Described herein are coated optical fibers including an optical fiber portion, wherein the optical fiber portion includes a glass core and cladding section that is configured to possesses certain mode-field diameters and effective areas, and a coating portion including a primary and secondary coating, wherein the primary coating is the cured product of a composition that possesses specified liquid glass transition temperatures, such as below 82 C., and/or a viscosity ratios, such as between 25 C. and 85 C., of less than 13.9. Also described are radiation curable coating compositions possessing reduced thermal sensitivity, methods of coating such radiation curable coating compositions to form coated optical fibers, and optical fiber cables comprising the coated optical fibers and/or radiation curable coating compositions elsewhere described.

Generally disclosed herein is an optical cable assembly a casing that defines a storage space, the casing having a first through hole at a first end and a second through hole at the second end, a first arrayed waveguide grating (AWG) disposed in the storage space, a second AWG disposed in the storage space, a first optical cable comprising at least one transmission optical fiber connected to a first end of the first and second AWGs, a second optical cable comprising at least one transmission optical fiber connected to a second end of the first and second AWGs, wherein the first and second AWGs are disposed substantially parallel with each other and substantially parallel with a longitudinal axis of the casing such that each of the first and second AWGs have a first end proximate the first through hole and a second end proximate the second through hole.

A medical optical fiber guidewire converter includes a first connector; a second connector; a conversing optical fiber with an overcurrent channel configured to transmit laser light and including a first and second optical fibers and a connecting optical fiber, a diameter of the first optical fiber is greater than that of the second optical fiber, the first optical fiber is connected to the first connector, and the second optical fiber is connected to the second connector; and a heat sink on the conversing optical fiber. The medical optical fiber guidewire converter couples optical fiber guidewires with different core diameters using the connecting optical fiber, thereby ensuring safety and reliability of laser light transmission in the overcurrent channel. The heat sink can absorb laser light overflowing from the conversing optical fiber and dissipate heat therefrom to reduce the temperature of and avoid thermal damage to the conversing optical fiber.

Fiber optic connectors and connectorized fiber optic cables include connector housings having locking portions defined on the connector housing that allow the connector housing to be selectively coupled to a corresponding push-button securing member of a multiport assembly. Methods for selectively connecting a fiber optic connector to and disconnecting the fiber optic connector from the multiport assemblies allow for connector housings to be forcibly and nondestructively removed from the multiport assembly.

Described herein are coated optical fibers including an optical fiber portion, wherein the optical fiber portion includes a glass core and cladding section that is configured to possesses certain mode-field diameters and effective areas, and a coating portion including a primary and secondary coating, wherein the primary coating is the cured product of a composition that possesses specified liquid glass transition temperatures, such as below 82 C., and/or a viscosity ratios, such as between 25 C. and 85 C., of less than 13.9. Also described are radiation curable coating compositions possessing reduced thermal sensitivity, methods of coating such radiation curable coating compositions to form coated optical fibers, and optical fiber cables comprising the coated optical fibers and/or radiation curable coating compositions elsewhere described.

A fiber optic connector comprises an outer housing, an inner housing installed in the outer housing, a fiber optic ferrule accommodated in the inner housing, an optical cable inserted into the inner housing and connected to the fiber optic ferrule, an elastic boot that is wrapped around both a connecting portion of the fiber optic ferrule connecting to the optical cable and a portion of the optical cable adjacent to the connecting portion, and a sealing structure. The sealing structure is disposed between a rear end portion of the outer housing and the elastic boot to provide a seal between the outer housing and the elastic boot.

In one embodiment, a system includes a central hub comprising a power source, a data switch, a coolant system, and a management module, a plurality of network devices located within an interconnect domain of the central hub, and at least one combined cable connecting the central hub to the network devices and comprising a power conductor, a data link, a coolant tube, and a management communications link contained within an outer cable jacket.

Fiber optic connectors and connectorized fiber optic cables include connector housings having locking portions defined on the connector housing that allow the connector housing to be selectively coupled to a corresponding push-button securing member of a multiport assembly. Methods for selectively connecting a fiber optic connector to, and disconnecting the fiber optic connector from the multiport assemblies allow for connector housings to be forcibly and nondestructively removed from the multiport assembly.

A fiber optic distribution cable includes a central inner jacket formed from one of a polyvinyl chloride or a low smoke zero halogen material, a plurality of optical fibers disposed within the inner jacket, and a plurality of first strength members disposed within the inner jacket. The fiber optic distribution cable further includes an outer jacket surrounding the central inner jacket, the outer jacket formed from the one of the polyvinyl chloride or the low smoke zero halogen material, and a plurality of second strength members disposed between the outer jacket and the central inner jacket. A fiber density of the cable is greater than 0.65 fibers per square millimeter.

Various aspects described herein relate to a machine learning based detecting of fracture hits in offset monitoring wells when designing hydraulic fracturing processes for a particular well. In one example, a computer-implemented method includes receiving a set of features for a first well proximate to a second well, the second well undergoing a hydraulic fracturing process for extraction of natural resources from underground formations; inputting the set of features into a trained neural network; and providing, as output of the trained neural network, a probability of a fracture hit at a location associated with the set of features in the first well during a given completion stage of the hydraulic fracturing process in the second well.