereof, as far as the mechanical the properties of the material allow, and that the fiber end of the light-conducting probe is angled towards the optical guide so that a part of the light signal present in the guide is absorbed in the light-conducting probe. Method for deflecting light by means of a light-conducting probe according to claim 1, characterized in that the light-conducting probe is as wide as the optical waveguide, in order to obtain the best possible deflection. Method for deflecting light by means of a light-conducting probe according to claim 1 or 2, characterized in that the light-conducting probe is made of the same material as the light-conducting core of the waveguide or a material with an equal or greater refractive index. Method for deflecting light by means of a light-conducting probe according to claim 1, 2 or 3, characterized in that the light-conducting probe is permanently attached to the optical waveguide arena. A method for deflecting light by means of a light-conducting probe according to any one of the preceding claims, wherein the guide is an optical fiber, characterized in that in a first step the optical fiber is laid on a hard surface before deflection.