Abstract: Exemplary embodiments are directed to a power controller. A method may include comparing a summation voltage comprising a sum of an amplified error voltage and a reference voltage with an estimated voltage to generate a comparator output signal. The method may also include generating a gate drive signal from the comparator output signal and filtering a signal coupled to a power stage to generate the estimated voltage.

Abstract: A circuit converts an input voltage to an output voltage. The circuit includes a first stage voltage converter that receives the input voltage and converts the input voltage. The first stage voltage converter includes a first buck converter having a double rail output: a first rail at a high intermediate voltage and a second rail at a low intermediate voltage. The circuit also includes a second stage voltage converter that receives the output rails and produces the output voltage.

Abstract: Exemplary embodiments are directed to wirelessly charging a chargeable device. A device may include a receiver configured to receive a stored power status from an embeddable, chargeable device. The device may further include a transmitter configured to wirelessly transmit power to charge the embeddable, chargeable device based on the stored power status.

Abstract: Micromodules and methods of making them are disclosed. An exemplary micromodule includes a substrate having a thin film inductor, and a bumped die mounted on the substrate and over the thin film inductor.

Abstract: Exemplary embodiments are directed to detection and validation of wirelessly chargeable devices positioned within a charging region of a wireless power transmitter. A device may include a wireless power transmitter configured detect a change in at least one parameter at the transmitter. The transmitter may further be configured to determine whether at least one valid chargeable device is positioned within a charging region of the transmitter upon detecting the change in the at least one parameter.

Abstract: Exemplary embodiments are directed to variable power wireless power transmission. A method may include conveying wireless power to a device at a first power level during a time period. The method may further include conveying wireless power to one or more other devices at a second, different power level during another time period.

Abstract: Micromodules and methods of making them are disclosed. An exemplary micromodule includes a substrate having a thin film inductor, and a bumped die mounted on the substrate and over the thin film inductor.

Abstract: A voltage regulator may be configured to detect variation in load current and control transient response when the load current has a high slew rate or varies at high repetition rates. A linear control circuit may be employed to control charging of an output capacitor and a load of the regulator. Upon detection of high load current step-up change at high slew rates, a non-linear control circuit may be activated. The fast load current step change may be detected by comparing an output voltage of the regulator to a feedback input of an error amplifier of the linear control circuit. The output of the error amplifier may be clamped to prevent output voltage ring-back when using the non-linear control circuit or to control load release dip. Output voltage overshoot may be controlled by turning OFF a top switch that charges the output capacitor before the inductor current becomes zero.

Abstract: Micromodules and methods of making them are disclosed. An exemplary micromodule includes a substrate having a thin film inductor, and a bumped die mounted on the substrate and over the thin film inductor.

Abstract: A voltage regulator with current-mode, dual-edge pulse width modulation (PWM) and non-linear control. The voltage regulator may include a top switch (e.g., MOSFET) configured to couple a power supply supplying an input voltage to a load. A linear control circuit of the regulator may use a first ramp signal to control turning ON of the top switch and a second ramp signal to control turning OFF of the top switch. A non-linear control circuit may turn ON the top switch upon detection of a load current step-up change to maintain an output voltage of the regulator within its regulation band. The non-linear control circuit may turn OFF the top switch upon a load current step-down change to prevent output voltage overshoot.

Abstract: Micromodules and methods of making them are disclosed. An exemplary micromodule includes a substrate having a thin film inductor, and a bumped die mounted on the substrate and over the thin film inductor.

Abstract: A circuit that synchronizes an output clock signal to a second clock signal includes a frequency locked loop circuit that receives the output clock signal and the second clock signal, modifies a frequency of the output clock signal in response to a difference in frequency between the output signal clock signal and the second clock signal to provide an output clock signal having a frequency within a predetermined error band of the frequency of the second clock signal and wherein the frequency locked loop continues to provide the output clock signal in the absence of the second clock signal.

Abstract: A circuit for minimizing the current spikes in through the stator coils in a brushless dc motor is disclosed. The circuit includes a voltage amplifier for receiving an input signal voltage and a feedback voltage, a compensation circuit for compensating the output of the voltage amplifier, a second voltage amplifier for amplifying the compensated output, a switch for selectively connecting compensated output to the stator coils, and a conductive path for discharging the compensation circuit when the switch is not conducting. The conductive path can be a transistor or a transistor in series with a voltage reference device. The invention reduces the commutation noise and the dynamic power requirement in a brushless direct current motor.

Abstract: The intelligent power supply regulator is used to adjust a supply voltage until an adjusted supply voltage to a served device is at or near the optimal supply voltage of the served device and thereafter maintain the adjusted supply voltage at or near the optimal supply voltage. Depending on the application, the intelligent power supply regulator can comprise: (1) a sensing circuit, a discriminator circuit and a voltage regulating circuit for regulating the supply voltage; or (2) a sensing circuit and a discriminator circuit for controlling a voltage regulating circuit, which regulates the supply voltage. The sensing circuit is coupled to the served device so that at least one performance parameter of the served device can be continuously measured.

Abstract: A method and a circuit for controlling a slew rate of a coil in a voice coil motor in a disk drive system. A slew rate control signal is generated by a microprocessor or by an analog circuit in response to one or more operating parameters of the disk drive system. A driver circuit selectively couples the coil between a voltage source and a ground in response to a driver signal, and controls the slew rate of the coil in response to the slew rate control signal.

Abstract: A circuit and method for measuring a back EMF voltage of a voice coil in a mass storage device, or the like, includes an amplifier connected across the coil to produce an output signal proportional to a voltage across the coil and a circuit connected to selectively connect the output signal of the amplifier to a circuit output when a driving current is not applied to said coil. A sample window is generated after drive currents within the coil have been allowed to decay to zero, and between a time during which a PWM signal changes from negative to positive and a time when the PWM waveform crosses a voltage error value.

Abstract: A method of parking the head by first moving the head toward the inner diameter of the disc an then back across the disc and parking the head on a flat part of a ramp. In one embodiment, a moderate voltage on the motor drives the head toward the inner diameter of the disc until the head hits the inner crash stop and then a moderate current drives the head back across the disc to give the head enough momentum to get to the flat part of he ramp. In another embodiment, more stages, each having a different voltage, are used to get better control of the velocity of the head as it is being driven across the disc. A higher voltage is also used to turn the head to move toward the inner diameter of the disc when it is moving fast toward the outer diameter. A retract circuit controls the movement of the head during retract. To be able to drive the head in the tow directions, the retract circuit needs to be bipolar, containing both a current source and a current sink. Counters are used to time the driving of the head.

Abstract: Methods and apparatuses are provided for use in driving a multiple-phase brushless motor. The methods and apparatuses include generating a slewed phase control signal for each phase of the motor. The slewed phase control signals are substantially proportional to a speed control signal during non-transitioning periods, and are slewed from one state to the next state over time during transitioning periods. The transitioning periods being associated with a commutation point. The slewed phase control signals are used to generate pulse width modulated (PWM) driving signals, for each phase of the motor. Thus, the shape of the resulting PWM driving signal will include additional PWM pulses during the transitioning period that provide for a trapezoidal shaping of the current supplied to each of the phase coils in the motor. The result is that torque ripple is reduced because the overall current applied to the motor and the torque resulting therefrom will tend to be more constant during commutation.

Abstract: A circuit for operating a polyphase DC motor, such as the type having a plurality of "Y" connected stator coils, has circuitry for charging the coils at a rate which will reduce EMI and other noise, while maintaining an acceptable charge rate. The gate of a selected high side driving transistor is charged at a relatively high rate during a ramping phase. During the ramping phase, the gates of the selected transistor is charged to a voltage near the voltage needed to form a channel in the transistor for conduction. After the ramping phase, the gates are charged at a lesser rate in order to control the rate of charging of the stator coils to prevent noise.

Abstract: A brushless DC motor system using PWM switching, in which the PWM switching is temporarily frozen whenever a zero crossing is expected in the back EMF. This avoids disruption of zero-crossing detection due to switching transients from the power transistor.