CH680953A5 - - Google Patents

Description

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CH 680 953 A5

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description

The invention relates to a low-reflection termination of a single-mode glass fiber according to the preamble of claim 1.

Such fiber ends are used for example in laser coupling or in measuring tasks, e.g. when determining the return loss of an optical connector or when measuring the feedback noise on semiconductor lasers. The performance reflection at an open fiber end is very disruptive.

A fiber coupling is known from DE-OS 2 611 011, in which the signals to be transmitted are emitted by a laser which, depending on the application, is sensitive to light which is reflected from the coupled glass fiber end. This can significantly disrupt the modulation behavior with direct modulation and high bit rates. If coherent lightwave transmission is provided, the laser can make mode or frequency jumps or the line width of the laser can change.

To avoid this, an arrangement consisting of a single-mode fiber and a gradient fiber is used, in which first one end of the single-mode fiber is butted onto one end of the gradient fiber. The glass fibers are then adjusted in such a way that the core of the single-mode fiber meets a region of the core of the gradient fiber in which the core refractive indices of the two glass fibers match as closely as possible. Finally, the adjusted glass fibers are fixed in this position, so that due to the combination of single-mode fiber / gradient fiber during the transition from the small light-guiding core of the single-mode fiber to the large core of the gradient fiber, the coupling losses for light waves are low, but large in the opposite direction.

It is also known to avoid disruptive influences by using an optical isolator that protects the laser. Such an insulator is complex to manufacture and therefore expensive. It also causes additional losses. Further known measures for suppressing the reflection consist in applying dielectric anti-reflective layers on the end face of the fiber end or in providing an angled grinding to the fiber axis. Fiber ends with a bevel cut are known, for example, from commercially available fiber optic connectors from Radiall.

On a fiber cut perpendicular to its optical axis there is an abrupt jump in refractive index from n = 1.5 (glass) to n = 1 (air). This leads to a reflection factor of around 4%. If no countermeasures are taken, this power component runs back in the direction of transmission and generates feedback noise in the laser or in bi-directional transmission systems a signal / noise degradation by crosstalk.

The invention has for its object to realize a low-reflection fiber termination with low insertion loss in a single-mode glass fiber while maintaining the straight-line beam path, which is simple in construction and can be produced at low cost. This object is achieved according to the invention by the constructive measures specified in the characterizing part of claim 1. Further features of the invention can be found in the dependent claims.

The invention is explained in more detail using an exemplary embodiment shown in a drawing. The drawing shows the end of a single-mode fiber with a low-reflection finish, partially cut longitudinally and shown in a side view.

In the drawing, the single-mode fiber is designated 1. It is a bare glass fiber that has been stripped of the primary coating and has a diameter of, for example, 125 μm. The fiber end is designed as a taper 2 and glued into a glass capillary 4 with a transparent adhesive 3. The glass capillary 4 is dimensioned sufficiently long so that it still comprises a length of the cylindrical part of the bare single-mode glass fiber 1 at the rear end. The glass capillary 4 has, for example, an inner diameter of approx. 130 μm and an outer diameter of e.g. 500 µm. Exact dimensions are not important here, since the only decisive factor is that the adhesive 3, which acts as a wave-guiding core, has an interface. In the present exemplary embodiment, which is in the medium working temperature range, this is achieved by using an adhesive 3 which completely fills the cavity of the glass capillary 4 and has a refractive index of 1.48, which is the same as that of the taper 2 of the single-mode glass fiber 1 or comes as close as possible to it and a glass capillary 4 with a refractive index of 1.44.

The taper 2 is approximately 1 to 2 mm long and its tip ends within the glass capillary 4 at least 10 mm in front of the end face 5 of the decoupling fiber conductor 6 which is arranged at right angles to the fiber axis and which forms the low-reflection termination of the single-mode glass fiber 1. The angle of inclination which the lateral surface of the taper 2 takes up to the fiber axis is not critical here. This is only of importance insofar as an extremely flat angle of inclination leads to an increase in damping losses. The length dimension of at least 10 mm between the taper tip and the free end of the coupling waveguide 6 ensures that the output is fully illuminated.

In the manufacture of the taper 2, the glass fiber 1 is e.g. heated to above its softening temperature in a suitable glass flame and then pulled out in such a way that its cross-section becomes continuously smaller. Due to the constantly decreasing cross-section, the fiber core loses its light-guiding property. The radiation power, which was formerly carried out in the basic mode of the fiber, is divided into a larger number of radiation modes which, in the case of a taper 2 standing freely in air, would illuminate a solid angle range which is dependent on the taper function. In the present arrangement, the radiation does not enter the free space

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out, but in the optical waveguide, which is formed by adhesive 3 and glass capillary 4. Therefore, the coupling waveguide 6 is characterized on the one hand by a low insertion loss, which e.g. has less than 0.5 dB, on the other hand due to a high reflection or return loss, e.g. is more than 50 dB with low insertion loss and a straight beam path. The suppression of reflection results from the structure parameters of the two coupled waveguides from the number of the respectively excited or excitable modes.

Since the reflection occurring at the receiving end of the single-mode optical fiber 1 is undesirable in all fiber-optic transmission systems that use semi-conductor lasers as transmitters, the present optical fiber termination can be used particularly advantageously for:

Transmission systems in which shorter fiber lengths can also occur, e.g. in the participant area.

- Transmission systems with increased demands on laser stability, e.g. Analog transmission or coherent reception.

- fiber sensor technology, e.g. Fiber gyroscope.

In addition, the present arrangement offers

Functional and cost advantages for measurement or control tasks, in which the radiant power that actually goes to the transmission link can be measured at the normally swamped fourth coupler gate. With analogue transmission, for example Linearize the transmitter characteristic over the interference of the fiber coupling.

Claims (3)

Claims 1. Low-reflection termination of a single-mode glass fiber for use in fiber-optic transmission and measurement systems, characterized in that the fiber end is designed as a taper (2) and fixed within a glass capillary (4) by means of a transparent adhesive (3), the refractive index of which is greater than the refractive index of the glass capillary (4). 2. Low-reflection termination according to claim 1, characterized in that the refractive index of the adhesive (3) matches that of the single-mode glass fiber (1) or comes as close as possible. 3. Low reflection termination according to claim 1 or 2, characterized in that the refractive index of the glass capillary (4) is smaller than the refractive index of the single-mode glass fiber (1). 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 3rd