Abstract: A multi-level power converter and a method using first, second, third and fourth switching elements, an inductor, and a flying capacitor are presented. A first terminal of the inductor may be connected to a switching terminal connecting the second and third switching elements. A first terminal of the flying capacitor may be connected to a terminal connecting the first and second elements. A second terminal of the flying capacitor may be connected to a terminal connecting the third and fourth switching elements. The multi-level power converter may have a first feedback circuit to generate control signals for setting the switching elements in a plurality of switching states for regulating an output voltage or an output current. The converter may have a second feedback circuit to generate control signals to allow the flying capacitor to be charged or discharged using an inductor current flowing through the inductor.

Abstract: A power supply has a multi-level DC-DC converter and a battery pack with two or more cells provided in series. The switching DC-DC converter provides a regulated voltage at an output. The converter has an energy storage element. The switching regulator is designed to selectively operate in two or more different modes. It switches between a first mode where one cell is connected (between battery and inductor of the converter), and the converter functions like a single cell buck converter and a second mode where two cells are connected in series and the converter functions like a two series cell buck converter. In general, any number of cells and modes can be provided, with successive cells being connected in series in each mode.

Abstract: A memory element is provided in which a logical state can be securely stored in all conditions even when input set and reset signals are overlapping. This is achieved through provision of an array of persistence latches with an asynchronous circuit that ensures correct operation. The persistence latches provide a persistent output for each of the first and second edges of each input. The memory element is arranged to receive a plurality of inputs including a first and second input. Each first and second inputs include a digital signal that can transition between a first state via a first edge which triggers transition from the first state to the second state and a second edge which triggers transition from the second state to the first state.

Abstract: A power supply is disclosed. The power supply includes a switching converter for providing an output voltage comprising a power switch coupled to a driver for driving the power switch with an on-off switching cycle; and a voltage threshold indicator. The voltage threshold indicator includes an input for receiving an output of the converter, and an output coupled to the driver. The voltage threshold indicator is adapted to provide a temperature compensated voltage threshold, and a control signal to control the on-off switching cycle. The control signal is adapted such that when the output voltage exceeds the temperature compensated voltage threshold, a value of the control signal changes.

Abstract: There is presented a boost converter and an associated method for starting the boost converter. The boost converter includes an input terminal for receiving an input voltage, an output terminal for providing an output voltage, a low-side power switch and a high-side power switch coupled at a switching node, and a voltage regulator coupled to the high-side power switch. The boost converter is also provided with a controller for operating the boost converter in a start-up phase. In the start-up phase the controller controls the boost converter to generate an intermediate voltage and increase the intermediate voltage to a predetermined value. The intermediate voltage is then provided to the voltage regulator to obtain a drive voltage. The high side power switch is then driven to increase the output voltage linearly up to a start-up voltage.

Abstract: A power converter and method using a flying capacitor, a first transistor, a second transistor, a third transistor, a fourth transistor, and a driver circuit are presented. The first transistor is coupled between an input terminal and a first terminal of the flying capacitor. The second transistor is coupled between the first terminal of the flying capacitor and an output terminal. The third transistor is coupled between the output terminal and a second terminal of the flying capacitor. The fourth transistor is coupled between the second terminal of the flying capacitor and a reference potential. The driver circuit is coupled between a high side power rail and a low side power rail. There is a regulation circuit to regulate a high side voltage of the high side power rail such that the regulated high side voltage is independent of an input voltage at the input terminal.

Abstract: A communication system and an IoT system are provided. The IoT system is applicable to a wireless network system including an access point. The IoT system includes a WiFi module and a GPIO device. The WiFi module is configured to connect to the access point. The GPIO device is configured to provide a plurality of wake-up signals to the WiFi module through a GPIO pin. A predetermined time period between any two of wake-up signals is greater than an interval between two delivery traffic indication messages from the access point. The WiFi module includes a timer and a power management unit, the power management unit drains power to transfer the WiFi module from a sleep mode to a normal mode after the timer receives the wake-up signal.

Abstract: The present document describes a level-shifter circuit and method to transmit data from a high-voltage domain to a low-voltage domain. The level-shifter circuit has a first current path with a first current control unit to set a first current based on a high-voltage data signal in the high-voltage domain; and a second current path with a second current control unit to set a second current based on the high-voltage data signal. Furthermore, the circuit has an isolation unit to transfer the first current and the second current from the high-voltage domain to the low-voltage domain; and a current comparator unit to compare the first current with the second current to provide a low-voltage data signal in the low-voltage domain, which corresponds to the high-voltage data signal.

Abstract: An apparatus and method for controlling an oscillating device is presented. In particular, a controller for adjusting the frequency of a drive signal driving a haptic actuator is presented. The controller contains a calculator adapted to receive a first and a second measurement of the electrical parameter and to calculate a difference between the first measurement and the second measurement. The first measurement is obtained at a first sampling time and the second measurement is obtained at a second sampling time. The controller is adapted to provide a control signal to adjust a frequency of the drive signal based on the difference.

Abstract: An output current calibration is disclosed to increase the accuracy and precision of the constant-current mode for a flyback converter.

Abstract: A circuit and a method for providing a switchable current linkage between a first terminal and a second terminal is presented. The circuit has a transistor switch and a charge pump circuit An output node of the charge pump circuit is coupled to a control terminal of the transistor device, and an input node of the charge pump circuit is coupled to a predetermined voltage. The charge pump generates a boosted voltage. A drive circuit provides feedback control for the current flowing through the transistor. The drive circuit also controls the voltage magnitude at the input node of the charge pump circuit in accordance with the feedback control or to control a magnitude of a voltage at the control terminal of the transistor device in accordance with the feedback control.

Abstract: A switching power converter is provided with a phase-shifting RC network for phase-shifting a divided version of a drain voltage of a power switch transistor into a phase-shifted voltage. A comparator compares the phase-shifted voltage to a DC bias voltage to detect peaks and valleys during resonant oscillations of the drain voltage of the power switch transistor.

Abstract: An isolated switching power converter communication channel is provided that comprises a pair of capacitors. A transmitter on a first side of a transformer for the converter transmits a transmitter signal over a first one of the capacitors. The transmitter also transmits a complement of the transmitter signal over a second one of the capacitors. A receiver on a second side of the transformer recovers a signal responsive to a high-pass-filtered difference of the received signals from the pair of capacitors.

Abstract: An electronic biasing circuit provides a DC bias voltage to a circuit to be biased. The biasing circuit has a first transistor and a second transistor. A gate of the first transistor is connected to a gate of the second transistor and supplies the DC bias voltage. A source of the first transistor is connected to a supply reference voltage. A source of the second transistor is connected to the supply reference voltage via a resistor element. The currents flowing through the first and second transistor are forced to be equal. A third transistor is connected in series with the first transistor and a fourth transistor is connected in series with the second transistor. Currents flowing through the third and fourth transistors are forced to be equal.

Abstract: An apparatus and method for stopping a linear resonant actuator is presented. A control system for use with an oscillating device has a response signal having a back electromotive force component and a driver adapted to provide a drive signal to the oscillating device. The control system has a sensor adapted to sense an electrical parameter of the response signal and a controller coupled to the sensor and to the driver. The controller has a calculator adapted to determine a sign of curvature of a portion of the response signal based on the electrical parameter, and the controller is adapted to provide a control signal to adjust the amplitude of the drive signal to slow down the oscillating device, and withdraw the drive signal upon identifying a change in the sign of curvature.

Abstract: A system is disclosed which provides feedback voltage DC level cancelling for a configurable output of a DC-DC switching converter. By simplifying the design, the operational amplifier can be used for a wider output voltage range. Extension of the usage case to a Boost DC-DC switching converter can give noticeable performance improvements. Offset introduction using a flying capacitor is attractive because it does not require trimming. The proposal also allows for improvements for DC-DC switching converters designed for lower supply voltages, with no decrease in the differential input signal swing.

Abstract: A dimmer for dimming light emitted by a light source is presented. The dimmer includes a regulation switch for regulating a current flowing through the light source and a regulator circuit that provides an electronic parameter to control the regulation switch. The regulator circuit has a dimmer switch for passing or blocking the electronic parameter, and a signal generator generating a plurality of modulated signals configured to operate the regulator circuit in a first phase and in a second phase. In the first phase the regulation circuit maintains the electronic parameter to a target value. In the second phase the regulation circuit monitors a variation of the electronic parameter and maintains the electronic parameter to a predetermined value.

Abstract: A system in package is provided comprising an embedded trace substrate having redistribution layers therein, at least one passive component mounted on one side of the embedded trace substrate and embedded in a first molding compound, at least one silicon die mounted on an opposite side of the embedded trace substrate and embedded in a second molding compound wherein electrical connections are made between the at least one silicon die and the at least one passive component through the redistribution layers, and solder balls mounted through openings in the second molding layer to the redistribution layers wherein the solder balls provide package output.

Abstract: Linear voltage regulators and a method for low-dropout LDO regulators are presented. Specifically, LDO regulators with circuits for noise reduction are discussed. A linear voltage regulator has a first noise reduction filter, an error amplifier circuit, and a pass device. The pass device may be coupled between an input and output terminal of the regulator. The error amplifier circuit generates a control signal for controlling the pass device based on a filtered reference signal and an output voltage at the output terminal of the regulator. The first noise reduction filter generates the filtered reference signal based on a reference voltage of a reference voltage source by reducing noise originating from the reference voltage source or noise generated by one or more passive components coupled between the reference voltage source and the first noise reduction filter.

Abstract: A system in package is described comprising a substrate having a top side and a bottom side, having redistribution layers therein, and having a cavity extending partially into the top side of the substrate. At least one passive component is mounted on the top side of the substrate and into the cavity and embedded in a first molding compound. At least one silicon die is mounted on the bottom side of the substrate and embedded in a second molding compound wherein electrical connections are made between the at least one silicon die and the at least one passive component through the redistribution layers. Solder balls are mounted through openings in the second molding compound to the redistribution layers wherein the solder balls provide package output.