Abstract: Scanning apparatus includes a rotor, including a permanent magnet, which is configured to rotate about an axis. A stator includes a magnetic core, which is configured to generate a static magnetic field in a vicinity of the rotor and defines an equilibrium angle of rotation of the rotor, at which the permanent magnet is aligned with the static component of the magnetic field. At least one coil is wound on the magnetic core so that when the coil driven with an AC electrical current at a selected frequency, the stator generate a time-alternating magnetic field, which causes the rotor to oscillate on the axis at the selected frequency about the equilibrium angle.

Abstract: In various embodiments, a voltage collection bootstrap circuit includes a capacitor, an inductor, an oscillator, a bias circuit, and a switch. A current may be induced in the inductor, the oscillator, or both. The inductor, the oscillator, or both may store energy in the capacitor. The inductor, capacitor, and oscillator may supply energy to the bias circuit. The bias circuit may output a difference between a reference voltage and a voltage corresponding to the energy received from at least one of the inductor, capacitor, and oscillator. Based on the output of the bias circuit, a switch may connect the voltage collection circuit to an output of at least one of the inductor, capacitor, and oscillator. Accordingly, energy may be provided to the voltage collection circuit using one or more induced currents.

Abstract: The present invention generally relates to a MEMS device having a plurality of cantilevers that are coupled together in an anchor region and/or by legs that are coupled in a center area of the cantilever. The legs ensure that each cantilever can move/release from above the RF electrode at the same voltage. The anchor region coupling matches the mechanical stiffness in all sections of the cantilever so that all of the cantilevers move together.

Abstract: Methods and systems may provide for detecting a location of an adjacent ultrasonic receiver of a battery powered device relative to a charging surface of a contactless charger. The charging surface may include an ultrasonic array of transmitter sub arrays, wherein one or more of the transmitter sub arrays may be selectively activated based on the location to focus an ultrasonic beam on the adjacent ultrasonic receiver. In one example, a movement of the adjacent ultrasonic receiver may be detected and the focus of the ultrasonic beam is adjusted in response to the movement.

Abstract: A MEMS device, such as an accelerometer or gyroscope, fabricated in interconnect metallization compatible with a CMOS microelectronic device. In embodiments, a proof mass has a first body region utilizing a thick metal layer that is separated from a thin metal layer. The thick metal layer has a film thickness that is significantly greater than that of the thin metal layer for increased mass. The proof mass further includes a first sensing structure comprising the thin metal layer, but lacking the thick metal layer for small feature sizes and increased capacitive coupling to a surrounding frame that includes a second sensing structure comprising the thin metal layer, but also lacking the thick metal layer. In further embodiments, the frame is released and includes regions with the thick metal layer to better match film stress-induced static deflection of the proof mass.

Abstract: Methods and systems may provide for a hybrid RF MEMS component design including an electrostatic actuation and a piezoelectric actuation. In one example, the method may include applying a first voltage to generate a first piezoelectric force to reduce a first gap between a cantilever and an actuation electrode, and applying a second voltage to generate an electrostatic force to create contact between the cantilever and a transmission electrode.

Abstract: A MEMS device, such as an accelerometer or gyroscope, fabricated in interconnect metallization compatible with a CMOS microelectronic device. In embodiments, a proof mass has a first body region utilizing a thick metal layer that is separated from a thin metal layer. The thick metal layer has a film thickness that is significantly greater than that of the thin metal layer for increased mass. The proof mass further includes a first sensing structure comprising the thin metal layer, but lacking the thick metal layer for small feature sizes and increased capacitive coupling to a surrounding frame that includes a second sensing structure comprising the thin metal layer, but also lacking the thick metal layer. In further embodiments, the frame is released and includes regions with the thick metal layer to better match film stress-induced static deflection of the proof mass.

Abstract: A Micro-Electro-Mechanical System (MEMS) accelerometer employing a rotor and stator that are both released from a substrate. In embodiments, the rotor and stator are each of continuous a metal thin film. A stress gradient in the film is manifested in capacitive members of the rotor and stator as a substantially equal deflection such that a relative displacement between the rotor and stator associated with an acceleration in the z-axis is substantially independent of the stress gradient. In embodiments, the stator comprises comb fingers cantilevered from a first anchor point while the rotor comprises comb fingers coupled to a proof mass by torsion springs affixed to the substrate at second anchor points proximate to the first anchor point.

Abstract: A MEMS device, such as an accelerometer or gyroscope, fabricated in interconnect metallization compatible with a CMOS microelectronic device. In embodiments, a proof mass has a first body region utilizing a thick metal layer that is separated from a thin metal layer. The thick metal layer has a film thickness that is significantly greater than that of the thin metal layer for increased mass. The proof mass further includes a first sensing structure comprising the thin metal layer, but lacking the thick metal layer for small feature sizes and increased capacitive coupling to a surrounding fame that includes a second sensing structure comprising the thin metal layer, but also lacking the thick metal layer. In further embodiments, the frame is released and includes regions with the thick metal layer to better match film stress-induced static deflection of the proof mass.

Abstract: A MEMS device, such as an accelerometer or gyroscope, fabricated in interconnect metallization compatible with a CMOS microelectronic device. In embodiments, a proof mass has a first body region utilizing a thick metal layer that is separated from a thin metal layer. The thick metal layer has a film thickness that is significantly greater than that of the thin metal layer for increased mass. The proof mass further includes a first sensing structure comprising the thin metal layer, but lacking the thick metal layer for small feature sizes and increased capacitive coupling to a surrounding fame that includes a second sensing structure comprising the thin metal layer, but also lacking the thick metal layer. In further embodiments, the frame is released and includes regions with the thick metal layer to better match film stress-induced static deflection of the proof mass.

Abstract: An electronic device may include a display, and a laser reception device to receive a laser beam and to provide power based on the received laser beam.

Abstract: Methods and systems may provide for detecting a location of an adjacent ultrasonic receiver of a battery powered device relative to a charging surface of a contactless charger. The charging surface may include an ultrasonic array of transmitter sub arrays, wherein one or more of the transmitter sub arrays may be selectively activated based on the location to focus an ultrasonic beam on the adjacent ultrasonic receiver. In one example, a movement of the adjacent ultrasonic receiver may be detected and the focus of the ultrasonic beam is adjusted in response to the movement.

Abstract: Methods and systems may provide for a system having a flexible substrate, an ultrasonic transducer array coupled to the flexible substrate and a processor coupled to the ultrasonic transducer array. The processor may identify a fingerprint based on a signal from the ultrasonic transducer array. The system may also include an external component having a curved profile, wherein the ultrasonic transducer array is embedded in the external component and includes a read surface that conforms to the curved profile. In one example, the external component includes a button having a function that is separate from identification of the fingerprint.

Abstract: A Micro-Electro-Mechanical System (MEMS) accelerometer employing a rotor and stator that are both released from a substrate. In embodiments, the rotor and stator are each of continuous a metal thin film. A stress gradient in the film is manifested in capacitive members of the rotor and stator as a substantially equal deflection such that a relative displacement between the rotor and stator associated with an acceleration in the z-axis is substantially independent of the stress gradient. In embodiments, the stator comprises comb fingers cantilevered from a first anchor point while the rotor comprises comb fingers coupled to a proof mass by torsion springs affixed to the substrate at second anchor points proximate to the first anchor point.

Abstract: The present invention generally relates to a MEMS device having a plurality of cantilevers that are coupled together in an anchor region and/or by legs that are coupled in a center area of the cantilever. The legs ensure that each cantilever can move/release from above the RF electrode at the same voltage. The anchor region coupling matches the mechanical stiffness in all sections of the cantilever so that all of the cantilevers move together.

Abstract: Methods and systems may provide for a hybrid RF MEMS component design including an electrostatic actuation and a piezoelectric actuation. In one example, the method may include applying a first voltage to generate a first piezoelectric force to reduce a first gap between a cantilever and an actuation electrode, and applying a second voltage to generate an electrostatic force to create contact between the cantilever and a transmission electrode.

Abstract: Piezoelectric switches and methods of forming piezoelectric switches. The piezoelectric switch includes first and second cantilever beam actuators. The second cantilever beam actuator has a projection that overlaps the first cantilever beam actuator in a contact region. The projection is mechanically separated from the first cantilever beam actuator by a nanogap such that the first and second cantilever beam actuators are electrically isolated from each other. Each of the first and second cantilever beam actuators includes a piezoelectric actuation layer.

Abstract: Piezoelectric switches and methods of forming piezoelectric switches. The piezoelectric switch includes first and second cantilever beam actuators. The second cantilever beam actuator has a projection that overlaps the first cantilever beam actuator in a contact region. The projection is mechanically separated from the first cantilever beam actuator by a nanogap such that the first and second cantilever beam actuators are electrically isolated from each other. Each of the first and second cantilever beam actuators includes a piezoelectric actuation layer.

Abstract: A thermoelastically actuated microresonator device comprising: a main body (14) having a cantilevered beam (12); a heating element (20) located adjacent a surface of the cantilevered beam and adjacent the main body, that may be periodically actuated to generate a periodic heat gradient across a height of the beam, thereby facilitating periodic deflection of the beam.