DE3110041A1 - Variable optical signal-branching device for optical pipes - Google Patents

Abstract

In a variable optical signal-branching device for optical waveguides, said device is provided with a transparent surface section extending along a directrix. It is possible to displace along this surface section an optical fibre whose tip rests on the transparent surface section and picks up light information emerging from the optical magnitude and conducts it away. The optical waveguide can be arranged in the shape of a helix on a drum or in the shape of a spiral on a disc.

Description

Changeable optical signal drop device

for light guides The invention relates to a changeable optical From two device for coupling and decoupling signals, and in particular one Changeable optical signal splitting device for optical waveguides.

The application of waveguide technology results in many technical Areas often the need for a light signal with a defined delay to make available or to measure delays or runtime differences. to signal branching devices can be used for this purpose in the sense of a potentiometer These can be used for both fine-tuning and zero-tuning to use.

The invention is based on the object of such a changeable to create optical signal branching device for optical waveguides, with which it it is possible to measure even the shortest running times.

According to the invention, this object is achieved in that the optical waveguide with a line running along a jacket fenden banners Surface portion is provided, and that along the transparent surface portion an optical waveguide fiber is displaceable, the tip of which on the transparent Surface section rests, and light information emerging on the optical waveguide picks up and leads away.

With such a signal branching device, a specific Delay time due to a defined distance between the tip of the optical fiber from the input of the fiber optic cable or a second, defining the reference point Adjust the fiber.

To avoid that on the entire length of the fiber optic cable Light signals emerge inappropriately, it is provided that between the transparent Surface section and the tip of the light waveguide fiber an immersion layer is provided.

In the interests of precise guidance of the optical fiber according to a further embodiment provided that the optical waveguide in the area of the transparent surface section has a guide groove and / or guide groove is provided. This guide groove or guide groove can also be formed thereby that the light guide between two upwardly protruding cladding material layers is held, which serve as a guide for the optical fiber.

The optical waveguide fiber preferably consists of an optical waveguide section with a substantially rectangular cross-section and is at the tip of the light guide section provided with an optical T.ster.

In the interest of the most precise length-related guidance possible tion the optical waveguide fiber, the invention also provides that the optical waveguide mounted helically on a drum or helically on a disc.

The optical waveguide fiber is on the drum-shaped or spiral-shaped optical fiber synchronous with the rotation of the drum or the disk, preferably mechanically positively driven.

A special embodiment of the invention can be used to measure a Difference in transit time between the light signals of two fiber optic lines serve, with each fiber optic link assigned a signal branching device is, and the runtime difference when zeroing by measuring the different Sampling is determined in the signal branching devices.

The advantages and features of the invention also emerge from the the following description of exemplary embodiments in conjunction with the claims and the drawing. They show: FIG. 1 a schematic representation of an optical one Delay line used optical fiber with a signal branching device According to the invention, Fig. 2 shows two optical, adjustable delay lines used fiber optic cables to determine a transit time difference by zero matching, 3 shows a detail from an optical waveguide wound in the shape of a drum an optical waveguide fiber lying thereon, FIG. 4 shows a side view of an optical waveguide with with an optical waveguide fiber lying on top, FIG. 5 shows a schematic View of a basic embodiment of a device eemHß Fig. 1, Fig. 6 shows a schematic view of a basic embodiment of a device according to. Fig. 2.

The speed of propagation of light, i.e. H. the time of flight, depends on the refractive index of the medium flowing through it. With an accepted Refractive index of 1.5 for glass or quartz results for a distance of 20 cm a running time of 1 ns. Correspondingly, a distance of 0.2 mm from the light is run through in a running time of about 1 ps.

In the optical waveguide shown schematically in FIG. 1 as optical delay line is the optical waveguide 10 from a laser 11 exposed to light m coupling out radiation with different transit times, is a defined decoupling plane A at the beginning of the optical waveguide Light beam coupled out with the aid of a coupler 12. The delayed beam of light is tapped in the decoupling plane R with the help of an optical fiber 14, which is shifted by a defined length al ge-Rendber of the decoupling plane A. I) the difference in length and thus the position of the optical waveguide fiber 14 is calculated from the refractive index of the light cell guide and the propagation speed of light.

In Fig. 2, two fiber optic coils 20 and 21 are used, which are wound in opposite directions and in a known manner as a laser rotary speed meter Find use. The speed at which the fiber optic coils earth rotated, due to the difference in length measured difference between the two decoupling levels C and D for the optical fibers 25 and 26 results when with the aid of the decoupled light signal in the evaluation circuit 27 a run time difference of zero is determined.

Because of the length of the fiber optic cables required, these are either Wound onto a drum in a screw-like manner or spirally onto a disc.

In Fig. 3 is a partial section in the longitudinal direction through an optical waveguide drum and in FIG. 4 a partial section from a radial section through an optical waveguide drum shown. As can be seen from FIG. 3, the optical waveguide 30 is on a carrier 31 wound, with a cladding material layer between the individual optical waveguide turns 32 is arranged, which protrudes silver from the surface of the optical waveguide and serves as a guide for the scanning tip 33 of the optical fiber undesired emergence of the light signals on the transparent surface section of the optical waveguide 30 is provided on the optical waveguide to work with an immersion layer, e.g. oil or gas.

In the illustration according to FIG. 4, the scanning tip 33 is the optical waveguide fiber shown in side view, in the event that the index jump between the fibers is, the front end of the optical waveguide fiber is ground at an angle is that it is used as a deflecting prism for the scattered light emerging from the optical waveguide 50 serves. At the scanning tip, which has relatively long delay times when scanning consist of a rectangular glass thread with an edge length of about 0.1 to 0.3 mm can, includes a sensor element 36 for receiving and deriving the the signals propagated in the optical fiber. The scanning tip 33 floats an immersion layer 34.

The optical fibers used can be used in different ways be produced, for example by a cross-sectional transformation on the desired dimension and shape. This can also be a ladder with grooves be drawn, which have the merit that the necessary for the leadership Groove already exists.

In Fig. 5 is an embodiment of an optical waveguide as an optical Delay line with a signal branching device in the basic structure shown. On a drum 50 with a mounted shaft 51, which is driven by a motor 52 is driven off, an optical waveguide 53 is wound, the input side End is led out through the interior of the drum and the shaft 51 axially. In this Area, the light is fed from a laser 54 via a beam splitter 55, with the help of which part of the light is decoupled and transmitted for evaluation 56 will.

The optical waveguide fiber 57 is guided on a spindle 58, which is coupled to the point 51 via a gear train 59. With the help of this gear 59 the spindle is set in a rotation, which a lateral adjustment of the optical fiber in accordance with the rotation of the drum. By this forced synchronization can also be the one swept over by the optical waveguide fiber Distance as a function of the rotation of the drum 50 and thus a delay time shift determine exactly.

Tn Fig. 6 is a schematic representation of an implementation of the basic arrangement according to Fig. 2 shown.

Of the he structure consists essentially of one Duplication of the arrangement according to FIG. 5, the optical waveguide 60 or 60 ' is also supported on a drum. The two optical waveguides 60 and hO ' are acted upon by a laser 61.The drive takes place via motors 52 and 52 ', both in terms of their direction of rotation and their speed of rotation can be controlled by an adjustment unit 62 for a zero adjustment is determined in a comparison circuit 63, which with the output signals the optical waveguide fibers 57 and 57 'and the output signals of the laser 61 are applied will. Since the optical waveguide fibers 57 and 57 'can only be displaced transversely to the drums are, but take a fixed position with respect to their circumference position, can from the l) sequence of drums 50 and 50 'via a further comparison circuit 64 determine the interference length between the two scanned optical fibers and thus the desired difference in runtime.

As already mentioned, such an arrangement can be used to determine the rate of turn of a turn, such as the turn of a ship Find. For reasons of principle arising from the Sagnac effect, it is it is desirable that the fiber optic loops enclose as large an area as possible can therefore between the laser 61 and the optical waveguides connected to it 60 or 60 'each have a further conductor loop connected in series, the lies outside the illustrated measuring arrangement. It is intended to use the conductor loops by a fiber optic ribbon cable merged in a circle, wherein the optical waveguides are offset to the side at the respective end faces, so that the individual loops are connected in series.

Ijir the ltir the realization of the invention Pulse-coded and frequency-modulated light signals are advantageously used by fine-tuning, temporal pulse positions or frequency superimpositions are spatially detectable.

In a further refinement, two different sources can be used with regard to Light modulation frequency as well as the light wavelength are used - For example around 850 nm and 1400 or / and 1600 nm, the source signals being synchronized are.

Instead of the embodiment according to the lig. 5 and u can also be embodiments find use with spirally wound Liclite waveguides on disks, the scanning with the aid of the optical fiber is then analogous to a record player can be done.

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Claims (14)

Claims 1. Changeable optical signal branching device for fiber optic cables, that is, the fiber optic cable (10; 20, 21; 3n; 53; 60, 60 ') with a transparent one running along a surface line Surface portion is provided, and that along the transparent surface portion an optical waveguide fiber (14; 25, 26; 57, 57 ') is displaceable, the tip of which (33) rests on the transparent Oberflychenabschnitt, and on the optical waveguide absorbs and removes leaking key information. 2. Signal branching device according to claim 1, d a d u r c h characterized, - That between the transparent surface section and the tip (33) of the optical fiber an immersion layer (34) is present. 3. Signal branching device according to claim 1 or 2, d a -characterized by - That one on the optical waveguide in the area of the transparent surface section guide groove and / or groove is provided. 4. Signal branching device according to one of claims 1 to 3, d a d ii r c h e k e n n n z e i c h n e t - that the optical waveguide between two upwardly protruding cladding material layers (32) is held, which as Serve guide for the tip (33) of the optical fiber. 5. Signal branching device according to one of claims 1 to 4, d a d u r c h e k e n n n z e i c h n e t - that the optical waveguide fiber consists of one Light guide section with an essentially rectangular <) cross-section, and - that the tip t33) of the light guide section is provided with an optical button is. 6. Signal branching device according to one or more of the claims 1 to 5, which are not shown - that the fiber optic cable is helical mounted on a drum (50) or spirally on a disc. 7. signal branching device according to claim 6, d a d u r ch characterized, - That the optical waveguide fiber along the drum-shaped or spiral-shaped optical fiber synchronous with the rotation of the drum or the disc is guided. 8. Signal branching device according to one or more of the claims 1 to 7, which are not shown - that two parallel fiber optic cables available. 9. signal branching device according to claim 8, d a -characterized, - That there are two geometrically parallel signal taps. 10. SirnalabzereigvorrichtunP according to claim 8 and 9, d a -characterized by - That both optical fibers are fed in parallel. 11. SignalabzweigvorrichtunP according to one or more of the claims 1 to 10, that is not indicated - that the grippers are individually and can be positioned differently. 12. Signalabzweigvorrichtun according to claims 6 and 7, characterized in that - That to measure a transit time difference between the light signals of two Fiber optic sections each fiber optic section has one signal branch before direction is assigned, and - that the runtime difference during zero adjustment by measuring the different scanning lengths in the signal branching devices is determined. 13. Signal branching device according to claim 1 to 12, d a d u r c h G e k e n n n n z e i c h n e t - that the optical waveguide (s) fixed the light waveguide fiber (s) in one or more tracks along the optical waveguide (s) are. 14. Signal branching device according to claim 1 to 13, characterized in that - That the optical waveguide consists of a material with a high refractive index.