DE10131374A1 - Arrangement for positioning an optical fiber - Google Patents

Abstract

An arrangement for positioning an optical fibre (2), relative to an optical component (1) provided with an active surface (4) is disclosed, by means of which light from the fibre (2), with a light-guiding core and a sheath surrounding the above, is transmitted to the component (1) or injected into the fibre (2) from the component (1). The fibre (2) is arranged in an open channel on a planar support (11). The end of the fibre (2) is provided with a plane, light-reflecting end surface (7), running at an acute angle (α) to the axis of the fibre (2). The fibre (2) is positioned relative to the active surface (4) of the optical component (1), such that, after reflection on the end surface (7), light guided by the fibre (2) falls on the active surface (4), or light emitted from the optical component (1) is injected into the core of the fibre (2). A support (11) made from a semiconductor material is used for a simple construction of the arrangement, on which the optical component (1) is also mounted.

Description

The invention relates to an arrangement for positioning an optical fiber relative to an optical component equipped with an active surface, with which light from the a light-conducting core and a jacket surrounding the same Fiber is transferred to the component or is coupled into the fiber by the component.

Such an arrangement has been known for a long time. For example, at Data transmission via glass fibers or optical fibers required. That in a more modern way Technology designed as a semiconductor circuit optical component can be used as a receiver or be designed as a transmitter. In the case of a receiver, for example Photodiode used with associated amplifier. With a transmitter can for optical component, a laser diode with driver circuit can be used. The respective optical component has an active surface for the reception or transmission of light given size. The frequency of the signals to be transmitted is also used to measure them Data or signals of importance.

In known arrangements with relatively low frequencies or data rates work, the fibers are positioned so that their core, for example one Has a diameter of 9 µm with its end face as close as possible to the active area of the optical component. The relative position of fibers and active areas is then not so critical if the optical component is a receiving diode acts because the active areas are large enough. In addition, in particular in the case of optical components operating as transmitters through an optimal position active adjustment set. If the optical component is a transmitter are usually also lenses between the active surfaces and the fibers built-in. With increasing frequency in data transmission (MHz or GHz range) the active area of the optical components must be smaller in order to have too large capacities to avoid the same. Such capacities must be as small as possible so that required electrical transfers at a sufficiently high speed can be carried out. The previous technique for coupling fibers and optical components are not very suitable for this application.

The invention has for its object to the arrangement described above shape that an optimal coupling between the active surface of an optical Component and an optical fiber can be achieved in a simple manner.

• - daß das Ende der Faser mit einer planen, Licht reflektierenden Endfläche versehen ist, die unter einem spitzen Winkel zur Achse der Faser verläuft, und
• - daß die Faser derart in unmittelbarer Nähe der aktiven Fläche des optischen Bauteils positioniert ist, daß jeweils nach Reflexion an der Endfläche von der Faser geführtes Licht auf die aktive Fläche fällt oder vom optischen Bauteil ausgehendes Licht in den Kern der Faser eingekoppelt wird.

According to the invention, this object is achieved by

• - That the end of the fiber is provided with a flat, light-reflecting end surface which is at an acute angle to the axis of the fiber, and
• - That the fiber is positioned in the immediate vicinity of the active surface of the optical component that light guided by the fiber falls on the active surface after reflection at the end surface or light emanating from the optical component is coupled into the core of the fiber.

With this arrangement, the light-conducting core of the optical fiber can be very close to the active surface of the optical component can be brought up. If the optical component is almost or directly on the cladding of the fiber, the distance is on average for example, only 62.5 µm if a commercially available fiber with a diameter of 125 µm is used. In addition, due to the curvature of the jacket circular fiber bundling of light takes place in one plane while in the a slight widening of the light beam occurs in the orthogonal plane. It results there is an approximately elliptical light spot when it hits the active surface of the optical component.

For simple construction of the arrangement, the optical fiber can be in a preferably V- shaped, open channel of a flat beam, which is also the optical component. The effort for the assembly of fiber and optical component is then very low, since the fiber only reaches a predeterminable end position in the channel must be inserted. In a preferred embodiment, a for the carrier Semiconductor material used on the at least one other electronic circuit is appropriate.

An embodiment of the subject of the invention is shown in the drawings.

Show it:

Fig. 1 shows schematically a circuit for receiving optical signals.

Fig. 2 also schematically shows an optical component.

Fig. 3 shows an arrangement according to the invention also in a schematic representation.

FIG. 4 shows an arrangement compared to FIG. 3.

Fig. 5 is an end view of the arrangement according to Fig. 4.

Fig. 6 shows a further supplemented arrangement.

In the following description, the case is first considered that the light of a Signal stream is transmitted via an optical fiber and then to a receiver trained optical component meets. Instead of the words "optical component", the For the sake of simplicity, the word "photodiode" is used.

The receiving circuit according to Fig. 1, as the light receiver comprises a photodiode 1, for example a PIN diode to which the light is transmitted through a an optical fiber 2 signal stream. To the working as an opto / electrical transducer photodiode 1, an amplifier 3 is connected for electrical signals, which are amplified by the data provided by the photodiode 1 signals to be further processed signals. The bias voltage required for photodiode 1 is denoted by U _B. The photodiode 1 consists of semiconductor material, such as gallium arsenide or indium phosphide. An active surface 4 and two electrical contacts 5 and 6 , to which the amplifier 3 can be connected, for example, are located on the semiconductor material.

To produce an arrangement consisting of the photodiode 1 and the optical fiber 2 , the end of the fiber 2 is first cut off at an angle. This results in a flat end surface 7 , which extends at an acute angle α to the axis of the fiber 2 . The end surface 7 is then mirrored. For this purpose, for example, a metal can be evaporated onto the end face 7 . In a preferred embodiment, gold is used as the metal. However, it is also possible to use other materials which are customary in mirror production, for example silver. Light incident on the end surface 7 treated in this way is reflected by the latter.

The optical fiber 2 consists of a light-conducting core 8 , which has a diameter of 9 μm, for example, and a jacket 9 surrounding the core 8 , which has an outer diameter of, for example, 125 μm. Core 8 and cladding 9 have different refractive indices. The angle α is expediently chosen such that light guided by the core 8 emerges from the fiber 2 in the shortest possible way after reflection at the end face 7 and is not reflected back into the core 8 if possible. With a deviation required in this sense, it is expediently in the vicinity of 45 °.

The optical fiber 2 is advantageously arranged in an open channel 10 of a flat, plate-shaped carrier 11 , on which the photodiode 1 can also be attached. The channel 10 is preferably V-shaped. At least one channel 10 is attached in the carrier 11 . The channel 10 is preferably precisely matched to the dimensions of the fiber 2 , so that it is guided exactly in the carrier 11 . The fiber 2 is expediently mounted in the channel 10 in such a way that it lies just below the surface of the carrier 11 . It can then be inserted into the channel 10 in the longitudinal direction thereof without being obstructed by the photodiode 1 , which may already be installed. In the end position, the fiber 2 is then just below the photodiode 1 . However, it is also possible to arrange the fiber 2 in the groove 10 so that the photodiode 1 bears against its jacket 9 . The fiber 2 is positioned in the finished arrangement in the carrier 11 such that the light reflected from the end surface 7 emerges at the point at which the active surface 4 of the photodiode 1 is located.

The material of the carrier 11 is arbitrary in itself. It can consist of ceramic, for example. In a preferred embodiment, however, semiconducting material is used for the carrier 11 , such as, for example, gallium arsenide or indium phosphide. The carrier 11 can be provided with an electronic circuit 12 , indicated by dashed lines, which is advantageously an amplifier. Further electronic circuits can also be attached to the carrier 11 . The fiber 2 is again attached in a preferably V-shaped groove 10 , which can be produced very precisely by etching in this material as a so-called V-groove (V-groove). The photodiode 1 is positioned with its active surface 4 over the end surface 7 of the fiber 2 . Their contacts 5 and 6 are connected in the shortest possible way to corresponding contacts of the circuit 12 . Such short, electrically conductive connections can also be used in a carrier 11 made of semiconducting material to and between other electronic circuits of the same. A disturbance or distortion in the transmission of signals by the conductive connections can be largely excluded.

The arrangement for the transmission direction of data streams from the optical fiber 2 to the photodiode 1 is described above. The arrangement can also be used for the opposite direction of transmission. Instead of the photodiode 1 as a receiver, a transmitter is then used as the optical component. A suitable transmitter is, for example, a laser diode, in particular a laser diode (VCSEL) designed as an area radiator.

Claims (4)

1. An arrangement is transmitted to the positioning of an optical fiber relative to a vehicle equipped with an active area optical component with which light from a light conducting core and a same surrounding cladding having fiber to the component or be coupled from the device into the fiber, characterized featured ,
that the end of the fiber ( 2 ) is provided with a planar, light-reflecting end face ( 7 ) which extends at an acute angle (α) to the axis of the fiber ( 2 ), and
that the fiber ( 2 ) is positioned in the immediate vicinity of the active surface ( 4 ) of the optical component ( 1 ) in such a way that, after reflection at the end surface ( 7 ), light guided by the fiber ( 2 ) onto the active surface ( 4 ) falls or light emanating from the optical component ( 1 ) is coupled into the core ( 8 ) of the fiber ( 2 ). 2. Arrangement according to claim 1, characterized in that the end face ( 7 ) is arranged at an angle (α) lying in the vicinity of 45 ° to the axis of the fiber ( 2 ) in such a way that light guided by the fiber ( 2 ) is not is reflected back into it. 3. Arrangement according to claim 1 or 2, characterized in that the optical fiber ( 2 ) is arranged in a preferably V-shaped, open channel ( 10 ) of a flat carrier ( 11 ) which also carries the optical component ( 1 ). 4. Arrangement according to claim 3, characterized in that the carrier ( 11 ) consists of a semiconductor material and has at least one further electronic circuit ( 12 ) to which the optical component ( 1 ) is electrically conductively connected.