Abstract: Example fiber optic enclosures include a cable spool assembly and a cover. Each disc of the cable spool assembly has a removable section that extends radially outwardly from a central portion of the disc. The cable spool assembly has a first diameter when the removable sections are attached to the discs. The central portion of each disc has a second diameter. The cover has a lateral dimension that is smaller than the first diameter of the cable spool assembly and larger than the second diameter of the cable spool assembly. Certain types of spool assemblies include a termination region including a plurality of adapters that rotate in unison with the first disc of the cable spool assembly.

Abstract: A fiber optic enclosure includes a housing including a base and a cover that cooperatively define an interior region of the housing; and a cable spool assembly rotatably disposed in the interior region of the housing. The cable spool includes a drum portion; and a tray assembly engaged to the drum portion and configured to rotate in unison with the drum portion when the cable spool assembly is rotated relative to the base. The tray assembly includes at least a first tray. Each tray includes optical adapters disposed in a row along a first end of the tray. Certain types of trays are pivotal relative to the drum portion along a pivot axis extending generally parallel to the row of adapters along a second end of the tray opposite the first end. Other types of trays include a second row of optical adapters that pivot relative to the first row.

Abstract: A drop terminal mounting system includes a fiber drop terminal having a housing and a base attached to the housing. The housing includes an outer surface containing a plurality of receptacles and cooperatively defines an inner cavity with the base. The drop terminal mounting system further includes a bracket having a first fastening region and a second fastening region adapted to secure the drop terminal to the bracket.

Abstract: In one embodiment, a media converter comprises a power interface that extracts power from a communication medium coupled to the media converter for powering the media converter. In another embodiment, a connector comprises a first media attachment interface to physically attach a first communication medium to the connector and a second media attachment interface to physically attach a second communication medium to the connector. The connector further comprises a mounting interface to physically attach the connector to a structure. The connector communicatively couples the first communication medium and the second communication medium. The connector processes management data communicated over at least one of the first communication medium and the second communication medium.

Abstract: Systems and methods for distributed antenna system reverse path summation using signal-to-noise ratio optimization are provided. In one embodiment, a method for reverse path summation for a distributed antenna system comprises: normalizing an uplink noise floor for a plurality of remote antenna units of a distributed antenna system, wherein the uplink noise floor is normalized based on a first remote antenna unit having a lowest noise floor of the plurality of remote antenna units; and scaling an uplink output gain of each of the plurality of remote antenna units by a scaling factor, wherein the scaling factor attenuates the uplink output gain based on a composite maximum host peak power for a host unit coupled to the plurality of remote antenna units.

Abstract: The invention relates to a terminal box (1) for fiberoptic cables, comprising an at least two-part housing with a lower part (3) and a cover (2), the cover (2) being arranged pivotably on the lower part (3), at least one receptacle for a splice, at least one feed (10) for a fiberoptic cable and a receptacle (11) for a coupling, the side faces (5, 6) of the cover (2) being longer than the end faces (7, 8) of the cover (2), a pivot bearing of the cover (2) being arranged on an end face (8) of the cover (2), and to a panel for accommodating a terminal box (1) for fiberoptic cables.

Abstract: A method for programming the delay for a node in a communication system is disclosed. The node receives a selected delay value and a signal path delay value indicating a delay for signals communicated to the node. The signal path delay comprises an aggregation of transport delays calculated by each node for segments of the communication system between the node and a host node. The method further calculates an additional delay necessary to meet the selected delay value.

Abstract: An example fiber optic cable includes an outer jacket having an elongated transverse cross-sectional profile defining a major axis and a minor axis. The transverse cross-sectional profile has a maximum width that extends along the major axis and a maximum thickness that extends along the minor axis. The maximum width of the transverse cross-sectional profile is longer than the maximum thickness of the transverse cross-sectional profile. The outer jacket also defines first and second separate passages that extend through the outer jacket along a lengthwise axis of the outer jacket. The second passage has a transverse cross-sectional profile that is elongated in an orientation extending along the major axis of the outer jacket. The fiber optic cable also includes a plurality of optical fibers positioned within the first passage a tensile strength member positioned within the second passage.

Abstract: Fault detection and response systems and processes can be used for pumps, e.g., pump/motors used in hybrid vehicles. The fault detection systems determine when certain operating conditions, which may affect the proper operation of the system, occur. The response systems take appropriate action based on which fault conditions are triggered. Example fault detection systems and processes include detection systems for different types of leaks, sensor malfunctions, or operation errors.

Abstract: The present disclosure relates to a drop cable assembly including a fiber optic drop cable having a length that extends from a first end of the fiber optic drop cable to an opposite second end of the fiber optic drop cable. The fiber optic drop cable also includes an intermediate location located between the first and second ends of the fiber optic drop cable. The drop cable assembly also includes a first fiber optic connector mounted at the first end of the fiber optic drop cable and a second fiber optic connector mounted at the second end of the fiber optic drop cable. The drop cable assembly further includes an optical fiber that extends continuously without splicing along the length of the fiber optic drop cable from the first fiber optic connector to the second fiber optic connector.

Abstract: A method for installing a drop terminal includes providing a drop terminal assembly including a drop terminal having an exterior surface, a first cable spool engaged to the exterior surface of the drop terminal, a second cable spool engaged to the first cable spool and a fiber optic cable having a first length disposed about the first cable spool and a second length disposed about the second cable spool. The drop terminal assembly is rotated to deploy the second length of fiber optic cable. The second cable spool is removed. The first length of fiber optic cable is bundled. The bundled first length of fiber optic cable is removed from the first cable spool. The drop terminal is removed from the first cable spool.

Abstract: A fiber distribution hub includes a cabinet; a termination region positioned within the interior of the cabinet; at least one termination module mounted in at least one opening defined at the termination region; fiber optic connectors coupled to termination adapters of the termination module; intermediate fibers extending rearwardly of the fiber optic connectors; and a multi-fiber connector terminating the intermediate fibers. The termination module includes a housing enclosing the termination adapters. One or more termination modules can be incrementally added to the fiber distribution hub.

Abstract: An optical fiber distribution assembly is disclosed. The assembly includes an enclosure formed by a circular base and a cover joined at a waterproof seal. The base includes openings configured to accept an input cable and an output cable. The assembly also includes an inner body formed by four panel members to define four quadrants. In one example, the inner body is formed by two panel members positioned perpendicularly to one another. Disposed on the inner body are plurality of cable management structures including: radius limiters, splice trays, splitters, terminations, and connector storage holders.

Abstract: A merchandise checkout system for ringing up merchandise in a grocery or other retail facility is disclosed. The merchandise checkout system includes visual sensors for acquiring images of an object to be rung up at checkout; a database configured to retain a visual model and UPC code of known items; and a processor configured to maintain and update the database with information about new merchandise presented for checkout. The visual model preferably includes at least one image of each item of merchandise in the retail store as well as geometric point features extracted from images of the merchandise. The processor in the exemplary embodiment is configured to: (a) compare the image of the object acquired at checkout to the visual model of the items in the database; (b) recognize the object based on the overall appearance of the packaging; (c) automatically ring up the price of the object at the POS; and (d) automatically add the acquired image to the database if the image of the object is new, i.e.

Abstract: A tray assembly for a fiber optic enclosure includes a mounting bracket having a first bracket, a second bracket and a divider panel. The first bracket is configured for mounting to a fiber optic enclosure. The first bracket defines a pivot axis. The second bracket is engaged to the first bracket and is adapted to pivot about the pivot axis between a closed position and an open position. The divider panel is engaged to the first bracket and is adapted to pivot about the pivot axis between a closed position and an open position. The tray assembly further includes a first set of trays engaged to the second bracket and a second set of trays engaged to the divider panel. The divider panel is disposed between the first and second sets of trays.

Abstract: A telecommunications patch panel is provided having a plurality of connector modules rotatably mounted to a frame member. Each connector module has a front face and an opposite facing rear face, and each front face includes a plurality of connector jacks. Each rear face includes a plurality of wire termination blocks. The wire termination blocks are electrically connected to the connector jacks. Each connector module is rotatable about a rotation axis relative to the frame member. A lock selectively locks each connector module to the frame member as desired. The connector jacks and the connector modules are arranged in linear arrays perpendicular to the axis of rotation.

Abstract: A telecommunications assembly includes a chassis with a top wall, a bottom wall, a front opening, a rear opening, and first and second transverse sidewalls extending between the front and rear openings, the top wall and bottom walls defining slots. Upper mounting guides defining upper key slots between adjacent upper guides and lower mounting guides defining lower key slots between adjacent lower guides are mounted to the top and bottom walls. The upper and lower guides define snap-fit structures inserted into the slots defined on the top and bottom walls for mounting the upper and lower guides to the chassis. At least one of the upper and the lower mounting guides defines adapter mounts for slidably receiving fiber optic adapters through the rear opening. Fiber optic modules are slidably received within the chassis through the front opening and each module is slidably inserted into the upper and lower key slots of the chassis, each module removable from the chassis through the front opening.

Abstract: A bulkhead adapter plate that mounts to a face panel of a cable management panel, and a method of making the bulkhead adapter plate. The plate including angled adapter mounting openings formed by performing a minimum number of bending operations.

Abstract: A fiber optic enclosure includes a housing and a cable spool assembly disposed on an exterior surface of the housing. The cable spool assembly has a first tear-away end and a second tear-away end. The first and second tear-away ends include at least one area of weakness extending from an inner diameter of the cable spool assembly to an outer diameter of the cable spool assembly. A mounting plate is rotationally engaged with the cable spool assembly such that the cable spool assembly and the housing selectively and unitarily rotate about an axis of the mounting plate.

Abstract: Systems for dynamic reallocation of bandwidth and modulation protocols is provided. In one embodiment, a radio head interface module comprises: a transmit buffer adapted to receive a data stream from a signal processing module and store the data stream as a page of data samples having a page header; a transmit engine; a digital upconverter, the transmit engine adapted to transfer the page of data samples from the transmit buffer to the digital upconverter; a configuration management unit adapted to receive reconfiguration information from the signal processing module, the reconfiguration information including at least one of air interface protocol parameters and bandwidth allocation information; and a memory adapted with digital upconverter parameters. The configuration management unit is accesses the memory to lookup associated digital upconverter parameters based on the reconfiguration information.