Abstract: A method of aligning an optical fiber includes placing an optical fiber onto a rotation stage, securing the optical fiber on the rotation stage, illuminating the optical fiber on the rotation stage, and collecting an initial image of an emission face of the optical fiber. The method also includes calculating a rotational offset of the optical fiber based on the initial image, and rotating the optical fiber on the rotation stage if the rotational offset of the optical fiber is not within a tolerance. The method further includes iteratively collecting at least one more additional image of the emission face of the optical fiber and releasing the optical fiber if the rotational offset of the optical fiber is within the tolerance.

Abstract: Various embodiments and methods related to an optical fiber alignment system are provided herein. The optical fiber alignment system includes a controller and a rotation stage having a central axis, a first end, and a second end. The central axis extends from the first end to the second end of the rotation stage. The rotation stage includes an optical fiber channel extending from the first end of the rotation stage to the second end of the rotation stage and may be operationally coupled with the controller. The rotation stage is configured to rotate about the central axis of the rotation stage. The optical fiber alignment system includes a light source positioned to emit light onto the optical fiber channel at an oblique angle from the central axis of the rotation stage. The optical fiber alignment system includes an image sensor positioned adjacent to the second end of the rotation stage.

Abstract: A method for profiling a laser beam includes receiving the laser beam at a thermochromic interface of a detector. A temperature set point for the detector can be selected. The temperature set point can correspond to an equilibrium temperature at the thermochromic interface. The method can also include capturing an image of the thermochromic interface and using the image to determine a partial intensity profile corresponding to at least a portion of the beam intensity profile. A reconstructed beam profile can be assembled using the partial intensity profile. If the reconstructed beam profile is not complete, the method can include iterating over additional temperature set points to determine additional partial intensity profiles. The method can also include determining that the reconstructed beam profile is complete and outputting the reconstructed beam profile.

Abstract: A method for profiling a laser beam includes receiving the laser beam at a thermochromic interface of a detector. A temperature set point for the detector can be selected. The temperature set point can correspond to an equilibrium temperature at the thermochromic interface. The method can also include capturing an image of the thermochromic interface and using the image to determine a partial intensity profile corresponding to at least a portion of the beam intensity profile. A reconstructed beam profile can be assembled using the partial intensity profile. If the reconstructed beam profile is not complete, the method can include iterating over additional temperature set points to determine additional partial intensity profiles. The method can also include determining that the reconstructed beam profile is complete and outputting the reconstructed beam profile.

Abstract: A system for determining the profile of a laser beam includes a detector having a thermochromic liquid crystal film (TLCF) in thermal communication with a heat spreader and a thermoelectric cooler. The liquid crystal film has a thermochromic response such that heating of the film by a received laser beam creates a detectable color response at the film. The system also includes an image sensor and a controller configured to output an operating current for the TEC and receive images from the sensor. The system can selectively vary the temperature set point of the TEC to change the steady state temperature of the TLCF to examine the full intensity profile of the received beam even when the temperature response bandwidth of the TLCF is too narrow to display the full beam profile in a single color spot.

Abstract: Systems and methods for aligning an optical fiber are provided herein. The method may include providing an optical fiber having a first end and a second end, where the first end of the optical fiber has a predefined manufacturing property. For example, the predefined manufacturing property of the first end of the optical fiber may include a predefined cleave angle. The method may also include positioning the optical fiber such that the first end of the optical fiber faces a microlens array (MLA) alignment system. In an example embodiment, the MLA alignment system may include a tilt sensing device and a position sensing device. The method may also include emitting a light beam from the first end of the optical fiber toward the MLA alignment system.

Abstract: Various embodiments and methods related to an optical fiber alignment system are provided herein. The optical fiber alignment system includes a controller and a rotation stage having a central axis, a first end, and a second end. The central axis extends from the first end to the second end of the rotation stage. The rotation stage includes an optical fiber channel extending from the first end of the rotation stage to the second end of the rotation stage and may be operationally coupled with the controller. The rotation stage is configured to rotate about the central axis of the rotation stage. The optical fiber alignment system includes a light source positioned to emit light onto the optical fiber channel at an oblique angle from the central axis of the rotation stage. The optical fiber alignment system includes an image sensor positioned adjacent to the second end of the rotation stage.

Abstract: Various embodiments and methods relating to an optical fiber alignment and splicing system are described herein. The optical fiber alignment and splicing system includes a first rotation stage having a first central axis, a first end, and a second end, and a second rotation stage having a second central axis, a third end, and a fourth end. The first central axis extends from the first end to the second end of the first rotation stage, and the second central axis extends from the third end to the fourth end. The first rotation stage includes a first optical fiber channel extending from the first end of the first rotation stage to the second end of the first rotation stage, and the second rotation stage includes a second optical fiber channel extending from the third end of the second rotation stage to the fourth end of the second rotation stage.

Abstract: A system for determining the profile of a laser beam includes a detector having a thermochromic liquid crystal film (TLCF) in thermal communication with a heat spreader and a thermoelectric cooler. The liquid crystal film has a thermochromic response such that heating of the film by a received laser beam creates a detectable color response at the film. The system also includes an image sensor and a controller configured to output an operating current for the TEC and receive images from the sensor. The system can selectively vary the temperature set point of the TEC to change the steady state temperature of the TLCF to examine the full intensity profile of the received beam even when the temperature response bandwidth of the TLCF is too narrow to display the full beam profile in a single color spot.

Abstract: A jewelry box removably coupled to a handset for recording the image of a person opening the jewelry box or a person to whom the open jewelry box is presented.