Abstract: An apparatus includes a phase delay module that is configured to receive a set of signals from an antenna assembly having a horizontal polarization element and an elliptical polarization element. The horizontal polarization element and the elliptical polarization element are collectively configured to receive the set of signals over a coverage area. The phase delay module is configured to determine (1) a signal strength of a first signal from the set of signals received via the horizontal polarization element and (2) a signal strength of a second signal from the set of signals received via the elliptical polarization element. The phase delay module is configured to send a combined signal including (1) the first signal and (2) the second signal having a phase delay if the signal strength of the first signal is higher than the signal strength of the second signal.

Abstract: A portable solar energy generation system that has a disassembled configuration and an assembled configuration. The system includes a solar energy generation assembly, and portable container. The system may further include an internal frame, a power inverter, charge controller, batteries, attachment components, wires, user input devices, fluid tank, turbine, pump, generator, and other system components. When in the disassembled configuration, all system components including the solar energy generation assembly are packaged within the portable container. When in the disassembled configuration, the solar energy generation assembly is coupled to an external surface of the container and is either generating electricity within the container or redirecting sunlight for electricity generation at a predetermined target.

Abstract: A method of producing a MEMS device provides a MEMS apparatus having released structure. The MEMS apparatus is formed at least in part from an SOI wafer having a first layer, a second layer spaced from the first layer, and an insulator layer between the first layer and second layer. The first layer has a top surface, while the second layer has a bottom surface facing the top surface. After providing the MEMS apparatus, the method increases the roughness of at least the top surface of the first layer or the bottom surface of the second layer.

Abstract: A virtual shuffleboard table gaming apparatus including a housing having a playing field, a game acquisition circuit, and a display. As a puck is propelled towards a puck return at the distal end of the playing field, the puck temporarily obstructs at least two beams from transmitters. Sensors that receive the transmitted beams provide information to the game acquisition circuit indicative of the time when the beams were blocked and unblocked. The duration of time the beams are block are used by a game controller to calculate the angle of travel, location, and velocity of the puck. This information is then used by the game controller to determine the travel path and resting place of a virtual puck on a virtual playing field, as well as determine whether the virtual puck rests in a scoring zone and maintain a game score.

Abstract: A microchip has a bonding material that bonds a first substrate to a second substrate. The bonding material has, among other things, a rare earth metal and other material.

Abstract: A lubricant additive gel formed by the gellation of two or more lubricant additives for the slow release of the additive components into a fluid. The lubricant additive gel slowly releases into its component lubricant additives when contacted with the fluid such as an oil thereby serving as a lubricant fluid such as an oil thereby.

Abstract: A microchip has a bonding material that bonds a first substrate to a second substrate. The bonding material has, among other things, a rare earth metal and other material.

Abstract: A method of forming an inertial sensor provides 1) a device wafer with a two-dimensional array of inertial sensors and 2) a second wafer, and deposits an alloy of aluminum/germanium onto one or both of the wafers. The alloy is deposited and patterned to form a plurality of closed loops. The method then aligns the device wafer and the second wafer, and then positions the alloy between the wafers. Next, the method melts the alloy, and then solidifies the alloy to form a plurality of conductive hermetic seal rings about the plurality of the inertial sensors. The seal rings bond the device wafer to the second wafer. Finally, the method dices the wafers to form a plurality of individual, hermetically sealed inertial sensors.

Abstract: A method of producing a MEMS device provides a first substrate having a first interior surface and thickness, and a second substrate having a second interior surface. The method also forms at least one closed wall on at least one of the first and second substrates, weakens the first substrate in a plane generally parallel to the first interior surface, and secures the first substrate to the second substrate. The at least one closed wall extends between the first interior surface and the second interior surface. The method further separates a portion of the first substrate along the plane generally parallel to the first interior surface after securing the first and second substrates, and removes an excess portion of the first substrate to produce a reduced thickness first substrate of no greater than about 20 microns.

Abstract: A method of forming a microphone having a variable capacitance first deposits high temperature deposition material on a die. The high temperature material ultimately forms structure that contributes to the variable capacitance. The method then forms circuitry on the die after depositing the deposition material. The circuitry is configured to detect the variable capacitance.

Abstract: A lubricant additive gel formed by the gellation of two or more lubricant additives for the slow release of the additive components into a fluid. The lubricant additive gel slowly releases into its component lubricant additives when contacted with the fluid such as an oil thereby serving as a lubricant fluid such as an oil thereby.

Abstract: A micromachined microphone is formed from a silicon or silicon-on-insulator (SOI) wafer. A fixed sensing electrode for the microphone is formed from a top silicon layer of the wafer. Various polysilicon microphone structures are formed above a front side of the top silicon layer by depositing at least one oxide layer, forming the structures, and then removing a portion of the oxide underlying the structures from a back side of the top silicon layer through trenches formed through the top silicon layer. The trenches allow sound waves to reach the diaphragm from the back side of the top silicon layer. In an SOI wafer, a cavity is formed through a bottom silicon layer and an intermediate oxide layer to expose the trenches for both removing the oxide and allowing the sound waves to reach the diaphragm. An inertial sensor may be formed on the same wafer, with various inertial sensor structures formed at substantially the same time and using substantially the same processes as corresponding microphone structures.

Abstract: A MEMS microphone has a backplate and a movable diaphragm that together form a variable capacitance. The backplate has a backplate surface and, in a corresponding manner, the diaphragm has a diaphragm surface that faces the backplate surface. At least one of the backplate surface and the diaphragm surface has at least a portion with a Hurst exponent that is less than or equal to about 0.5.

Abstract: A virtual shuffleboard table gaming apparatus including a housing having a playing field, a game acquisition circuit, and a display. As a puck is propelled towards a puck return at the distal end of the playing field, the puck temporarily obstructs at least two beams from transmitters. Sensors that receive the transmitted beams provide information to the game acquisition circuit indicative of the time when the beams were blocked and unblocked. The duration of time the beams are block are used by a game controller to calculate the angle of travel, location, and velocity of the puck. This information is then used by the game controller to determine the travel path and resting place of a virtual puck on a virtual playing field, as well as determine whether the virtual puck rests in a scoring zone and maintain a game score.

Abstract: A MEMS sensor includes a substrate having a MEMS structure movably attached to the substrate, a cap attached to the substrate and encapsulating the MEMS structure, and an electrode formed on the cap that senses movement of the MEMS structure.

Abstract: A lubricant additive gel formed by the gellation of two or more lubricant additives for the slow release of the additive components into a fluid. The lubricant additive gel slowly releases into its component lubricant additives when contacted with the fluid such as an oil thereby serving as a lubricant fluid such as an oil thereby.

Abstract: A microchip has a bonding material that bonds a first substrate to a second substrate. The bonding material has, among other things, a rare earth metal and other material.

Abstract: A microchip has a bonding material that bonds a first substrate to a second substrate. The bonding material has, among other things, a rare earth metal and other material.

Abstract: A method for play of a parlor entertainment unit including a remote activation assembly and an activation-sensing unit. The activation-sensing unit, which may be battery operated and housed in the entertainment unit, may be in an energy-conserving sleep mode until the activation-sensing unit receives a wake-up signal. In one embodiment, the wake-up signal may be generated by the engagement of an activation mechanism, such as a coin slide. After being awoken, the activation-sensing unit may transmit an inquiry to the remote activation assembly as to whether the associated entertainment unit has been selected for play and/or whether there is a sufficient number of credits available for play. If that entertainment unit has not been selected for play, the activation-sensing unit may return to a sleep mode. However, if sufficient play credits are available for the entertainment unit, play may commence.

Abstract: A method of forming an inertial sensor provides 1) a device wafer with a two-dimensional array of inertial sensors and 2) a second wafer, and deposits an alloy of aluminum/germanium onto one or both of the wafers. The alloy is deposited and patterned to form a plurality of closed loops. The method then aligns the device wafer and the second wafer, and then positions the alloy between the wafers. Next, the method melts the alloy, and then solidifies the alloy to form a plurality of conductive hermetic seal rings about the plurality of the inertial sensors. The seal rings bond the device wafer to the second wafer. Finally, the method dices the wafers to form a plurality of individual, hermetically sealed inertial sensors.