Abstract: A distributed feedback plus reflection (DFB+R) laser includes an active section, a passive section, a low reflection (LR) mirror, and an etalon. The active section includes a distributed feedback (DFB) grating and is configured to operate in a lasing mode. The passive section is coupled end to end with the active section. The LR mirror is formed on or in the passive section. The etalon includes a portion of the DFB grating, the passive section, and the LR mirror. The lasing mode of the active section is aligned to a long-wavelength edge of a reflection peak of the etalon.

Abstract: A system is proposed for continuously monitoring the integrity of a transmission fiber coupled to a laser source and immediately shutting down the laser source upon recognition of any type of cut, break or disconnect along the transmission fiber. A pair of monitoring photodiodes is included with the laser source and used to look at the ratio of reflected light to transmitted light, shutting down the laser if the ratio exceeds a given threshold. If a break is present, the power of the reflected light will be higher than normal, where a defined threshold is used to determine of the calculated intensity is indicative of a break. By using measurements performed in terms of decibels, the monitoring system needs only to take the difference in intensities to generate the reflection/transmission ratio output.

Abstract: A method of fabricating waveguide on a semiconductor substrate including an optical input at a first end region for receiving a continuous wave coherent light beam having a predetermined first beam profile, and a second end region opposite the first end region active layer for transferring the light beam with a predetermined second beam profile, including forming a sequence of layers including a bottom cladding layer, an active layer, and a top cladding layer on a semiconductor substrate; providing an appropriately configured mask over the region where a waveguide is to be formed; etching the semiconductor substrate down to the active layer thereby forming a partial waveguide structure; and re-growing the top cladding layer and the contact layer to the uniformly planar level of the top surface of the partial waveguide structure.

Abstract: A semiconductor gain device comprising a substrate; an optical waveguide layer extending from a first end of the substrate to a second end of the substrate opposite to the first end, the optical waveguide layer including an active layer formed on the upper surface; a reflective mirror provided at one end of the optical waveguide layer, and an exit aperture on the other end of the optical waveguide layer for emitting optical energy; wherein at least a portion of the optical waveguide layer is curved on the surface of the substrate from the first end to the second end with a radius of curvature of less than 4 mm.

Abstract: A chip scale atomic clock is disclosed that provides a low power atomic time/frequency reference that employs direct RF-interrogation on an end-state transition.

Abstract: A chip scale atomic clock is disclosed that provides a low power atomic time/frequency reference that employs direct RF-interrogation on an end-state transition.

Abstract: A chip scale atomic clock is disclosed that provides a low power atomic time/frequency reference that employs direct RF-interrogation on an end-state transition.

Abstract: A chip scale atomic clock is disclosed that provides a low power atomic time/frequency reference that employs direct RF-interrogation on an end-state transition.

Abstract: An optical waveguide assembly and method of forming the same is described. The optical waveguide assembly includes a waveguide, an amorphous silicon arrayed waveguide grating communicative with the waveguide, and an integrated amorphous silicon waveguide grating laser which communicatively outputs a laser output responsive to the amorphous silicon arrayed waveguide grating. The method includes providing a waveguide, providing an amorphous silicon arrayed waveguide grating communicative with the waveguide, and providing an integrated amorphous silicon waveguide grating laser which communicatively outputs a laser output responsive to the amorphous silicon arrayed waveguide grating.

Abstract: An optical device and a method of forming the same is described. The optical waveguide includes a substrate, an etch-stop layer adjacent to the substrate, a barrier layer adjacent to the etch-stop layer, and an active waveguide having a lower cladding layer adjacent to the barrier layer. Also described is a method of coupling to at least one active waveguide. The method includes etching an active waveguide with a high selectivity towards a crystallographic plane to form a sloped terminice with respect to a substrate upon which the active waveguide is formed, and depositing at least one other waveguide over the etched sloped terminice and at least a portion of the substrate, wherein the at least one other waveguide is photonically coupled to the etched active waveguide to provide photonic interconnectivity for the etched active waveguide.

Abstract: A method of coupling a waveguide to a multi-layered active device structure on a substrate is described. The method includes forming a junction area by etching the active device structure to form a sloped etch profile with respect to the substrate, aligning multiple layers of the multi-layered active device structure via an etch stop adjacent the multi-layered active device structure, and depositing the waveguide over the etched active device structure, wherein a sloped active passive junction is formed at the junction area that reduces residual interface reflection in a resulting coupled device. Also described is a method for removing at least one laser layer in a sloped junction region forming passive amorphous silicon waveguides. This includes depositing a SiN layer for use as an etch mask, patterning a photoresist mask, patterning the SiN layer by reactive ion etching, stripping the photoresist mask, and etching the at least one laser layer.

Abstract: A monolithic device for photonically coupling a first optical waveguide to a second optical waveguide, including: an input being optically coupled to the first waveguide; a first portion being optically coupled to the input; a second portion being optically coupled to the first portion; and, an output being optically coupled to the second portion and the second waveguide; wherein, when an optical signal is provided on the first waveguide, a given part of the signal is provided to the second waveguide dependently upon an angle between the first and second portions. At least one of the waveguides may have an amorphous silicon material coating.

Abstract: A high power laser system including: a plurality of emitters each including a large area waveguide and a plurality of quantum well regions optically coupled to the large area waveguide, wherein each of the quantum well regions exhibits a low modal overlap with the large area waveguide; a collimator optically coupled to the emitters; a diffraction grating optically coupled through the collimator to the emitters; and, an output coupler optically coupled through the diffraction grating to the emitters.

Abstract: A clock including: a portable, at least partially evacuated housing; a cell being positioned within the housing and including an internal cavity having interior dimensions each less than about 1 millimeter, an intra-cavity pressure of at least about 760 Torr, and containing a metal atomic vapor; an electrical to optical energy converter being positioned within the housing to emit light through the metal atomic vapor; an optical energy intensity detector being positioned within the housing to receive the light emitted by the converter through the metal atomic vapor; at least one conductive winding around the cavity to stabilize the magnetic field experienced in the cavity dependently upon the detector; and, an output to provide a signal from the housing dependently upon the detector detecting the light emitted by the converter through the metal atomic vapor.

Abstract: An optical amplifier including: a photonic gain element; and, a transistor electromagnetically coupled to the gain element to inject current into the gain element responsively to the internal optical intensity of the gain element.

Abstract: An optical system including: a substrate having a recess; and, a substantially planar, semiconductor waveguiding membrane suspended over the recess and having a thickness less than about 200 nm; wherein, the optical system supports a propagating optical mode having a majority of its energy external to the semiconductor waveguiding membrane.

Abstract: A monolithic device for photonically coupling a first optical waveguide to a second optical waveguide, including: an input being optically coupled to the first waveguide; a first portion being optically coupled to the input; a second portion being optically coupled to the first portion; and, an output being optically coupled to the second portion and the second waveguide; wherein, when an optical signal is provided on the first waveguide, a given part of the signal is provided to the second waveguide dependently upon an angle between the first and second portions. At least one of the waveguides may have an amorphous silicon material coating.

Abstract: A high efficiency, low voltage defect laser, and a method of forming a high efficiency laser. The low voltage defect laser includes at least one p-clad layer, at least one n-clad layer, and at least one waveguide of at least a plurality of quantum wells. The at least one waveguide is sandwiched at least between the p-clad layer and the n-clad layer, and at least one permeable crystal layer may be embedded in the p-clad layer and immediately adjacent to the at least one waveguide. The method includes growing an AlGaAs layer atop a GaAs layer, etching of the AlGaAs into submicron structure, oxidizing the AlGaAs, SAG undoped growing of an SAG undoped GaAs atop the GaAs layer, and regrowing, with p++ doped GaAs, of a planar-buried p++ GaAs.

Abstract: A monolithic light amplification system including: an un-doped waveguide; a ridge waveguide positioned over the un-doped waveguide; and, at least a doped layer between the un-doped waveguide and ridge waveguide; wherein, the un-doped waveguide and ridge waveguide cooperate to amplify light input to the un-doped waveguide.

Abstract: A method for photonically coupling to at least one active photonic device structure formed on a substrate, the method including: etching the active device structure with a high selectivity towards a crystallographic plane to form a sloped terminice with respect to the substrate; and, depositing at least one waveguide over the etched terminice and at least a portion of the substrate; wherein, the waveguide is photonically coupled to the etched active device structure to provide photonic interconnectivity for the etched active device structure.