Abstract: Apparatus and methods are described herein for cleaving an optical element at a defined distance from a splice (or other reference point/feature) of the optical element within a desired precision and/or accuracy. In some embodiments, a method includes receiving an indication of a location of a feature in an intermediate optical assembly visible within an image of the intermediate optical assembly. The feature can be for example, a splice. A position of the intermediate optical assembly is translated relative to a cleave unit based on the indication. After translating, the intermediate optical assembly, the intermediate optical assembly is cleaved to form an optical assembly that has an end face at a location disposed at a non-zero distance from the location of the feature. In some embodiments, the location of the feature can be determined with an image recognition system.

Abstract: Apparatus and methods are described herein for cleaving an optical element at a defined distance from a splice (or other reference point/feature) of the optical element within a desired precision and/or accuracy. In some embodiments, a method includes receiving an indication of a location of a feature in an intermediate optical assembly visible within an image of the intermediate optical assembly. The feature can be for example, a splice. A position of the intermediate optical assembly is translated relative to a cleave unit based on the indication. After translating, the intermediate optical assembly, the intermediate optical assembly is cleaved to form an optical assembly that has an end face at a location disposed at a non-zero distance from the location of the feature. In some embodiments, the location of the feature can be determined with an image recognition system.

Abstract: Apparatus and methods are described herein for cleaving an optical element at a defined distance from a splice (or other reference point/feature) of the optical element within a desired precision and/or accuracy. In some embodiments, a method includes receiving an indication of a location of a feature in an intermediate optical assembly visible within an image of the intermediate optical assembly. The feature can be for example, a splice. A position of the intermediate optical assembly is translated relative to a cleave unit based on the indication. After translating, the intermediate optical assembly, the intermediate optical assembly is cleaved to form an optical assembly that has an end face at a location disposed at a non-zero distance from the location of the feature. In some embodiments, the location of the feature can be determined with an image recognition system.

Abstract: In some embodiments, a non-transitory processor-readable medium storing code includes code to cause a processor to receive an image signal associated with an image of an end face of a polarization-maintaining optical fiber (PM fiber), determine a center position of the PM fiber, perform a local image equalization on the end face, and define an edge map of the end face. The code can perform a Hough space analysis on the edge map to determine the center position of a first structure and/or a second structure on the end face. The first structure and the second structure can each define at least in part a birefringence of the PM fiber. A birefringence axis of the PM fiber can be calculated based on at least two of the center position of the PM fiber, the center position of the first structure and the center position of the second structure.

Abstract: In some embodiments, a non-transitory processor-readable medium storing code includes code to cause a processor to receive an image signal associated with an image of an end face of a polarization-maintaining optical fiber (PM fiber), determine a center position of the PM fiber, perform a local image equalization on the end face, and define an edge map of the end face. The code can perform a Hough space analysis on the edge map to determine the center position of a first structure and/or a second structure on the end face. The first structure and the second structure can each define at least in part a birefringence of the PM fiber. A birefringence axis of the PM fiber can be calculated based on at least two of the center position of the PM fiber, the center position of the first structure and the center position of the second structure.