Abstract: A hydrocarbon resource processing device may include a radio frequency (RF) source and an RF applicator coupled to the RF source. The RF applicator may include a base member being electrically conductive, and first and second elongate members being electrically conductive and having proximal ends coupled to the base member and extending outwardly therefrom in a generally parallel spaced apart relation. The first and second elongate members may have distal ends configured to receive the hydrocarbon resource therebetween. In another embodiment, the RF applicator may include an enclosure being electrically conductive and having a passageway therethrough to accommodate a flow of the hydrocarbon resource and a divider being electrically conductive and positioned within the enclosure.

Abstract: A method of producing heavy oil from a heavy oil formation by combining electromagnetic heating to achieve fluid communication between wells, following by in situ combustion to mobilize and upgrade the heavy oil.

Abstract: A device for heating a hydrocarbon resource in a subterranean formation having at least one pair of laterally extending upper and lower wellbores therein may include a radio frequency (RF) source. The device may also include an upper wellbore RF radiator to be positioned in the laterally extending upper wellbore and including a plurality of first terminals. The device may further include a lower wellbore RF radiator to be positioned in the laterally extending lower wellbore and comprising a plurality of second terminals. The device may also include an interconnection arrangement configured to couple the RF source and the first and second terminals so that at least one of the upper and lower wellbore RF radiators heat the hydrocarbon resource in the subterranean formation.

Abstract: A communications system may include an optical source to generate an optical carrier signal, and an RF signal path including a first electro-optic (EO) modulator to modulate the optical carrier signal based upon an RF signal, a stimulated Brillouin scattering (SBS) device coupled to the first EO modulator, and an optical circulator downstream from the SBS device. A local oscillator (LO) path may include a second EO modulator coupled to the optical source to modulate the optical carrier signal based upon an LO signal, and an optical bandpass filter(s) coupled to the second EO modulator. A filter function path may be coupled to the optical circulator and include a third EO modulator to perform optical modulation based upon a filter function signal. A detector may be coupled to the RF signal path and the LO path to generate an intermediate frequency (IF) signal.

Abstract: An apparatus for hydrocarbon resource recovery from a subterranean formation includes a radio frequency (RF) source, an RF antenna to be positioned within the subterranean formation to deliver RF power to the hydrocarbon resource within the subterranean formation, and an RF transmission line extending between the RF source and the RF antenna. The RF transmission line may include RF transmission line sections coupled together in end-to-end relation. Each section may include an inner conductor, an outer conductor surrounding the inner conductor, and an outer load-carrying tubular member surrounding the outer conductor. A respective coupling assembly joins ends of adjacent sections together. Each coupling assembly may include an electrical coupler being fixedly connected to first ends of corresponding inner and outer conductors and being slidably connected to opposing second ends of adjacent inner and outer conductors, and a mechanical coupler connecting ends of adjacent load-bearing tubular members together.

Abstract: A communications system includes a sender device configured to send data packets in accordance with a Transmission Control Protocol (TCP) to a receiver device. An intermediate device is coupled between the sender device and the receiver device and includes a wireless transceiver configured to provide a communications link between the sender device and the receiver device and wherein said communications link is susceptible to at least one of transmission delays and transmission errors. A controller is coupled to the wireless transceiver and configured to serve as a TCP proxy between the sender device and the receiver device by sending successive simulated TCP acknowledgements of delivery to the sender device starting at a delay time shorter than a TCP retransmission timeout period and increasing for each successive simulated TCP acknowledgement.

Abstract: A portable modular treatment system to be remotely deployed adjacent a solvent extraction bitumen well may include a portable initial separation module configured to receive a liquid emulsion from the solvent extraction bitumen well including bitumen, produced water, solvent, and at least one non-condensable gas, and liberate the at least one non-condensable gas while the solvent remains with the liquid emulsion. The system may further include a portable free water removal module configured to receive the liquid emulsion from the portable initial separation module and separate the bitumen and solvent from the produced water, a portable skimming tank module configured to receive the produced water from the portable free water removal module and remove free oil from the produced water through gravity separation, and a portable condenser module configured to receive the bitumen and solvent from the portable free water removal module and separate the bitumen and solvent.

Abstract: Payload deployment system (400) comprises a payload deployment device (402) and a payload deployment structure (406) comprising a frame (102) having a first end, a second end, and a body extending from the first end toward the second end. The frame includes an aperture (106) located along a length of the body, wherein the aperture extends from a first surface of the frame to a second surface of the frame. A heating element (116) is located along a portion of an edge of the aperture, wherein the heating element is configured to be selectively electrically energized. The frame further includes a mounting portion (104) wherein the payload deployment structure is connected to the payload deployment device via the mounting portion.

Abstract: Method and system for Single Event Latchup (SEL) current surge mitigation involves monitoring data signals for a protected device and deriving from them a detected signature comprised of one or more detected signature vector components. The detected signature vector components are compared to previously stored signature vector components. Based on the comparing, the system selectively differentiates between the occurrence of standard power surges associated with normal operation of the protected device, and a non-standard current surge which requires cycling power of the protected device for continued proper functioning of the protected device.

Abstract: A method may include generating a laser light beam with a laser source, splitting the laser light beam into a first front side beam and a back side beam for a back side of an ion trap using a first beamsplitter, directing the front side beam to a second beamsplitter using an input telescope, and splitting the first front side beam into a plurality of second front side beams directed to a common acousto-optic medium using a second beamsplitter. The common acousto-optic medium may have a respective plurality of electrodes coupled to the common acousto-optic medium for each of the second front side beams. The method may further include directing the plurality of second front side beams to a front side of the ion trap using an output telescope, and generating a respective RF drive signal for each of the plurality of electrodes using a plurality of RF drivers.

Abstract: Wireless transceiver includes a plurality of RF filters. A first band switching network includes a first plurality of RF switches to selectively direct transmitter RF energy to a selected RF filter. A second band switching network includes a second plurality of RF switches which selectively controls which of RF filter is connected to an antenna port. A receiver RF switch is connected to at least one of the RF filters and to a receiver input to selectively permit the received RF energy arriving at one RF filter to be communicated to the receiver. Each RF switch is a PIN diode type with at least one series diode provided along a signal path. No more than two PIN diodes are present in the signal path between the common transmitter port and the common antenna port when any of the RF filters is in use.

Abstract: A laser system may include a laser source configured to generate a laser light beam and an acousto-optic modulator (AOM). The AOM may include an acousto-optic medium configured to receive the laser light beam, and a phased array transducer comprising a plurality of electrodes coupled to the acousto-optic medium and configured to cause the acousto-optic medium to output a zero order laser light beam and a first order diffracted laser light beam. The system may further include a beamsplitter downstream from the AOM and configured to split a sampled laser light beam from the zero order laser light beam, a photodetector configured to receive the sampled laser light beam and generate a feedback signal associated therewith, and a radio frequency (RF) driver configured to generate an RF drive signal to the phased array transducer electrodes so that noise is diverted to the first order diffracted laser light beam based upon the feedback signal.

Abstract: An antenna assembly may be positioned within a wellbore in a subterranean formation. The antenna assembly includes a tubular antenna element to be positioned within the wellbore, and an RF coaxial transmission line to be positioned within the tubular antenna element. The RF coaxial transmission line includes a series of coaxial sections coupled together in end-to-end relation, each coaxial section including an inner conductor, an outer conductor surrounding the inner conductor, and a dielectric therebetween. Each of the outer conductors has opposing threaded ends defining overlapping mechanical threaded joints with adjacent outer conductors.

Abstract: A wireless communications device may include a wireless receiver, and an adaptive demodulator coupled to the wireless receiver. The adaptive demodulator is configured to apply first and second bandpass filters to amplitude information of a received signal at first and second frequency bands, respectively, and classify the received signal as one of a PSK modulation type, a second PSK modulation type, and a third FSK modulation type based upon whether a tone exists in the amplitude information of the received signal in one or more of the first and second frequency bands. The adaptive demodulator is configured to adjust a demodulating parameter based upon a classified modulation type of the received signal.

Abstract: A cover is fitted to an aperture in an enclosure. A biasing mechanism is connected to the cover to mechanically bias the cover in an open position. An adhesive member is disposed around the aperture to retain the cover in a closed position against the bias of the biasing mechanism. A release mechanism effects release of the cover from the adhesive member by diminishing adhesion thereof in response to an open command signal.

Abstract: Systems (100) and methods (600) for operating an exoskeleton disposed at least partially on a joint of a wearer's limb (118). The methods involve respectively aligning first apertures (310 or 312) of a first planar flexible element (304 or 306) of the exoskeleton with second apertures (310 or 312) of a second planar flexible element (304 or 306) of the exoskeleton. The first and second planar flexible elements abut each other. A toothed flexible element (302) is then caused to ratchetedly engage the first and second planar flexible elements by bending the joint.

Abstract: A system for automatically controlling a gimbaled camera system of a vehicle. The system includes a camera positioned relative to a body of the vehicle and one or more sensors configured to sense the pointing direction of the camera. One or more sensors are configured to monitor movement of the vehicle relative to a surface. A processor is configured to receive the sensed camera pointing direction data and vehicle movement data. The processor establishes and stores a target position representative of the position of a target object relative to the vehicle body based on an object independent association and automatically adjusts the camera pointing direction in response to the vehicle movement data such that the camera remains aimed on the target position. A method for automatically controlling the gimbaled camera system is also provided.

Abstract: A method is for making an electronic device including forming a multilayer circuit board having a non-planar three-dimensional shape defining a membrane switch recess therein, the multilayer circuit board including at least one liquid crystal polymer (LCP) layer, and at least one electrically conductive pattern layer thereon defining at least one membrane switch electrode adjacent the membrane switch recess to define a membrane switch. The method also includes filling the membrane switch recess with a compressible dielectric material, and positioning at least one biasing member in the membrane switch recess.

Abstract: A laser system may include a laser source configured to generate a first laser light beam, a beamsplitter configured to split the first laser light beam into a plurality of second laser light beams, and a multi-channel acousto-optic modulator (AOM). The multi-channel AOM may include a common acousto-optic medium configured to receive the plurality of second laser light beams, and a respective phased array transducer comprising a plurality of electrodes coupled to the acousto-optic medium for each of the second laser light beams. The laser system may further include a plurality of radio frequency (RF) drivers configured to generate respective RF drive signals for the phased array transducer electrodes.

Abstract: A calibration system for a climate system utilizing closed loop feedback and a phase change cell includes controlling a transfer rate of energy between a phase change cell and a thermal mass based on at least a temperature of the thermal mass. The transfer rate is controlled in order to control the temperature of the thermal mass and selectively move a material in the phase change cell through a phase change with transferred energy. In particular, the temperature of the thermal mass is controllable when the material is maintained in the phase change. A thermal sensor in the thermal mass may also be calibrated based on the temperature of a thermal sensor in the phase change cell during a predetermined portion of the phase change.