DE3112167A1 - Optical coupling arrangement - Google Patents

Abstract

The invention relates to an optical coupling arrangement, which in particular permits a low-loss optical coupling between an astigmatic semiconductor laser (e.g. a so-called "gain-guided" semiconductor laser) and an optical fibre.

Description

description

tX opi s che coupling arrangement "The invention relates to an optical Coupling arrangement according to the preamble of claim 1.

Such Eoppelanord: lungs are required, for example, to the from a substantially rectangular exit surface of a semiconductor laser outgoing radiation (light) in an optical waveguide or an optical fiber to couple, the z. B. has a circular cross section. Are called semiconductor lasers so-called "gain-guided" semiconductor lasers are used, they generally transmit radiate astigmatism. Should be such an astigmatic Semiconductor lasers are optically coupled to an optical fiber, so is the use a plan convex lens known, e.g. B. from the European patent application 0 017 374 by P. Kirkby. A planoconvex lens is used in such a coupling arrangement with its flat surface essentially directly on an exit mirror of a Semiconductor laser attached.

A first disadvantage of such a coupling arrangement is that that for a given astigmatism of the semiconductor laser and for each curvature (radius of curvature) the planoconvex lens a corresponding thickness of the planoconvex lens must be maintained must if the astigmatism is to be reduced. One such arrangement is only suitable for experimental purposes, because semiconductor laser with scattering Astigmatism each require a separate adaptation of the planoconvex lens.

A second disadvantage is that the planoconvex lens is essentially is attached directly to an output mirror of the semiconductor laser, because If the planoconvex lens needs to be displaced, the exit mirror are damaged in such a way that the resonator of the semiconductor laser is even completely gets destroyed. Such shifts are z. 3 when adjusting the coupling arrangement required.

The object of the invention is therefore, in particular for an astigmatic Semiconductor laser whose emitted radiation is in the plane of the output mirror has an arbitrarily shaped cross-section to specify an optical dual arrangement, which reduces the optically effective astigmatism, which is easily adjustable and which enables the generation of radiation that is perpendicular to their Direction of propagation has a largely arbitrary cross-section.

This object is achieved according to the invention by the in the characterizing part of claim 1 specified features solved.

Appropriate embodiments are compiled in the subclaims.

A first advantage of the invention is that in particular at the coupling of a radiation emitted by a "gain-guided" semiconductor laser into an optical fiber, e.g. B. a single mode optical fiber, eite considerable reduction the optical coupling losses is achieved.

A second advantage is that the coupling arrangement is lightweight is adjustable without damaging the output mirror of the semiconductor laser. It It is possible that the scattering of the astigmatism in semiconductor lasers increases significantly reduce the z. B. have occurred as a result of manufacturing tolerances.

The invention will play in the following with reference to Ausführungsbei explained in more detail with reference to the schematic drawings. FIG. la or FIG. Ib cross-sections through a "gainguided" semiconductor laser for explanation the appearance of astigmatism FIG. 2 and FIG. 3 according to the invention Embodiments FIG. 1a shows a schematic cross section, perpendicular to laser-active zone 11, by a semiconductor laser 1.

The radiation 2 (light) emerging perpendicular to the laser-active zone 11 has a first focus 13 which is on an output mirror 12 of the semiconductor laser 1 lies.

FIG. Ib shows a schematic cross section, in the plane of the laser-active Zone 11, by a semiconductor laser 1.

The radiation 2 exiting parallel to the laser-active zone 11 (light) has a second focus 14, which lies within the laser-active zone 11 and which from the output mirror 12 is a distance that also includes astigmatic displacement a is called.

In addition, the so-called "gain-guided" semiconductor lasers Cross-section of the emitted radiation 2 generally in a parallel direction to the l-asera'Ktiven zone 11 a larger diameter than in a direction perpendicular to the laser-active zone 11 is now the radiation 2 of such a semiconductor laser 1 z. B. be coupled into an optical fiber by means of a spherical lens, so there are considerable optical coupling losses, because under the mentioned Conditions can either the first focus 13 or the second focus 14 exactly the input of the optical fiber can be mapped. Apart from that in general result in a lack of adaptation of the cross-section of the radiation themselves hence considerable optical losses due to the astigmatism.

FIG. 2 shows a schematic representation of an inventive Embodiment that makes it possible first of all, the astigmatism mentioned To make semiconductor laser 1 essentially ineffective, so that then z. B. by means of a further optical arrangement, not shown, at the same time an exact one Illustration of the foci 13 and 14 is possible. Coupling losses are considerable as a result decreased. The principle of the invention is based on this, initially by means of a convex plane optical system 3, e.g. B of a cylindrical lens, the foci 13 and 14, which are attached to the locations W1 and W "are to be combined to form a common radiation source 21, which is at a location Wj W "? which is in the space between the exit mirror 12 of the semiconductor laser 1 and the vertex H of the convex plane system 3. A convex plane The only difference between an optical system and a multi-convex optical system is by the direction of the incident optical radiation. According to FIG. 2 falls the Radiation 2 emitted by the semiconductor laser 1 initially onto a convex surface 31 of the system 3 and then on its flat surface 32. Therefore, such a optical system called convex plan. By changing the distance c between Semiconductor laser 1 and the system 3, it is possible, the astigmatic displacement to make a visually ineffective. Such an adjustment process enables daastinmatiscne forth an adaptation to scattering / dislocations a, the z. B. production-related could be. Is the system 3 designed as a convex plane cylinder lens, whose longitudinal axis according to FIG. 2 essentially parallel to the laser-active zone 11 runs, the radius r of the cylinder lens is calculated according to the formula r = a c (c + a) (n - where n is the optical refractive index of the material of the cylindrical lens denotes for radiation 2. It is therefore possible, for example, to add the radius r to one adjust specified distance c. It is advantageous e.g. for manufacturing of the cylinder lens that the thickness d of the cylinder lens, according to the formula mentioned, has no influence on the radius r. With an exemplary given astigmatic The above formula allows a free choice of the radius r as well as the offset a Distance c. This choice enables a stratification source 21 with an essentially Generate symmetrical cross-section, because the radius of the beam waist, perpendicular to the laser-active zone 11, the radiation source 21 is calculated according to the formula w, = wJ (c + a) / c, where w, the radius measured perpendicular to the laser-active zone 11 is the waist of radiation 2 at exit mirror 12. The radius w; the waist can e.g. be chosen such that wl = w, '"where w,', the radius of the waist denoted parallel to the laser-active zone 11 of the radiation source 21. Such a one Radiation source is referred to as symmetrical and is particularly well suited for further optical images, e.g. for coupling the Radiation 2 into an optical fiber with a circularly symmetrical cross section.

Such an embodiment is shown in FIG. 3 shown. the Radiation 2 emitted by an astigmatic semiconductor laser 1 initially passes through a described benes convex flat optical system 3, - the one in place W generates a radiation source 21. This radiation source 21 is by means of a optical coupling system Ll, L2 to the input W "of an optical fiber 4, z. B. a fashion mode optical fiber. It is advisable to use the coupling system L1, L2 should be designed at least as a two-line system, because this makes it possible to use a coupling system spatially very compact and mechanically insensitive to build. One in the coupling system Optical lens L1 or lens group L1 included in L1 L2 has, for example, one such focal length and numerical aperture that the radiation source 21 is essentially is imaged lossless in an infinitely distant point, so there is a parallel radiation.

This radiation is generated by means of the optical lens h or lens group L2 coupled into the optical fiber 4, taking into account their numerical Aperture. It is also expedient to have at least one optically effective surface 31 to be anti-reflective for the radiation used 2. The described coupling system L1, L2 relates to an optical fiber 4 with a symmetrical cross section according to the invention it is possible to use optical fibers and / or optical waveguides with any cross-section to use. In such an embodiment it is expedient to use a coupling system to choose that enables a corresponding anamorphic image.

It is also useful to use the semiconductor laser 1, the system 3, the coupling system Li L2 and the optical fiber 4 (length z. B. 1 m) or a number these parts to one summarize optical component. A Such a component can, for example, be supplied by a manufacturer with as little optical loss as possible adjusted and housed in a housing. A connection of the component z B, to a long optical fiber (e.g. several 100 m) is then carried out by means of a plug and / or splice connections.

The invention is not limited to the exemplary embodiments mentioned limited, but equally applicable to other astigmatic radiation sources, whose astigmatism is to be reduced.

In addition, the invention is advantageously optically operative Arrangements can be used that require very precise optical images, e.g. for Directional radio with astigmatic radiation sources (semiconductor laser) and / or with the optical data recording, directional radio generally uses a beam path with a small widening of the beam cross-section required. Such a beam sets but a radiation source that is as free of astigmatism as possible is required, in the case of the optical For data recording, the smallest possible image of a radiation source is desired. Such an image also sets a radiation source that is as astigmatism-free as possible in advance.

Claims (16)

Claims t Optical coupling arrangement, the at least one anamorphic Contains imaging element, characterized in that in particular one of at least an astigmatic semiconductor laser (1) emitted radiation (2) initially at least a substantially convex planes optical system (3) passes through. 2, optical coupling arrangement according to claim 1, characterized in that that the optical system (3) reduces the astigmatism of the conductor laser (1). 3. Optical coupling arrangement according to claim 1 or 2, characterized in that that the system (3) consists of at least one substantially convexly planar cylinder lens consists. 4. Optical coupling arrangement according to claim 3, characterized in that that the thickness (d) of the cylindrical lens is chosen in such a way that the Astigmatism of the semiconductor laser (1) is essentially eliminated. 5. Optical coupling arrangement according to claim 3 or 4, characterized in that that the longitudinal axis of the cylinder lens is essentially parallel to a section line, which consists of a laser-active surface (11) of the semiconductor laser (1) and its one Outcoupling mirror (12) is created 6. Optical coupling arrangement according to claim 5, characterized characterized in that between the radius r of the cylindrical lens, an astigmatic Displacement (a) of an astigmatic semiconductor laser (1) and a distance (c) between a coupling-out mirror (12) of the semiconductor laser (1) and the vertex of the cylindrical lens essentially the relationship r = 1a c (c + a) (n - 1) exists, where n is the optical Refractive index of the material of the cylindrical lens referred to. 7. Optical coupling arrangement according to one or more of the preceding Claims, characterized in that an optical system (3) has at least one Beam focus (13, 14) of a semiconductor laser (1) in a space between the semiconductor laser (1) and the system (3). 8. Optical coupling arrangement according to claim 7, characterized in that that the system (3) has at least two beam foci (13, 14) of the semiconductor laser (1) essentially at a common location (W ', w ;,) which lies in the room and which acts as a radiation source (21). 9. Optical coupling arrangement according to claim 8, characterized in that that by changing a distance (c) between the semiconductor laser (1) and the Syst '> rn C5) u a radiation (2) with asymmetrical cross-section a radiation source (21) can be produced with a symmetrical cross section. 10. Optical coupling arrangement according to claim 8 or 9, characterized in that that in particular for the optical coupling of at least one semiconductor laser (1) at least one optical fiber (4) at least one optical coupling system (L1 L2) it is provided that the Lichbquelle (21) essentially maps out at least an optically effective input of at least one optical fiber (4). 11. Optical coupling arrangement according to claim 10, characterized in that that the coupling system (L1, L2) consists of at least two optical lenses (L1, L2) and / or Lens systems. 12. Optical coupling arrangement according to claim 10 or 11, characterized in that that at least one optical fiber (4) is designed as a single-mode optical fiber. 13. Optical coupling arrangement according to one or more of the preceding Claims, characterized in that at least one optical system (3) and / or an optical coupling system (L1 L2) contains at least one optical lens (L2), whose diameter is equal to or greater than the diameter of a coupled one Optical fiber. 14. Optical cone arrangement according to one or more of the preceding Claims, characterized in that at least one semiconductor laser (1), at least an optical system (3) and at least one optical coupling system (L1, L2) essentially Are combined into an optical component on which optionally at least one Optical fiber (4) is attached. 15. Optical coupling arrangement according to one or more of the preceding Claims, characterized in that at least one optically effective surface (31) is essentially anti-reflective for the radiation used. 16. Optical coupling arrangement according to one or more of the preceding Claims, characterized in that at least one optical coupling system (L1 L2) is designed as an anamorphic optical arrangement.