Abstract: A method is for making an electrical inductor. The method includes forming a first subunit having a sacrificial substrate, and an electrically conductive layer defining the electrical inductor and including a first metal on the sacrificial substrate. The method includes forming a second subunit having a dielectric layer and an electrically conductive layer thereon defining electrical inductor terminals and having the first metal, and coating a second metal onto the first metal of one of the first and second subunits. The method includes aligning the first and second subunits together, heating and pressing the aligned first and second subunits to form an intermetallic compound of the first and second metals bonding adjacent metal portions together, and removing the sacrificial substrate.

Abstract: A plurality of wireless engine sensors each includes a sensing circuit that senses an engine parameter as engine data. A radio transceiver receives and transmits the engine data regarding the sensed engine parameters. An engine monitoring module includes a housing configured to be mounted at the aircraft engine. A sensor receiver is mounted within the housing and receives the engine data from the wireless engine sensors. A first wireless transmitter is carried by the housing. A memory is carried by the housing and a processor is carried by the housing and coupled to the memory and the first wireless transmitter and configured to collect and store in the memory engine data related to engine parameters sensed during operation of the aircraft engine by the plurality of wireless engine sensors and transmit the engine data via the first wireless transmitter.

Abstract: Systems (1900) and methods (2300, 2400) for use in a network node (1901-1903). The methods involve: receiving a Data Communication (“DC”) from Data Link Layer Software (“DLLS”); identifying an IDentity Parameter (“IDP”) contained in DC which comprises a False Value (“FV”) specifying false information about the node or DC; obtaining a True Value (“TV”) specifying true information about the node or DC; replacing the FV with the TV to generate a modified DC; and forwarding the modified DC to Network Layer Software (“NLS”). The methods also involve: receiving a Data Unit (“DU”) from NLS comprising a Transport Layer Header (“TLH”) and a Network Layer Header (“NLH”) including TVs specifying true information about the node or FDU; obtaining a FV which specifies false information about the node or FDU; replacing a TV of DU with the FV so as to form a Modified Data Unit (“MDU”); and forwarding MDU to DLLS.

Abstract: System (201) for mitigating co-site interference includes a co-site filter bank (208) containing filters (2061, 2062, . . . 206n) which can be optionally selectively inserted in an antenna input/output path (2051, 2052, . . . 205n) of two or more transceivers (2041, 2042, . . . 204n). A control system (900) receives information concerning the transceivers. Based on the information, the control system determines whether optional RF filtering should be used to limit RF signals which are communicated to or from the transceivers so as to mitigate co-site interference.

Abstract: A system for preventing discomfort to a user of a robotic exoskeleton (200) determines the existence of an exoskeleton operating condition which has the potential to cause at least one of a discomfort or an injury to a user (204) when the exoskeleton is being worn by the user. Responsive to the determining, an exoskeleton control system (224) selectively controls at least one viscous coupling (208, 210) disposed at an interface location (201, 203) of the exoskeleton where a physical interaction occurs between a portion of the user and a portion of the exoskeleton when the exoskeleton is in use. The control system selectively varies a viscosity of a fluid (216) comprising the viscous coupling to control the stiffness of the interface.

Abstract: Systems (100) and methods (300) for efficient video analysis. The methods involve: automatically identifying features of at least one feature class which are contained in a first video stream; simultaneously generating a plurality of first video chips (904) using first video data defining the first video stream; displaying an array comprising the first video chips within a graphical user interface window; and concurrently playing the first video chips. Each of the first video chips comprises a segment of the first video stream which includes at least one identified feature.

Abstract: Embodiments of phase shifters (10) include electrical conductors (34) suspended within an electrically-conductive housing (28), and a shuttle (16) having an electrically-conductive plate (74) that provides a variable capacitance between a ground potential and the electrical conductor (34) when the shuttle (16) is moved between a first and second position. The plate (74) is electrically connected to a ground plane (27) of the phase shifter (10) by adjacent electrically-conductive portions (54, 55b, 53a) of the shuttle (16).

Abstract: System and methods for providing a cognitive network (300). The methods involve generating Initialization Parameters (“IPs”) for a first Multi-Objective Optimization (“MOO”) algorithm based on project requirements; determining a first Pareto Front (“PF”) for a first Protocol Stack Layer (“PSL”) of a protocol stack by solving the first MOO algorithm using IPS (450, 550); initialize or constrain a second MOO algorithm using the first PF (100); determining a second PF for a second PSL succeeding the first PSL using the second MOO algorithm; analyzing the first and second PFs to develop Best Overall Network Solutions (“BONSs”); ranking the BONSs according to a pre-defined criteria; identifying a top ranked solution for BONSs that complies with current regulatory and project policies; computing configuration parameters for protocols of PSLs that enable implementation of the top ranked solution within the cognitive network; and dynamically re-configuring network resources of PSLs using the configuration parameters.

Abstract: Robotic system (100) includes a processing device (512) and a plurality of robot actuators (501) to cause a specified motion of the robot (102). The processing device (512) responds to one or more user robot commands (115) initiated by a control operator input at a remote control console (108). A user robot command will specify a first movement of the robot from a first position to a second position. The processing device will compare a current pose of the robot to an earlier pose of the robot to determine a difference between the current pose and the earlier pose. Based on this comparing, the processing device will selectively transform the user robot command to a latency-corrected robot command which specifies a second movement for the robot which is different from the first movement.

Abstract: A method has been described for making an electrical structure having an air dielectric and includes forming a first subunit including a sacrificial substrate, an electrically conductive layer including a first metal on the sacrificial substrate, and a sacrificial dielectric layer on the sacrificial substrate and the electrically conductive layer. The method further includes forming a second subunit including a dielectric layer and an electrically conductive layer thereon including the first metal, and coating a second metal onto the first metal of one or more of the first and second subunits. The method also includes aligning the first and second subunits together, heating and pressing the aligned first and second subunits to form an intermetallic compound of the first and second metals bonding adjacent metal portions together, and removing the sacrificial substrate and sacrificial dielectric layer to thereby form the electrical structure having the air dielectric.

Abstract: A method for detecting an oil mass covered by ice includes collecting alert data at a first probability of detection using an airborne platform moved about a search area above the ice. An alert area having a likelihood of an oil mass covered by the ice is determined based upon the alert data. Confirmation data is collected at a second probability of detection higher than the first probability of detection using a ground platform moved over the alert area. An oil mass covered by the ice is detected based upon the confirmation data.

Abstract: A device for heating hydrocarbon resources in a subterranean formation having a wellbore therein may include a radio frequency (RF) antenna positioned within the wellbore. The RF antenna may include a superconductive material. The device may include an RF source configured to supply RF power to the RF antenna to heat the hydrocarbon resources.

Abstract: The unattended surveillance device may include a housing to be positioned for unattended surveillance, a video camera associated with or carried by the housing to capture video, and an image processor carried by the housing and cooperating with the video camera. The image processor extracts moving objects in the foreground of the captured video, generates a profile image or sequence of profile images of the extracted moving objects, compresses the sequence of profile images, and generates a surveillance information packet based upon the compressed sequence of profile images. Also, a wireless transmitter or transceiver may be associated with the image processor to transmit the surveillance information packet to a surveillance monitoring station.

Abstract: A method for detecting an oil mass covered by ice includes collecting radiometric data different frequencies, corresponding to respective different depths into the ice, using at least one airborne platform moved about a search area above the ice so that the radiometric data defines radiometric volumetric data. The radiometric volumetric data is processed to thereby detect an oil mass covered by the ice.

Abstract: Systems (100) and methods (800) for routing packets within a Multi-Channel Communications Device (“MCCD”). The methods involve receiving a first packet (300) which has a first classification level and a second packet (300) which has a second different classification level. Subsequently, modified first and second packets (400) are generated by inserting routing headers (402) between data link layer protocol headers (308, 308?) and network layer protocol headers (310, 310?) of the first and second packets. Each routing header comprises an error-detecting code (512) and routing information (502) describing a route within the MCCD along which the first or second packet is to travel. The routing headers are then used by a single packet router (160) to simultaneously route the modified first and second packets through the MCCD to at least one port of a plurality of output interface ports (116, 1901, . . . , 190N) of the MCCD.

Abstract: Integrated Microelectromechanical System (“MEMS”) devices and methods for making the same. The MEMS devices comprise a substrate (200) and a MEMS filter device (100) mechanically suspended above a major surface of the substrate. A first gas gap (202) exists between the major surface of the substrate and the MEMS filter device. An isolation platform (600) is provided to absorb vibrations from an external environment prior to reaching the MEMS filter device. In this regard, the isolation platform comprises: a frame structure (610) framing a periphery of the MEMS filter device; and at least one resilient component (612-618) coupled between the frame structure and the MEMS filter device. The frame structure is mechanically connected to the substrate. Electronic circuitry is connected to the MEMS filter device via a resilient interconnection (204, 206) that is movable in at least one direction of the vibrations.

Abstract: A wireless communications device may include a receiver configured to receive a continuous phase modulation (CPM) signal and a demodulator coupled downstream from the receiver. The demodulator may be configured to generate a CPM correlation matrix based upon an expected CPM signal, and generate a temporary correlation matrix. The temporary correlation matrix may include a first copy of the CPM correlation matrix inverted in time, and a second copy of the CPM correlation matrix.

Abstract: Methods for fabrication of electronic systems and systems therefrom are provided. An electronic system includes a first substrate (202) having a first surface (202a) and a second substrate (208) having a second surface (208a) facing the first surface. The system also includes a plurality of battery cell layers (106-112) disposed on a plurality of laterally spaced areas on the first and second surfaces (203, 209). In the system, portions of the battery cell layers on the first surface are in physical contact with portions of the battery cell layers on the second surface and the battery cell layers on the first surface and the second surface form a plurality of electrically interconnected battery cells (206, 212) on the first and the second surfaces that are laterally spaced apart and that define one or more batteries (200).

Abstract: Systems (100) and methods (300) for efficient spatial feature data analysis. The methods involve simultaneously generating chip images using image data defining at least a first image and video chips using video data defining at least a first video stream. Thereafter, an array is displayed which comprises grid cells in which at least a portion of the chip images is presented, at least a portion of the video chips is presented, or a portion of the chip images and a portion of the video chips are presented. Each chip image comprises a panned-only view, a zoomed-only view, or a panned-and-zoomed view of the first image including a visual representation of at least one first object of a particular type. Each of the video chips comprises a segment of the first video stream which include a visual representation of at least one second object of the particular type.

Abstract: Compact haptic interface (100) includes a base (102) and a yoke (304) rotatably disposed within the base. A first drive coupling (312) between a first motor (301) and the yoke rotates the yoke about a yoke axis (308). A carrier (306) is mounted to the yoke and rotatable about a carrier axis (310) transverse to the yoke axis. A rod (110) mounted to the carrier extends along a rod axis (346) transverse to the yoke axis and the carrier axis. A second drive coupling (314) rotates the carrier about the carrier axis responsive to operation of a second motor (302) which is mounted to the yoke. A third motor (303) is supported on the carrier and rotatable with the carrier about the carrier axis of rotation. A third drive coupling (340) facilitates linear movement of the rod along a linear direction responsive to operation of the third motor.