Lateral-Bragg-Grating-Surface-Emitting Laser/Amplifier (LBGSE)
First Claim
1. A device for emitting light consisting of an optical-waveguide amplifier, which will be referred to as “
- Amplifier.”
The Amplifier amplifies light flowing along a length in a given flow direction (z), restrains light from flowing in the first of the two direction perpendicular to the said flow direction (x) and has a width in the second of the two direction perpendicular to the said flow direction (y). The Amplifier is formed on a substrate. The Amplifier is contiguous with two planar waveguides each located on a given side of the Amplifier with plane defined by the said flow direction and the second of the two directions perpendicular to said flow direction (y,z). The said planar waveguides restrains light from flowing in the first of the two directions perpendicular to the said flow direction and are formed on the same substrate as the Amplifier. The planar waveguides contain Bragg diffraction gratings with grating lines parallel to the given flow direction. A particular grating order of said Bragg diffraction gratings causes light to be emitted out of the waveguide plane at angle less than 90°
to the said first of the two directions perpendicular to the said flow direction. Another grating order of said diffraction grating reflects light at angle less than 90°
to the second of the said two directions perpendicular to said flow direction.
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Abstract
A traveling-wave, surface-emitting-optical-waveguide amplifier uses Bragg gratings to provide both confinement in the lateral direction and couple light out of the waveguide plane. The grating lines are parallel to the direction of flow of the optical mode in the traveling-wave amplifier and result in emission along the entire length of the amplifier. The parallel grating does not cause feedback into the optical mode so that laser oscillation in the traveling wave amplifier is avoided. At the same time the continuous output coupling provided by the grating avoids the deleterious effect of power saturation. In this way coherent light is emitted from a very wide and long area resulting in very high power and outstanding low beam divergence.
A DFB or DBR laser may be included monolithically as the power source for the amplifier and to obtain a Master-oscillator-power amplifier (MOPA) with outstanding performance.
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Citations
20 Claims
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1. A device for emitting light consisting of an optical-waveguide amplifier, which will be referred to as “
- Amplifier.”
The Amplifier amplifies light flowing along a length in a given flow direction (z), restrains light from flowing in the first of the two direction perpendicular to the said flow direction (x) and has a width in the second of the two direction perpendicular to the said flow direction (y). The Amplifier is formed on a substrate. The Amplifier is contiguous with two planar waveguides each located on a given side of the Amplifier with plane defined by the said flow direction and the second of the two directions perpendicular to said flow direction (y,z). The said planar waveguides restrains light from flowing in the first of the two directions perpendicular to the said flow direction and are formed on the same substrate as the Amplifier. The planar waveguides contain Bragg diffraction gratings with grating lines parallel to the given flow direction. A particular grating order of said Bragg diffraction gratings causes light to be emitted out of the waveguide plane at angle less than 90°
to the said first of the two directions perpendicular to the said flow direction. Another grating order of said diffraction grating reflects light at angle less than 90°
to the second of the said two directions perpendicular to said flow direction. - View Dependent Claims (2, 3, 4, 5, 6, 13, 14, 15, 16)
- Amplifier.”
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7. A device for emitting light consisting of an Amplifier. The Amplifier amplifies light flowing along a length in a given flow direction (z), restrains light from flowing in the first of the two direction perpendicular to the said flow direction (x) and has a width in the second of the two direction perpendicular to the said flow direction (y). The Amplifier is formed on a substrate. The said Amplifier is contiguous to a planar waveguides located on a given side of the Amplifier with plane defined by the said flow direction and the second of the two directions perpendicular to said flow direction (y,z). The said planar waveguide restrains light from flowing in the first of the two directions perpendicular to the said flow direction and is formed on the same substrate as the Amplifier. The planar waveguide contains a Bragg diffraction gratings with grating lines parallel to the given flow direction. A particular grating order of said diffraction grating causes light to be emitted out of the waveguide plane at angles less than 90°
- to the said first of the two directions perpendicular to the said flow direction. Another grating order of said diffraction grating reflects light at angle less than 90°
to the second of the said two directions perpendicular to said flow direction. - View Dependent Claims (8, 9, 10, 11, 12, 17, 18, 19, 20)
- to the said first of the two directions perpendicular to the said flow direction. Another grating order of said diffraction grating reflects light at angle less than 90°
Specification