DE2409455A1 - Branch output for light conductor - using curved portion of conductor to control partial output - Google Patents

Abstract

The light conductor is mounted on a substrate in a curve such that a given proportion of the conducted light is radiated outwards to a receiver in the vicinity of the curve. The receiver pref. comprises a photodetector, an electrical amplifier and a receiving unit. It may also consist of an optical system, a further light conductor, a light amplifier and a receiving unit, or a photodetector, an electrical amplifier, a laser or light-emitting diode, a further light conductor and a receiving unit.

Description

Decoupling device for light from optical waveguides The invention relates to a coupling device for light from optical waveguides.

On message transmission routes over several kilometers signals branched off from the optical waveguides after several sections will. It has been proposed (P 2340 020.6), a decoupling device for Light through a branch of a fiber core in a common fiber cladding to reach. The light signals to be continued are after the branching point in the continuing fiber core through a plug connection in a continuing one optical waveguide coupled. All angles occurring in the branching zone the individual cores against each other are specified so that in all curvatures practically no energy losses occur.

With such a decoupling device, however, it is necessary to build an optical waveguide, which in a cladding branched core regions having.

The object of the invention is to provide a decoupling device for light to specify from optical waveguides, which makes it possible to at any Place this waveguide a given proportion of the light guided in this decoupling.

This object is achieved according to the invention in that the waveguide applied to a substrate with such a curvature is that a predetermined proportion of the light guided in the waveguide is emitted to the outside and that in the vicinity of the curvature of the waveguide at least one device is arranged to absorb radiation.

This is where the disruptive signal transmission losses occur The resulting curvatures in waveguides are used to decouple signals.

The advantage here is that in one signal transmission line A guided signal can be given small proportions by a predetermined curvature taken from the line. The extraction is possible without disconnecting the transmission line possible.

Details of the relationship between the radius of curvature of the Waveguide and the proportion of the coupled-out light energy for kernmantle and Gradient fibers are available, for example, from S.E. Miller in an essay in "IPhe Bell System Technical Journal "Vol. 48, No. 7, 1969, p. 2059 ff The light component is referred to there as light loss).

According to the invention, the outcoupled light components are advantageous reused via a device for radiation absorption, which consists of a Consists of a photodetector, an electrical amplifier and a receiver.

For the most complete possible absorption of the decoupled light components by means of the photodetector, either an imaging optical system is connected upstream of it or the photodetector is designed as a large-area photodiode.

When using imaging optics, the decoupled Light component in particular directly to a continuing waveguide, a subsequent one Device for amplifying the guided light and finally a receiver respectively.

In the event that the receiver is not directly on the waveguide is arranged, the light picked up by the photodetector is electrically amplified and fed to a laser diode or a luminescent diode, which is connected to a further optical waveguide and a subsequent receiver is connected.

Allow to register the light signals guided in the waveguide In particular, several such devices are located at a curvature of the waveguide arrange for radiation absorption.

The device (s) for absorbing radiation are advantageously built in integrated technology.

Details of the invention are based on exemplary embodiments explained in more detail in the description of the figures.

Figure 1 shows a structure according to the invention with an imaging Optics, a photodiode, an amplifier and a receiver, Figure 2 the same with imaging optics, a further waveguide, its signals are optically amplified en route and a receiver and Figure 3 do the same with a large area photodiode, an amplifier, a laser diode and a receiver.

In the figure 1, a curved core sheath fiber 1 is shown, whose Core made of doped quartz glass with the refractive index nK = 1.465 and a cladding consists of pure quartz glass with a refractive index nM = 1.458. The core diameter is 77 μm, the outer cladding diameter is 130 μm. This core sheath fiber (multimode fiber) is mounted on a substrate 2, which of the fiber has a curvature with a radius of curvature of R = 1 cm over a 1/4 arc of a circle. Run through the fiber in the direction of the arrow Signals generated at the interfaces between the core and cladding areas in the rectilinear parts of the fiber are totally reflected. In the area the curvature of the fiber, on the other hand, falls below the angle of total reflection and some of the signals are radiated to the outside.

In the above data of the fiber, the radiated portion is the signal energy 1 dB / cm.

This emitted light is transmitted to a photodetector via a lens 3 4 shown, the light-dependent electrical signal to an amplifier 5 and finally fed to a receiver 6.

At this receiver, for example on a route section a transmission link is set up, so the on the transmission link Read guided information.

According to FIG. 2, the device for absorbing radiation can also be designed so that the coupled out beam portion through a lens 3 on a further waveguide 7 is mapped and the light signal X over continued there an optical repeater 8 and another communication line 9 is fed to a receiver 10.

In the figure 3 an embodiment is shown, which it allowed, on the imaging optics shown as lenses 3 of Figures 1 and 2 to renounce.

The light coupled out from the curved waveguide 1 is here fed directly to a large-area photodiode 11 whose light-dependent signals electrically amplified (5) are fed as pump current pulses to a laser diode 12. This is connected to a continuing optical communication system 13, which in turn ends in a receiver 14.

All of these devices for absorbing radiation can be used in front of the advanced Message transmission lines 9 and 13 are also integrated according to known techniques being constructed.

3 Figures 7 claims

Claims (7)

Claims S decoupling device for light from optical waveguides, in that the waveguide is on a substrate with such a curvature is applied that a predetermined proportion of the in the waveguide guided light is radiated outwards, and that in the vicinity of the curvature of the waveguide arranged at least one device for absorbing radiation is. 2. decoupling device according to claim 1, characterized in that g e k e n n z e i c h n e t that the device for recording radiation from a photodetector, an electrical amplifier and a receiver. 3. decoupling device according to claim 1, characterized in that g e k e n n z e i c h n e t that the device for recording radiation from an imaging optics, a further waveguide, a subsequent device for amplification of led light and a receiver. 4. decoupling device according to claim 1, characterized in that g e k e n n z e i c h n e t that the device for absorbing radiation is then mutually exclusive a photodetector, an electrical amplifier, a laser or luminescence diode, another optical waveguide and a receiver. 5. decoupling device according to claims 1 to 3, characterized g e It is not noted that between the curved waveguide section and the photodetector an optics is arranged, which emerges from the waveguide Images light on the photodetector. 6. Decoupling device according to one or more of the preceding Claims, characterized in that the photodetector has a large area Photodiode is. 7. Decoupling device according to one or more of the preceding Claims, characterized in that the device for absorbing radiation is built in integrated technology. ee e te