Abstract: Embodiments include creating an immersive environment for media playback by synchronizing devices. Aspects include receiving a playback tag set associated with a media item, each tag includes a respective condition, a respective attribute and a respective value of the attribute. Aspects also include determining that the first condition of the first tag is met and instructing one or more devices to apply the first value of the first tag to the first attribute of the first tag. Aspects further include determining that a first device has left a viewing area and tracking a location of the first device. Aspects also include identifying a second device in proximity to the first device and receiving an outside tag set associated with the media item. Aspects further include instructing the second device to apply the first outside value of the first outside tag to the first outside attribute of the first outside tag.

Abstract: A fiber optic mechanical splice connector including a single connector element operable for providing optical fiber alignment and strain relief includes opposed splice components that define first and second grooves for receiving the bare glass portions of mating optical fibers, as well as the coated or buffered portion of at least one of the optical fibers when the splice components are biased together by an actuator. The mating optical fibers are aligned while the coated or buffered portion of one of the optical fibers is retained within the same connector element, thus eliminating positioning problems that occur when separate connector elements are utilized for fiber alignment and strain relief. The splice components may be unbiased to allow removal of at least one of the mating optical fibers without destroying the connector assembly or potentially damaging the optical fibers.

Abstract: The present invention addresses the need for a stress relieving device and protective jacket for exposed fiber within a field-installed optical network enclosure, such as a network interface device. The present invention incorporates a furcation tube coupled with a furcation body. The coupling may be accomplished by a direct connection or with use of an external or internal transition body. The present invention enables a field-installer to transition an optical fiber cable from the field into a furcation tube thereby providing a means for attaching an optical connector, such as a mechanical splice connector, onto the optical fiber and furcation tube.

Abstract: A fiber optic mechanical splice connector including a single connector element operable for providing optical fiber alignment and strain relief includes opposed splice components that define first and second grooves for receiving the bare glass portions of mating optical fibers, as well as the coated or buffered portion of at least one of the optical fibers when the splice components are biased together by an actuator. The mating optical fibers are aligned while the coated or buffered portion of one of the optical fibers is retained within the same connector element, thus eliminating positioning problems that occur when separate connector elements are utilized for fiber alignment and strain relief. The splice components may be unbiased to allow removal of at least one of the mating optical fibers without destroying the connector assembly or potentially damaging the optical fibers.

Abstract: A mechanical splice connector is shown and described for sequentially performing a splice actuation followed by a strain relief actuation by rotating a single, multiple-position cam member or multiple cam members from an unactuated position to a first actuated position and a second actuated position. The mechanical splice connector aligns and retains at least one stub optical fiber and the bare glass portion of at least one adjoining field optical fiber, as well as strain relieving a coated portion of the field optical fiber, or alternatively, a buffered portion of the field optical fiber. A method is also described for sequentially performing a splice actuation followed by a strain relief actuation, wherein the splice actuation is reversible prior to performing the strain relief actuation in the event that the optical continuity of the splice coupling is unacceptable, thereby avoiding potential damage to the field optical fiber or the connector.

Abstract: A cam member having a specific interior geometry for applying a force to alignment components of a mechanical splice fiber optic connector. A cam member defining an interior surface having a decreasing diameter transition from a cam member un-actuated position to an actuated position without an intermediate position having a diameter greater than the actuated position diameter. A cam member defining an un-actuated diameter and an actuated diameter, wherein the un-actuated diameter is greater than the actuated diameter in both un-actuated and actuated positions of the cam member. A flexible and resilient cam member for use in a fiber optic connector that maintains specific diametral relationships while maintaining a splice force.

Abstract: A field installable optical fiber connector includes a connector housing, a ferrule, a ferrule holder, a splice holder, splice components and a cam member. The splice holder is disposed within the connector housing and defines a first cavity adjacent the forward end and a second cavity adjacent the rearward end. The ferrule holder is fixedly disposed within the first cavity and defines a recess adjacent the forward end. The ferrule is fixedly disposed within the recess and defines a longitudinal bore for receiving an optical fiber stub. The splice components are disposed within the second cavity and configured to receive and secure the optical fiber stub to a field fiber when the cam member disposed about the splice holder is actuated. The splice holder is made of a plastic material and the ferrule holder is made of a metal material to simultaneously satisfy cost, capacity, geometry, strength and machining requirements.

Abstract: A field installable fiber optic connector includes a housing and a ferrule holder inserted from the rearward end of the housing. A spring element inserted into the front of the housing and a spring element retainer attached to the ferrule holder bias the ferrule holder forward. An optical fiber stub is disposed between opposed splice members and a field fiber is inserted between the splice members and guided by a groove into abutment with the end of the optical fiber stub. A cam disposed about the ferrule holder is movable to facilitate insertion of the field fiber and to clamp the field fiber and the optical fiber stub between the splice members. In one embodiment, a trigger is coupled to the housing. The trigger is disposed about and slides relative to the ferrule holder, thereby biasing the housing forward relative to the ferrule holder to aid in latching the connector.

Abstract: A field installable fiber optic connector includes a housing, a spring element seat and a ferrule holder that is inserted from the rearward end of the housing. A spring element inserted into the front of the housing abuts the spring element seat. A spring element retainer attached to the ferrule holder abuts the forward portion of the spring element to compress the spring element and bias the ferrule holder forward. An optical fiber stub disposed between opposed splice members in an aligning groove terminates intermediate the ends of the splice members. An optical fiber is inserted between the splice members and guided by the groove into abutment with the end of the optical fiber stub. A cam disposed about the ferrule holder is movable to facilitate insertion of the optical fiber and to clamp the optical fiber and the optical fiber stub between the splice members.

Abstract: Methods are provided for validating the continuity of one or more optical fibers upon which a fiber optic connector is mounted. Typically, the fiber optic connector is mounted upon an optical field fiber by actuating a cam mechanism to secure the optical field fiber in position relative to an optical fiber stub. If subsequent testing indicates that the continuity of the optical field fiber and the optical fiber stub is unacceptable, the cam mechanism can be deactuated, the optical field fiber can be repositioned and the cam mechanism can be reactuated without having to remove and replace the fiber optic connector.