DE10013932A1 - Laser module - Google Patents

Abstract

The invention relates to a laser module with a coupling lens (6) that is mounted independent of a laser submount (2) and that has a high numerical aperture and excellent imaging properties, whereby the laser radiation emitted by the laser diode collimates or focuses onto the optical axis (OA) of the laser module. The coupling lens is adjusted at an angle to the optical axis by way of an intermediate ring (4) of the housing and in the longitudinal direction of the optical axis by means of a focusing element (5) disposed in the intermediate ring so that the optical axis (typically axis of symmetry) of the coupling lens coincides as precisely as possible with the optical axis of the laser module.

Description

The present invention relates to a laser module, which in op toelectronic messaging systems can be used.

Optical transmit and receive modules are often constructed as so-called coax modules. In such a module, an optoelectronic component is used as the transmitting and receiving unit, which in preferred embodiments is mounted on a carrier together with control components. In Fig. 1 added an exemplary arrangement is shown in cross section. On the carrier T, a laser diode LD is attached, the radiation S of which is passed through a lens L by means of suitably arranged reflectors R, as shown, to be coupled into a transmission system, and on the other hand is directed into a monitor diode MD, so that the radiation power can be regulated and stabilized by means of a suitable feedback. In Fig. 2 this arrangement is shown in an oblique view, in which it can also be seen that the reflectors R can be formed by ver mirrored glass prisms or by polished or etched te and mirrored silicon bodies, where the crystal lattice structure of the silicon is suitably aligned . Such a transmitting or receiving component 2 , as shown in FIG. 1, is also referred to as a "laser submount" in the arrangement shown there. This laser submount is inserted into a housing of a coax laser module or TO laser module provided for this purpose. The entire principle of such a module is shown in cross section in the attached FIG. 3.

In Fig. 3, the transmitting or receiving device 2 is arranged in a housing 21 , in which it is attached to the position provided for this purpose on the module base, for. B. is glued on. The radiation generated, for example, by the laser diode passes through a window of the housing and passes into a cylindrical intermediate piece 14 in order to be coupled into a glass fiber 18 . Instead of a laser diode, a photodiode can be present as the receiving component. The beam path is then aligned in the same way, but is oriented in the opposite direction to the arrow shown in FIG. 3. For higher demands on the data rates to be transmitted and the length of the transmission paths, an optical isolator 13 is often inserted into the beam path, here in the interior of the cylindrical intermediate piece 14 , in order to suppress undesirable effects of reflected laser light on the laser. Such an optical isolator essentially consists of a Faraday rotator between a linear polarizer and an analyzer. With this arrangement it is achieved that the light is linearly polarized and then the polarization direction is rotated by 45 °. After an undesirable reflection and again passing through the analyzer and the rotator, the direction of polarization of this reflected light is oriented at right angles to the direction of transmission of the polarizer, so that the radiation from the polarizer is shielded. Furthermore, a further lens 15 , shown in FIG. 3 as a spherical lens, can be attached in the intermediate piece 14 in front of the glass fiber 18 . The glass fiber 18 is arranged in a capillary 17 of a flange 16 , onto which a kink protection 19 is pushed. After a lateral adjustment, this flange 16 is fixed to the cylindrical intermediate piece 14 by means of weld seams 20 .

So far, such modules for low-cost applications Typical range for data rates up to 1 Gbit / s and shorter transmission distances are used. However, it does exist increasing interest, this construction technique for essential much higher data rates (up to 10 Gbit / s) at low cost rich use. For this, the components with a ge own adaptation circuit operated. In so-called But terfly housings mounted on Peltier coolers, coaxial Laser modules used for optical WDM transmission systems.  

For this extended area of application there is often a higher one optical output power and thus a higher coupling degree of efficiency required than with a conventional construction way of the module can be achieved.

The object of the present invention is to provide a laser module admit that with a simple structure a high coupling effect degree enables and especially for the transmission of high Data rates and / or longer transmission distances are suitable is.

This task is accomplished with the laser module with the characteristics of Claim 1 solved. Refinements result from the pending claims.

In the laser module according to the invention, an optimal ju fixed coupling lens, preferably an aspherical lens, with respect to the beam path close behind one for beam provided emission laser diode attached. With this The coupling lens becomes the laser emitted by the laser diode radiation collimates on the optical axis of the laser module or on a point or short section of the optical ach focused. The coupling lens used according to the invention is a component of the laser module that is Submount or a laser chip is mounted independently and consequently can be chosen to have a high numerical Has an aperture and good optical imaging properties, that with a lens etched into a silicon subcarrier cannot be reached. The coupling lens is in the longitudinal direction of the laser beam and adjusted transversely to it so that the optical axis (typically axis of symmetry) of the coupling lens with the intended optical axis of the La serstrahles matches. The optical axis of the laser beam les in the laser module is provided by the position of the Coupling an external waveguide to the laser module de finishes. The coupling lens is adjusted during assembly  of the laser module before the moving parts of the assembly permanently z. B. be fixed by welding.

A more detailed description of preferred embodiments follows examples of the arrangement according to the invention with reference to the figures.

Fig. 1 shows a laser submount described at the outset according to the prior art in cross section.

FIG. 2 shows the arrangement of FIG. 1 in an oblique top view without an integrated lens.

Fig. 3 shows an initially described coax laser module from the prior art in cross section.

Fig. 4 shows an example of a laser module according to the invention.

In Fig. 4, an example of a laser module according to the invention, a coaxial laser module is shown in cross section, in which there is a laser chip mounting housing 2 (usually referred to as a laser submount) with a laser diode on a carrier 1 (TO carrier) . Instead of the drawn-in laser chip mounting housing, which deflects the laser beam emitted by the laser diode in the direction facing away from the carrier (upward in the drawing) by means of a suitable reflecting surface, the laser module can also have a laser chip with a laser diode on one Conventional len subcarrier without radiation deflection. The carrier 1 is then designed such that the subcarrier with the laser chip can be mounted perpendicular to the bottom of the carrier, so that the laser beam is emitted parallel to the optical axis OA of the laser module. In any case, the component of the laser module provided with the laser diode does not have an integrated lens and can therefore have the structure shown in FIG. 2 in the example of a laser chip mounting housing.

A stiffening ring 3, which is an integral part of the Trä gers 1 or rings welded or around the carrier 1 of this is soldered, a mechanically stable fixation allows the carrier to the housing of the laser module. This Ge housing has an intermediate ring 4 and a ge in front of the Monta ge with as little play as possible and preferably cylindrical focusing element 5 , in which the Ankop pellinse 6 is used. To better attach the coupling lens or to facilitate assembly, the coupling lens can be provided with its own holder 61 , with which it is attached in the focusing element 5 . At the coupling lens 6 can instead be used directly in the focussing element 5 . Instead of a single, preferably aspherical lens, a lens system, ie a suitable combination of lenses, as is known per se from a large number of optical instruments, can be used as the coupling lens 6 . The coupling lens 6 is mounted so close to the laser diode that the emitted laser radiation is collimated on the optical axis OA of the laser module or is focused on a waveguide to be coupled (in particular a glass fiber).

An optical isolator 7 , which is not absolutely necessary and which serves to avoid the effects of reflected laser light on the laser diode and has already been described above, can be arranged in the beam path 5 behind the coupling lens 6 in the beam path 5 as shown in FIG. 4 or in the housing part 8 to be appropriate. This housing part 8 serves the mechanical stabilization of the arrangement and the inclusion of a not absolutely necessary, but the coupling to an external waveguide simplifying wide ren lens 9 , which is shown here as a spherical lens. Instead of a spherical lens, another lens shape or a lens system can be selected. In the event that the direct coupling of an external waveguide to the focusing element 5 delivers sufficient results of the operating properties (performance), the housing part 8 can be omitted.

In the described embodiment, a glass fiber is used as the external waveguide, which is attached by means of a flange 10 for receiving the glass fiber or a connector (ferrule) for a glass fiber connector. To complete the illustration, a capillary 11 with an optical fiber 12 guided therein is shown in the figure as an example. A connector clamp for attaching a fiber optic connector can in principle also be attached to the focusing element 5 .

The described exemplary embodiment of the laser module offers the advantage that when assembling the arrangement, the adjustment of the coupling lens which is independent of the laser chip and which is decisive for the improvement according to the invention can be made very precisely by displacing the intermediate ring 4 transversely to the beam direction and the focusing element 5 lengthways the beam direction within the intermediate ring 4 is pushed ver. When an optimal position of the coupling lens 6 is reached , the stiffening ring 3 , the intermediate ring 4 and the focusing element 5 are fixed relative to one another, which can be done in particular by welding or soldering. Three-point welding or circular welding using a laser beam is the process that is particularly suitable for this.

If the fastenings of the parts that are initially displaceable relative to one another are carried out at the points A, B and C shown in such a way that they sufficiently seal all around, the laser submount 2 or laser chip can be hermetically sealed to the outside and thus against the ingress of dust and moisture are sealed. In this case, care must be taken that the optical isolator 7 or at least the holder 61 is mounted in the focusing element 5 such that the seal is complete. Easier it is to achieve a complete seal when the focus sierungselement is 5 "eingeglast" directly with the Ankoppellinse 6, ie when the Ankoppellinse 6 dust without their own mount or bracket having a low-melting glass solder and waterproof in the focusing element 5 is attached.

The coupling lens does not have to be in the longitudinal direction of the Optical axis displaceable part of the laser module be brought. In an alternative embodiment the coupling lens in a cross to the direction of the laser beam adjustable part attached, which in turn on or in another part is arranged in the longitudinal direction of the Laser radiation can be adjusted.

Claims (6)

1. Laser module
with a laser chip mounting housing ( 2 ) with a laser diode or with a laser chip with a laser diode and
with a device ( 8 , 9 , 10 ) fixedly arranged relative thereto, for coupling an external waveguide ( 12 ), whereby an optical axis (OA) of the laser module for laser radiation emitted by the laser diode is defined,
characterized in that
there is a coupling lens ( 6 ),
which is attached as a component independent of the laser chip or the laser chip mounting housing,
whose optical axis is adjusted to the optical axis (OA) of the laser module and
which is arranged so close to the laser diode that the laser radiation emitted by the laser diode is collimated or focused on the optical axis (OA) of the laser module. 2. Laser module according to claim 1, wherein the coupling lens ( 6 ) in or on a along the optical axis (OA) of the laser module adjusted focusing element ( 5 ) is attached. 3. Laser module according to claim 2, in which
an intermediate ring ( 4 ) is provided between a stiffening ring ( 3 ) on a carrier ( 1 ) on which the laser chip mounting housing ( 2 ) or the laser chip is arranged and a further housing part ( 8 ),
the focusing element ( 5 ) is arranged in the intermediate ring ( 4 ) and
the intermediate ring ( 4 ) is adjusted transversely to the optical axis (OA) of the laser module. 4. Laser module according to claim 3, wherein the laser diode to the outside through the carrier ( 1 ), the stiffening ring ( 3 ), the intermediate ring ( 4 ) and the Fokusierungsele element ( 5 ) is sealed. 5. Laser module according to claim 1, wherein the coupling lens ( 6 ) is mounted in or on an element which is adjusted transversely to the optical axis (OA) of the laser module. 6. Laser module according to one of claims 1 to 5, wherein the coupling lens ( 6 ) is an aspherical lens.