Abstract: An apparatus and method for connectivity in networks configured for non-disruptive disconnection of one or more peripheral devices are disclosed. The apparatus includes a first logical layer associated with a first peripheral device, the first peripheral device arranged in a network configured for non-disruptive disconnection of at least one peripheral device, at least a second logical layer associated with at least a second peripheral device, the at least a second peripheral device arranged in the network configured for non-disruptive disconnection of at least one peripheral device, at least one power source associated with the first logical layer and the at least a second logical layer, and a first electrically conductive link coupled to the first logical layer, the at least a second logical layer, and the at least one power source associated with the first logical layer and the at least a second logical layer.

Abstract: Disclosed are full-bridge power converters providing DC output power at increased conversion efficiencies, and methods of operating full-bridge power converters providing DC output power at increased conversion efficiencies. In disclosed embodiments, the switches of the full-bridge are operated to reduce conduction losses and to provide for zero-voltage switching.

Abstract: Methods and systems for reconfiguring communications systems are provided. In one embodiment, a radio head interface for a communications system comprises: a first interface for communicating with a signal processing module digitally performing waveform processing to modulate and demodulate radio signals; a second interface for communicating with a radio head for transmitting and receiving wireless radio signals; a first buffer coupled to the first interface for receiving a page of data from the signal processing module, the page of data comprising a page header for communicating reconfiguration parameters and a plurality of digital radio frequency samples representing a modulated radio signal; at least one digital frequency converter coupled to the second interface; and a configuration management unit, the configuration management unit adapted to receive the reconfiguration parameters from the page header and reconfigure the at least one digital frequency converter based on the reconfiguration parameters.

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: A method for thermal management is provided. The method includes providing thermal isolation between at least one high-power thermally tolerant electronic component and at least one low-power thermally sensitive electronic component housed within an electrical enclosure, providing a first conductive path from the at least one low-power electronic component to a first heatsink, providing a second conductive path from the at least one high-power electronic component to a second heatsink, dissipating heat generated by the at least one low-power thermally sensitive electronic component and dissipating heat generated by the at least one high-power thermally tolerant electronic component to an environment external to the electrical enclosure by channeling the heat generated by the at least one low-power thermally sensitive electronic component and the at least one high-power thermally tolerant electronic component along the first and second conductive path, respectively.

Abstract: A system for transceiving radio frequency signals is provided. The system includes a multiplexing apparatus at a base of a tower and communicatively coupled to a cable, and a low noise amplifier at the base of the tower. The multiplexing apparatus includes a transmitter path, a portion of a receiver path, and a transceiver path portion. The low noise amplifier is operable to amplify signals in a first spectral region and is communicatively coupled to the multiplexing apparatus. The multiplexing apparatus is configured to pass signals in the first spectral region between the cable and a first-band base transceiver station via the low noise amplifier. The multiplexing apparatus is further configured to pass signals in a second spectral region between the cable and at least one second-band base transceiver station.

Abstract: Optical systems for sensing radiation emissions from radiological and nuclear matter. An example system includes a light source, a light sensor, a processing device in signal communication with the light source and the light sensor, and a fiber optic cable that receives light from the light source and delivers light to the light sensor. The fiber optic cable includes an optical fiber core region surrounded by a cladding region. The optical fiber is a single mode optical fiber having a mode field diameter greater than 25 ?m. The optical fiber cladding region includes a plurality of lengthwise holes positioned to provide single mode light propagation properties. The plurality of lengthwise holes have a diameter between 0.1-5 ?m.

Abstract: An adaptable virtual network system comprises a plurality of network elements and a plurality of virtual links. Each network element is communicatively coupled to at least one other network element via at least one physical link. At least one physical link comprises at least two virtual links. The adaptable virtual network system supports at least two virtual networks, each virtual network comprising at least one virtual link communicatively coupling at least two network elements.

Abstract: A network for a dual lane control system is provided. The network comprises at least one hub for a first channel and at least one hub for a second channel. A first plurality of end nodes is in a first lane. Each of the first plurality of end nodes is coupled to the first and second channels by being in communication with the hubs for the first and second channels. A second plurality of end nodes in a second lane are each redundant with a respective end node in the first lane. Each of the second plurality of end nodes is coupled to the first and second channels by being in communication with the hubs for the first and second channels.

Abstract: A wireless sensor network comprises a plurality of nodes that communicate over wireless communication links. At least one of the plurality of nodes receives sensor data from a sensor. The wireless sensor network is queried by specifying a set of events of interest. For each event of interest included in the set of events of interest, a producer node included in the plurality of nodes identifies when that event of interest occurs and, when that event of interest occurs, transmits event data related to that event of interest to a consumer node included in the plurality of nodes. The wireless sensor network further comprises a data management stack that comprises a plurality of layers. The plurality of layers comprises an execution layer that executes on each producer node included in the plurality of nodes. For each event of interest included in the set of events of interest, the execution layer executing on the producer node for that event of interest identifies when that event of interest occurs.

Abstract: In a transceiver, a transmitter circuit is provided substantially the same common-mode voltage regardless of whether the transceiver is in a transmitting or receiving mode. In one embodiment, the transmitter circuit includes a driver circuit which, in the transmission mode of the transceiver, drives an output differential signal, and which, in the receiving mode of the transceiver, provides a termination circuit for an input differential signal. A variable resistor is provided to connect between a supply voltage and the driver circuit, the resistance of the variable resistor is selected such that the common-mode voltage of the output differential signal of the transmission mode substantially equals the common-mode voltage in the input differential signal of the receiving mode.

Abstract: A navigation system and method for gyrocompass alignment in a mobile object. The system includes an inertial measurement device configured to provide a first set of sensor data and a positioning unit configured to provide a second set of data. In an example embodiment, the navigation system includes a processing device configured to receive the data sets provided by the inertial measurement device and the positioning device, and the processing device is configured to dynamically calibrate the received first data set the processing device includes a Kalman filter, and the processing device is further configured to generate a gyrocompass alignment using the first dynamically calibrated first data set, the second data set, and the Kalman filter. The method includes receiving sensor data from a plurality of sensors, dynamically calibrating at least a portion of the sensor data, and generating gyrocompass alignment information based on the dynamically calibrated sensor data.

Abstract: A method of stabilizing heading in an inertial navigation system includes operating an inertial measurement unit comprising horizontal-sensing elements and off-horizontal-sensing elements while the inertial measurement unit is in a first orientation, calibrating the horizontal-sensing elements of the inertial measurement unit based on horizontal aiding measurements, forward-rotating the inertial measurement unit by a selected-rotation angle about a horizontal-rotation axis so that the inertial measurement unit is oriented in a second orientation, operating the forward-rotated inertial measurement unit while the inertial measurement unit is in the second orientation, and calibrating the rotated off-horizontal-sensing elements based on horizontal aiding measurements while the inertial measurement unit is in the second orientation. When the inertial measurement unit is in the first orientation, the horizontal-sensing elements are oriented in a horizontal reference plane.

Abstract: A method of fabricating a multi-axis sensor is provided. The method includes forming patterns of sacrificial material overlaying a substrate and overlaying a flexible material on the sacrificial material and an anchor-surface of the substrate. The flexible material includes sensor-regions, an anchor-region, and at least one hinge-region. The method further includes forming sensor elements from orientable sensor material overlaying respective sensor-regions of the flexible material; forming at least one respective anchor-hinge in the flexible material along the boundary between the anchor-region and an adjacent sensor region; forming the sensor-regions, the anchor-region, and the at least one hinge-region in the flexible material; training the sensor elements to form respective oriented-sensor elements that are oriented in the same direction; etching the sacrificial material; and etching the substrate at an angle from the anchor-surface.

Abstract: A relative navigation system and method are disclosed. The relative navigation system includes a first sensor unit responsive to a motion of a first position, a second sensor unit responsive to a motion of a second position, and a first processing unit associated with at least one of the first sensor unit and the second sensor unit and communicatively coupled to the first sensor unit and the second sensor unit. The first processing unit is configured to generate relative navigation solution information associated with first sensor unit information and second sensor unit information.

Abstract: Systems and methods for passive thermal management using phase change material are provided. In one embodiment, a thermal management method is provided. The method comprises securing an electronics assembly to a mounting surface using a thermally insulative support structure; insulating a phase change material within the support structure; and melting the phase change material to reduce heat transfer from an external environment to the electronics assembly during a high temperature transient thermal condition.

Abstract: A navigation system for a vehicle having a receiver operable to receive a plurality of signals from a plurality of transmitters includes a processor and a memory device. The memory device has stored thereon machine-readable instructions that, when executed by the processor, enable the processor to determine a set of error estimates corresponding to pseudo-range measurements derived from the plurality of signals, determine an error covariance matrix for a main navigation solution using ionospheric-delay data, and, using a parity space technique, determine at least one protection level value based on the error covariance matrix.

Abstract: A reconfigurable radio communication subsystem is provided comprising a first radio communication unit communicatively coupled to a first antenna and a second antenna, and a second radio communication unit communicatively coupled to a third antenna and the first or second antenna. The first, second, and third antennas are operable in a first frequency band. The subsystem includes a first antenna subsystem coupled to the first radio communication unit and a fourth antenna operable in a second frequency band, and a second antenna subsystem coupled to the second radio communication unit and the fourth antenna. The first and second radio communication units include reconfigurable voice/data functions operating in the first frequency band, voice/data functions operating in the second frequency band, and a radio communications system management function. Cross-connecting buses couple the first radio communication unit and the second radio communication unit.

Abstract: A shelf assembly for a confined space formed within a structure is provided. The shelf assembly includes a fixed portion having a structure attachment interface to fixedly attach the shelf assembly to the structure and a slideable portion that is operable to slide out and extend from the fixed portion of the shelf assembly. The slideable portion has an enclosure attachment interface to attach an electronics enclosure to the slideable portion of the shelf assembly. The slideable portion has a first state and a second state in which the slideable portion is held in a first position or second position, respectively. In the first state, the entire slideable portion of the shelf assembly is positioned within the structure. In the second state, at least the enclosure attachment interface is positioned outside of the structure.

Abstract: A micro-electromechanical systems (MEMS) device includes a substrate comprising at least one anchor, a proof mass having first and second deceleration extensions extending therefrom, a motor drive comb, a motor sense comb, a plurality of suspensions configured to suspend the proof mass over the substrate and between the motor drive comb and the motor sense comb. The suspensions are anchored to the substrate. A body is attached to the substrate. At least one deceleration beam extends from a first side of said body. The at least one deceleration beam is configured to engage at least one of the first and second deceleration extensions and slow or stop the proof mass before the proof mass contacts the motor drive comb and the motor sense comb.