Radiant energy – Photocells; circuits and apparatus – Housings
Reexamination Certificate
2001-10-30
2004-03-09
Le, Que T. (Department: 2878)
Radiant energy
Photocells; circuits and apparatus
Housings
C257S081000
Reexamination Certificate
active
06703605
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to an optoelectronic micromodule.
2. Description of the Related Arts
Such an optoelectronic micromodule is known from EP 0 331 331 A1, EP 0 660 467 A1 and DE 43 13 493 A1.
EP 0 331 331 A2 discloses an optoelectronic micromodule having an optical component and a focussing lens. The optical component emits optical radiation in an emission direction perpendicular to a main carrier surface. The focussing lens, which is held by an auxiliary carrier, is arranged above the optical component in the emission direction. In this case, the focussing lens can be displaced by means of the auxiliary carrier in such a way as to enable the beam direction to be adjusted. However, one disadvantage of the arrangement described is that an adjustment of the focussing is not possible by a shift of the focussing lens in or counter to the beam direction.
DE 43 13 493 A1 discloses an optoelectronic micromodule in which an optical waveguide is coupled to a light-emitting element by means of a ball lens. In this case, the ball lens is almost arranged in the emission direction of the light-emitting element. The light-emitting element is fixed on a carrier. The ball lens is positioned in an etched trench formed in the carrier. A shift of the ball lens is not provided, however, in the optoelectronic micromodule described. Consequently, adjusting both the beam direction and the focussing of the ball lens can be carried out only in a complicated manner.
FIG. 1
shows a simplified illustration of the optoelectronic micromodule
101
disclosed in EP 0 660 467 A1.
The optoelectronic micromodule
101
has a substrate
102
having a substrate surface
103
, on which a laser diode
104
, a monitor diode
105
and a glass prism
106
are fixed. The laser diode
104
emits laser radiation parallel to the substrate surface
103
predominantly in a first beam direction
107
and in a second beam direction
108
, the latter being oriented in the opposite direction to the first beam direction
107
. The monitor diode
105
is part of a control unit (not shown) for the laser diode
104
and, to that end, is arranged on the substrate surface
103
in such a way that laser radiation emitted by the laser diode
104
in the second beam direction
108
can be incident in the monitor diode
105
. The glass prism
106
has a mirror surface
109
, which forms an angle of 45° with respect to the normal of the substrate surface
103
, and is arranged on the substrate surface
103
in such a way that laser radiation emitted by the laser diode
104
in the first beam direction
107
is deflected by the mirror surface
109
from the first beam direction
107
into a third beam direction
110
and, consequently, beam deflection is effected. Said third beam direction
110
is oriented perpendicularly to the substrate surface
103
. The glass prism
106
is covered by a lens optical arrangement
111
, fabricated in a planar process, with an effective optical region
112
on an area opposite to the substrate surface
103
. In this case, the lens optical arrangement
111
is arranged in such a way that laser radiation passes through the effective optical region
112
in the third beam direction
110
and is focussed onto a desired point by said region.
An unsatisfactory optical quality of the focussed laser radiation is achieved by the construction shown in
FIG. 1
, with the result that typically only a coupling efficiency of approximately 25% is achieved when the laser radiation is coupled into a monomode optical fiber. This is due primarily to the inadequate optical properties of the lens optical arrangement
111
fabricated in a planar process. In the case of the typically high optical aperture of the laser diode
104
, the lens optical arrangement
111
exhibits high aberration and, moreover, cannot be fabricated with the required diameter of the effective optical region
112
. In addition, the beam deflection is undesirable for many optoelectronic micromodules, for example for optoelectronic micromodules in butterfly housings.
An adjustment of an optoelectronic micromodule which can be effected during operation of the optoelectronic micromodule is referred to as active adjustment.
BRIEF SUMMARY OF THE INVENTION
The invention is based on the problem of providing an optoelectronic micromodule which can be actively adjusted in two dimensions, in which it is possible to dispense with a deflection of the optical beam path and it is also possible to use optical components having high optical quality. In this case, the optical components are provided for influencing light (e.g. focussing, deflection, filtering, modulation, etc.), light being understood to be electromagnetic radiation in the wavelength range from ultraviolet to far infrared.
The problem is solved by means of the optoelectronic micromodule having the features in accordance with the independent patent claim.
An optoelectronic micromodule comprises an optoelectronic component, for example an optoelectronic radiation source, and also a radiation variation unit. The optoelectronic component is fixed on a main carrier and can emit light in an emission direction, the emission direction being directed parallel to a main carrier surface of the main carrier. Furthermore, the radiation variation unit is arranged in the emission direction and fixed to an auxiliary carrier. The auxiliary carrier has an auxiliary carrier surface which is oriented plane-parallel to the main carrier surface and is in touching contact with the latter. Furthermore, the auxiliary carrier is arranged such that it is displaceable plane-parallel to the auxiliary carrier surface relative to the emission direction, thereby enabling two-dimensional adjustment of the radiation variation unit. The radiation variation unit can be adjusted both parallel and perpendicularly to the emission direction.
As an alternative, the optoelectronic component may also emit light in at least two emission directions. It is then advantageous if a radiation variation unit is provided in each emission direction.
Furthermore, a recess may be provided in the main carrier, in which recess the radiation variation unit can be accommodated at least partly such that it is freely moveable during its adjustment without contact with the main carrier.
The recess in the main carrier may also be designed as a through opening.
In a preferred embodiment of the optoelectronic micromodule, a through hole is provided in the auxiliary carrier, in order that the light can leave the optoelectronic micromodule after passing through the radiation variation unit.
Silicon is preferably chosen as fabrication material for both the main carrier and the auxiliary carrier, since the form of the carriers and also of the recesses can be controlled in a specific manner by crystal growth and also preferential etching. Any desired method for crystal growth and also for preferential etching can be used. It is pointed out that silicon carriers can be fabricated with very great precision.
One advantage of the optoelectronic micromodule according to the invention is that the radiation variation unit can be adjusted while the optoelectronic component is emitting, i.e. active adjustment can take place.
In accordance with a first embodiment of the invention, a ball lens may be provided as the radiation variation unit, which ball lens focuses the light emitted by the optoelectronic component through the through hole in the auxiliary carrier for example onto an input end of an optical waveguide.
Instead of a ball lens, however, it is also possible to use other optical components.
In accordance with a second embodiment of the invention, the radiation variation unit is realized by a spherical lens which, just like the ball lens described above, focuses the light emitted by the optoelectronic component through the through hole in the auxiliary carrier for example onto an input end of an optical waveguide.
In a third embodiment of the invention, a planar mirror is provided as the radiation variation unit, whi
Briggs and Morgan P.A.
Infineon - Technologies AG
Le Que T.
Spears Eric J
Stone Jeffrey R.
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