Abstract: Provided are methods and systems for identification and analysis of materials and molecular structures. An apparatus for identification and analysis of materials and molecular structures may include a laser. The laser may, in turn, include an amplified spontaneous emission-suppressed single-frequency laser excitation source. The apparatus may further comprise a plurality of filters. The plurality of filters may include reflective volume holographic grating blocking filters. The apparatus may also comprise an optical unit and an optical spectrometer. The optical unit may be configured to deliver excitation energy to a sample substance and capture Raman signal scattering from the sample substance. The optical spectrometer may be disposed in a path of the Raman signal and configured to measure a spectrum of the Raman signal and generate a detection signal. Finally, the apparatus may comprise a processing unit configured to analyze the spectrum.

Abstract: Provided are methods and systems for identification and analysis of materials and molecular structures. An apparatus for identification and analysis of materials and molecular structures may include a laser. The laser may, in turn, include an amplified spontaneous emission-suppressed single-frequency laser excitation source. The apparatus may further comprise a plurality of filters. The plurality of filters may include reflective volume holographic grating blocking filters. The apparatus may also comprise an optical unit and an optical spectrometer. The optical unit may be configured to deliver excitation energy to a sample substance and capture Raman signal scattering from the sample substance. The optical spectrometer may be disposed in a path of the Raman signal and configured to measure a spectrum of the Raman signal and generate a detection signal. Finally, the apparatus may comprise a processing unit configured to analyze the spectrum.

Abstract: Systems and methods are provided herein. An exemplary system may include a laser source, the laser source having a laser center wavelength; at least one narrowband optical element receiving light emitted by the laser, the narrowband optical element having a filter center wavelength, the narrowband optical element being arranged such that the filter center wavelength is initially spectrally aligned with the laser center wavelength, the filter center wavelength changing in response to a temperature change such that the filter center wavelength is not substantially aligned with the laser center wavelength; and a passive adjustment mechanism coupled to the narrowband optical element, the passive adjustment mechanism including an actuator, the actuator moving in response to the temperature change, the actuator motion rotating the narrowband optical element, the rotation compensating for the temperature change such that the filter center wavelength and laser center wavelength remain spectrally aligned.

Abstract: Provided are methods and systems for identification and analysis of materials and molecular structures. An apparatus for identification and analysis of materials and molecular structures may include a laser. The laser may, in turn, include an amplified spontaneous emission-suppressed single-frequency laser excitation source. The apparatus may further comprise a plurality of filters. The plurality of filters may include reflective volume holographic grating blocking filters. The apparatus may also comprise an optical unit and an optical spectrometer. The optical unit may be configured to deliver excitation energy to a sample substance and capture Raman signal scattering from the sample substance. The optical spectrometer may be disposed in a path of the Raman signal and configured to measure a spectrum of the Raman signal and generate a detection signal. Finally, the apparatus may comprise a processing unit configured to analyze the spectrum.

Abstract: Systems and methods are provided herein. An exemplary system may include a laser source, the laser source having a laser center wavelength; at least one narrowband optical element receiving light emitted by the laser, the narrowband optical element having a filter center wavelength, the narrowband optical element being arranged such that the filter center wavelength is initially spectrally aligned with the laser center wavelength, the filter center wavelength changing in response to a temperature change such that the filter center wavelength is not substantially aligned with the laser center wavelength; and a passive adjustment mechanism coupled to the narrowband optical element, the passive adjustment mechanism including an actuator, the actuator moving in response to the temperature change, the actuator motion rotating the narrowband optical element, the rotation compensating for the temperature change such that the filter center wavelength and laser center wavelength remain spectrally aligned.

Abstract: Disclosed is a fiber loading station that is used to load and align a fiber optic cable into a fiber chuck assembly. The fiber chuck assembly and aligned fiber are mounted to a pallet that can be loaded into a package assembly station such as a laser welder. The laser welder can solder the fiber to a package of a fiber module. The fiber is pre-aligned within the loading station so that the operator of the package assembly station does not have to waste time aligning the fiber with the package in the laser welder. One fiber may be loaded at the loading station while another fiber is being soldered to a package in the laser welder. Having a separate fiber loading station allows a production facility to both align fiber and solder fiber to a package in a parallel overlapping process. This reduces the assembly time, increases throughput and decreases assembly cost to manufacture a photonic package.

Abstract: a gripper that can grasp an optical device. The gripper includes a jaw assembly coupled to a platform. The jaw assembly can be actuated by a fluid powered actuator to grasp a device. The fluid powered actuator may be a pneumatic cylinder. The actuator can be coupled to a pressure regulator that regulates the force exerted by the jaw assembly onto the device. The gripper may also have a speed regulator that regulates the speed of the jaw assembly. The jaw assembly may include a first jaw and a movable second jaw. The gripper jaws are coupled to the platform by fasteners in a manner that allows for interchangeability of the jaws.

Abstract: A clip to align a fiber optic cable with a light source within a fiber module. The clip may have a pair of sidewalls that are separated by a channel. The fiber optic cable can be located within the channel of the clip and attached to the sidewalls. The sidewall are adjoined by a pair of joining segments. The joining segments are separated by a space which allows a ferrule of the fiber optic cable to be welded to a center location of the clip.

Abstract: A process for laser welding a ferrule of a fiber optic cable to a clip of a fiber module. The process can detect and correct a movement of the fiber optic cable so that the fiber is aligned with a light source such as a laser diode. The detection method includes the steps of mechanically moving the ferrule with an automated device after a weld is completed and then detecting a change in optical power of a light beam that is transmitted through the fiber optic cable. The detection can determine a direction that the ferrule shifted during the weld process. The shift of the ferrule can be corrected by subsequent laser welds of the ferrule and clip. The power and time duration of the laser welds can be determined from an empirically derived look-up table. The entire process of detection and correction can be automated.