Abstract: In some embodiments, a wireless power charging circuit includes a wireless power receiver configured to receive wireless power from a receive coil and to produce a first voltage; an open loop capacitor divider coupled to receive the first voltage from the wireless power receiver and configured to provide a second voltage, the second voltage being reduced from the first voltage; and a linear battery charger coupled to receive the second voltage from the open loop capacitor and configured to provide a charging voltage to provide to a battery coupled to the system.

Abstract: Embodiments of the invention relate to a method for producing a color sensor with a sensor characteristic adjusted by three sensor elements that each comprise an element characteristic, and a color filter cooperating with the sensor elements and consisting of color filter elements that each comprise a filter element characteristic, and to a color sensor. Embodiments include a method with which a color sensor with a precisely adjustable sensor characteristic can be produced from several photosensitive elements and from simple filter elements is solved in that the particular filter element characteristics are adjusted in such a manner that they have in cooperation with the respective element characteristic an interim characteristic of the sensor which deviates from the sensor characteristic on the whole, wherein the sensor characteristic is generated from the interim characteristic by a transformation algorithm using transformation parameters.

Abstract: An apparatus comprises an amplifier circuit and a bias circuit. The bias circuit is generally configured to dynamically adjust a bias voltage reference at a bias node connected to one or more input transistors of the amplifier circuit to maintain a low baseband impedance.

Abstract: A method of measuring a Q-factor in a wireless power transmitter includes charging a capacitor in a LC tank circuit that includes a transmission coil to a voltage; starting a Q-factor determining by coupling the LC tank circuit to ground to form a free-oscillating circuit; monitoring the voltage across the capacitor as a function of time as the LC tank circuit oscillates; and determining the resonant frequency and the Q-factor from monitoring the voltage.

Abstract: In accordance with some embodiments of the present invention, a method of determining a Q-factor in a transmit circuit with a resonant circuit includes setting a system voltage; performing a coarse scan to determine a course resonant frequency; performing a fine scan based on the course scan to determine a resonant frequency; performing a final measurement at the resonant frequency to determine an average system voltage and an average peak voltage of the resonant circuit; calculating a Q parameter from the average system voltage and the average peak voltage; and calculating the Q-factor from the Q parameter.

Abstract: An apparatus includes a first circuit and a plurality of second circuits. The first circuit may be configured to generate a pair of quadrature signals from a radio-frequency signal. The second circuits may each comprise a plurality of cascode amplifiers. The cascode amplifiers may be connected in parallel. The cascode amplifiers may be configured to generate a plurality of intermediate signals by modulating the quadrature signals in response to a first control signal and a second control signal. The first control signal generally switches a contribution of the cascode amplifiers in the generation of the intermediate signal. The second control signal may adjusts a total current passing through all of the cascode amplifiers.

Abstract: Hybrid-coding, multi-cell architecture and operating techniques for step devices provide advantages over binary-coded and thermometer-coded step devices by minimizing or avoiding glitches common in the transient response of binary-coded step devices and by minimizing or avoiding significant increases or degradation in one or more of area, package dimensions, pin counts, power consumption, insertion loss and parasitic capacitance common to thermometer-coded step devices having equivalent range and resolution.

Abstract: In accordance with embodiments of the present invention, a coil design for the transmission of wireless power. In some embodiments, the coil can include a winding with one or more turns of conductive traces mounted on a substrate, wherein the one or more turns include characteristics that enhance operation of the coil. In some embodiments, the winding includes a transmit coil and a receive coil, each coupled to terminals that provide for a transmit functionality and a receive functionality. In some embodiments, the traces are varied in width and/or thickness in order to optimize the inductance and the coil resistance. In some embodiments, parameters of a control circuit coupled to the coil to affect a transmit functionality or a receive functionality can be optimized.

Abstract: An apparatus including a host interface and a registered clock driver interface. The host interface may be configured to receive an enable command from a host. The registered clock driver interface may be configured to perform power management for a dual in-line memory module, generate data for the dual in-line memory module, communicate the data, receive a clock signal and communicate an interrupt signal. The registered clock driver interface may be disabled at power on. The registered clock driver interface may be enabled by in response to the enable command. The apparatus may be implemented as a component on the dual in-line memory module.

Abstract: An apparatus including a host interface and a power management interface. The host interface may be configured to receive control words from a host. The power management interface may be configured to (i) enable the host to read/write data from/to a power management circuit of a dual in-line memory module, (ii) communicate the data, (iii) generate a clock signal and (iv) communicate an interrupt signal. The power management interface is disabled at power on. The apparatus is configured to (i) decode the control words, (ii) enable the power management interface when the control words provide an enable command and (iii) perform a response to the interrupt signal. The clock signal may operate independently from a host clock.

Abstract: An apparatus includes a log amplifier and a calibration circuit. The log amplifier may be configured to generate an output signal in response to an offset between a first voltage and a second voltage. The calibration circuit may be configured to disconnect an input power and perform a cancellation of the offset when the input power is not present. The first voltage may be generated by the apparatus in response to a power detection. The second voltage may be received from a reference circuit. The cancellation of the offset may extend a working range of the apparatus. The output may provide a linear-in-dB power detection.

Abstract: In accordance with aspects of the present invention, a first wireless power enabled device includes a transceiver and control logic. The transceiver includes a plurality of switches coupled in a full-bridge configuration with a resonant tank circuit. The control logic is configured to detect a presence of a second wireless power enabled device, establish a trusted relationship with the second wireless power enabled device, determine an operating mode of the first wireless power enabled device selected from a transmit mode or a receive mode, and drive the plurality of switches to operate the resonant tank circuit in the determined operating mode. The first wireless power enabled device may further include a memory that stores a copy of a first key associated with the first wireless power enabled device and a copy of a second key associated with the second wireless power enabled device.

Abstract: An apparatus includes a package and a beam former circuit. The package may be configured to be mounted on an antenna array at a center of four antenna elements. The beam former circuit may (i) be disposed in the package, (ii) have a plurality of ports, (iii) be configured to generate a plurality of radio-frequency signals in the ports while in a transmit mode and (iv) be configured to receive the radio-frequency signals at the ports while in a receive mode. A plurality of ground bumps may be disposed between the beam former circuit and the package. The ground bumps may be positioned to bracket each port. Each ground bump may be electrically connected to a signal ground to create a radio-frequency shielding between neighboring ports.

Abstract: An apparatus comprises a plurality of transceiver circuits, a memory, and an interface circuit. The memory generally embodies a table associating a plurality of index values with corresponding gain and phase values for each channel of each of the transceiver circuits. In a first mode, the interface circuit may be configured to receive the corresponding gain and phase values associated with each of the plurality of index values and store the corresponding gain and phase values in the table. In a second mode, the interface circuit, in response to receiving one of the index values, configures each channel of each of the transceiver circuits with the corresponding gain and phase values from the table.

Abstract: A wireless status indicator for a wireless power transfer system includes an object configured to wirelessly generate power responsive to a magnetic flux field of a wireless power transmitter and to generate a status indication of the wireless power transfer system. A wireless power transfer system comprises a wireless power status indicator configured to wirelessly generate power responsive to a wireless power signal and to generate a status indication of the wireless power transfer system. A related method includes generating power by a wireless status indicator and generating a status indication responsive to a wireless power signal. The wireless status indicator is a separate stand-alone device than a wireless power transmitter and wireless power receiver involved in the wireless power transfer. The status indication corresponds to a state of wireless power transfer.

Abstract: An apparatus comprises a first RF port, a second RF port, a first resonator circuit and at least one second resonator circuit. The first resonator circuit and the second resonator circuit may be connected between the first RF port and the second RF port. The first resonator circuit may comprise a first inductor, a first capacitor, and a first stacked switch device. The second resonator circuit may comprise a second inductor, a second capacitor, and a second stacked switch device. The first capacitor and the first stacked switch device may be coupled in series across the first inductor. The second capacitor, the second inductor, and the second stacked switch device may be connected in parallel.

Abstract: A system and method of wireless power transfer using a power converter with a bypass mode includes a power converter. The power converter includes a pulsed switch, a capacitor configured to supply a drive voltage to the pulsed switch, a first circuit configured to charge the capacitor when the power converter operates in a switched mode of operation, and, a second circuit configured to charge the capacitor when the power converter operates in a bypass mode of operation.

Abstract: A system and method of wireless power transfer using a power converter with a bypass mode includes a power converter. The power converter includes a pulsed switch, a capacitor configured to supply a drive voltage to the pulsed switch, a first circuit configured to charge the capacitor when the power converter operates in a switched mode of operation, and, a second circuit configured to charge the capacitor when the power converter operates in a bypass mode of operation.

Abstract: An apparatus includes a first circuit and a second circuit. The first circuit may be configured to generate (i) a variable current and (ii) a constant current. The variable current may be proportional to a temperature of the first circuit. The second circuit may be configured to present a resistance through a plurality of first transistors between two ports in response to both the variable current and the constant current. The resistance may have a predefined dependence on the temperature.

Abstract: An apparatus comprises a phased array antenna panel, a plurality of amplifier circuits, and a plurality of beamformer circuits. The phased array antenna panel generally comprises a plurality of antenna elements. Each of the amplifier circuits is mounted on the phased array antenna panel adjacent to a respective one of the plurality of antenna elements and each of the amplifier circuits has one or more first ports directly coupled to the respective antenna element. Each of the beamformer circuits is mounted on the phased array antenna panel adjacent to a number of the amplifier circuits. Each of the beamformer circuits has one or more second ports directly coupled to each of the adjacent amplifier circuits. Each of the beamformer circuits is generally configured to exchange a plurality of radio-frequency signals with each of the adjacent amplifier circuits via the second ports.