Arrangement for converting an optical wave having a small spot width into a wave having a larger spot width
First Claim
1. An arrangement for converting a waveguided first optical wave having a small first spot width into an optical wave matched to the spot width of a second optical wave that is guided in an optical waveguide that has a second spot width that is larger relative to the spot width of the first optical wave, said arrangement comprising a first integrated optical waveguide having a small end face matched to the small first spot width for the infeed of the first optical wave having the small first spot width, which is guided in a longitudinal axial direction in the first waveguide, a second integrated optical waveguide having a relatively large cross section matched to a relatively larger spot width for guiding a matched optical wave in the longitudinal axial direction and having a relatively larger second end face matched to the relatively larger second spot width for outfeed of the matched optical wave of the second waveguide, said first and second waveguides being arranged to extend parallel to each other with the first waveguide being arranged in the interior of the second waveguide and the first waveguide being constructed so that the first optical waveguide having the first spot width is guided in the first waveguide from the small end face in a longitudinal axial direction to a relatively larger second end face of the second waveguide and is coupled over to and propagates in the second waveguide in a longitudinal axial direction to the relatively larger second end face and spreads to form the matched optical wave.
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Abstract
An arrangement for converting an optical wave having a small spot width into an optical wave having a larger spot width comprises a first integrated optical waveguide to which a semiconductor component may be coupled and is embedded in a second, larger optical waveguide to which a monomode fiber is to be coupled. The first optical waveguide preferably tapers as it extends into the second waveguide and ends at a distance from the end face of the second waveguide so that a first optical wave in the first waveguide will spread as a consequence of the first optical waveguide becoming thinner until the wave guidance is assumed by the second waveguide. The coupler enables coupling monomode fibers to optical semiconductor components without requiring microlenses for matching the various modes.
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Citations
6 Claims
- 1. An arrangement for converting a waveguided first optical wave having a small first spot width into an optical wave matched to the spot width of a second optical wave that is guided in an optical waveguide that has a second spot width that is larger relative to the spot width of the first optical wave, said arrangement comprising a first integrated optical waveguide having a small end face matched to the small first spot width for the infeed of the first optical wave having the small first spot width, which is guided in a longitudinal axial direction in the first waveguide, a second integrated optical waveguide having a relatively large cross section matched to a relatively larger spot width for guiding a matched optical wave in the longitudinal axial direction and having a relatively larger second end face matched to the relatively larger second spot width for outfeed of the matched optical wave of the second waveguide, said first and second waveguides being arranged to extend parallel to each other with the first waveguide being arranged in the interior of the second waveguide and the first waveguide being constructed so that the first optical waveguide having the first spot width is guided in the first waveguide from the small end face in a longitudinal axial direction to a relatively larger second end face of the second waveguide and is coupled over to and propagates in the second waveguide in a longitudinal axial direction to the relatively larger second end face and spreads to form the matched optical wave.
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