Abstract: A circuit for driving a power switch is presented. The circuit includes a first power switch coupled to a second power switch via a switching node and a driver coupled to the first power switch, where the driver contains an energy storing element coupled to the switching node. The circuit also contains a sensor to sense an electrical parameter of the driver and a charger coupled to the sensor. The charger provides a charge current to charge the energy storage element, and to control the charge current based on the electrical parameter. In particular, a circuit for driving a power switch based on a III/V semiconductor is presented. In addition, a method of powering a power switch driver is presented. The method includes sensing an electrical parameter of the driver and adjusting a current to charge the energy storing element based on the electrical parameter.

Abstract: A method and apparatus for limiting or preventing electromagnetic interferences in a switching converter are presented. In particular, a power circuit provided with an active electromagnetic interference filter is presented. There is an electromagnetic interference EMI reduction circuit for use with a switching converter. This EMI reduction circuit has a current source and is adapted to regulate a voltage across the current source to provide a current having a constant average value. The switching converter is adapted to provide a converter current, and the current source constant average value may be substantially equal to an average value of the converter current. The circuit has a variable resistance; and an adjuster adapted to adjust the variable resistance based on the converter current. The adjuster may have a comparator, which is adapted to compare a voltage value at a terminal of a transistor switch, and a reference value.

Abstract: A circuit for driving a power switch is presented. The circuit includes a first power switch coupled to a second power switch via a switching node and a driver coupled to the first power switch, where the driver contains an energy storing element coupled to the switching node. The circuit also contains a sensor to sense an electrical parameter of the driver and a charger coupled to the sensor. The charger provides a charge current to charge the energy storage element, and to control the charge current based on the electrical parameter. In particular, a circuit for driving a power switch based on a III/V semiconductor is presented. In addition, a method of powering a power switch driver is presented. The method includes sensing an electrical parameter of the driver and adjusting a current to charge the energy storing element based on the electrical parameter.

Abstract: An electronic circuit provided with a III/V semiconductor domain, and a method of operating such a circuit is presented. In particular, the present application relates to electronic circuit based on a Gallium Nitride (GaN) semiconductor. GaN components must be controlled in a way that ensures proper operation over a wide variation of GaN parameters. There is a circuit comprising a first domain coupled to a second domain, the first domain being based on a III/V semiconductor; wherein the first domain comprises a first component and a second component. The second component being representative of an electrical characteristic of the first component. The second domain contains a sensor adapted to sense an electrical quantity of the second component and an input generator coupled to the sensor. The input generator is adapted to provide at least one input, based on the electrical quantity, to the first domain.

Abstract: A circuit and method for regulating an internal power supply of a switching converter is presented. A switching converter with a depletion mode power switch coupled to an enhancement mode power switch via a switching node and an energy storing element coupled to the depletion mode power switch is provided. The energy storing element may be adapted to provide energy to the switching converter. For instance, the energy storing element may be a capacitor. Optionally, the switching converter may comprise an inductor coupled to the depletion mode transistor, the inductor being adapted to provide an inductor current.

Abstract: A method and apparatus for driving a power stage is presented. In particular, the power stage is a half-bridge. In the method, there is a first power switch coupled to a second power switch via a switching node. The method steps include sensing a first control-terminal voltage of one of the first power switch and the second power switch and turning on the first power switch based on the first control-terminal voltage and sensing a second control-terminal voltage of one of the first power switch and the second power switch and turning on the second power switch based on the second control-terminal voltage. Optionally, the first power switch is turned on when the first control-terminal voltage has reached a first threshold value, and the second power switch is turned on when the second control-terminal voltage has reached a second threshold value.

Abstract: An actuation system is proposed for an optical system, comprising a voice coil motor for actuating the optical system, the voice coil motor comprising a magnet and an electric coil, a position measuring unit for measuring the position of the electric coil and providing a position feedback signal, and a control unit for closed loop control of the position of the optical system based on a target position and the position feedback signal, used for generating a drive signal for the electric coil. According to the disclosure, a ferromagnetic element is arranged in proximity to the electric coil so that the inductance of the electric coil depends on its position. Further, the position-measuring unit measures the inductance of the electric coil and determines the position of the electric coil based on the determined inductance.

Abstract: A controller for a power converter to convert electrical power at an input voltage into electrical power at an output voltage and a method of operating such controller is presented. The controller for controlling a power converter has an input port to receive a voltage representative of the input voltage; an input voltage measuring unit to sample a measuring voltage and to determine a measurement value that is representative of the input voltage; a switch; and a diode connectable with a storage unit to provide a supply voltage for the controller during operation of the controller. The switch controls the charging of the storage unit from the voltage at the input port.

Abstract: A circuit arrangement comprising a first capacitor and a second capacitor which are arranged in series between a high potential and a low potential is described. The circuit arrangement comprises first power consuming circuitry which is arranged in parallel to the first capacitor. The first power consuming circuitry (113) consumes electrical power at a first voltage. The circuit arrangement comprises second power consuming circuitry which is arranged in parallel to the second capacitor. The second power consuming circuitry consumes electrical power at a second voltage, wherein a magnitude of the sum of the first voltage and the second voltage is smaller than an absolute difference between the high potential and the low potential. The circuit arrangement sets a voltage at the first capacitor in accordance to the first voltage and to set a voltage at the second capacitor in accordance to the second voltage.

Abstract: A wearable biometric device includes a biometric sensor system adapted to measure a predetermined physiological property of a user's body at two or more different locations at the body surface and to provide for each such location an associated primary signal indicative of said measured physiological property. The device also includes a detector system adapted to detect a level of coupling of the biometric sensor system with the body at each of the locations and to provide for each of the locations an associated secondary signal indicative of said detected level of coupling and also includes a signal processing unit adapted to generate an output signal indicative of said physiological property as a function of the primary and secondary signals.

Abstract: A switched mode power converter comprising a main inductor and a half bridge for providing an inductor current is described. The power converter comprises a first output power switch for directing the inductor current to a first output port and bypass circuitry for making at least part of the inductor current available for controlling the switching state of at least one of the power switches. Furthermore, the power converter comprises a control unit configured to control the first output power switch such that the inductor current is directed to the first output port within different first time intervals. Furthermore, the bypass circuitry is controlled to make the inductor current available for controlling the switching state of the at least one power switch during a non-overlapping time interval.

Abstract: A controller for a power converter to convert electrical power at an input voltage into electrical power at an output voltage and a method of operating such controller is presented. The controller for controlling a power converter has an input port to receive a voltage representative of the input voltage; an input voltage measuring unit to sample a measuring voltage and to determine a measurement value that is representative of the input voltage; a switch; and a diode connectable with a storage unit to provide a supply voltage for the controller during operation of the controller. The switch controls the charging of the storage unit from the voltage at the input port.

Abstract: A method for the start-up and/or the maintenance of a supply voltage for a driver circuit for a solid state light source is described. The driver circuit comprises a switched-mode power converter with a switch and a transformer. The switched-mode power converter converts an input voltage into an output voltage. The driver circuit has a controller which generates a gate control signal for putting the power converter switch into an on-state or an off-state. The driver circuit comprises a supply voltage capacitor to provide a voltage to the controller. A primary coil of the transformer is arranged in series with the power converter switch. A secondary coil arrangement of the transformer provides the output voltage. and is coupled to the supply voltage capacitor via a supply voltage transistor which is controlled such that the supply voltage provided by the supply voltage capacitor lies within a pre-determined voltage interval.

Abstract: A solid state lighting SSL assembly comprises an SSL device, a capacitor, a directional conducting device and a supply switch. The capacitor is coupled in parallel with the SSL device. The directional conducting device is coupled between an output terminal of the capacitor and a supply terminal which provides a supply voltage for the SSL assembly. The directional conducting device is configured to conduct in a direction from the output terminal to the supply terminal and to isolate in the opposite direction. The supply switch is coupled between the output terminal and ground. In addition, a method for operating a solid state lighting SSL assembly is proposed.

Abstract: An once a channel voltage exceeds a threshold, when the transistor is in an OFF state. This is over-voltage protection circuit for a transistor is presented. This circuit acts to switch on the transistor achieved with internal components which are integrated with the transistor, avoiding the need for external diodes or Zener structures. The circuit has a transistor with a control terminal, a first current carrying terminal and a second current carrying terminal. The over-voltage protection circuit has a level shifter arranged to feed back a level-shifted version of a channel voltage between said first and second current carrying terminals to the control terminal. The level shifter allows the switching threshold voltage of the transistor to be crossed when a predetermined value of the channel voltage is crossed.

Abstract: The present document relates to the measurement of the current through a transistor. In particular, the present document relates to a circuit arrangement which allows an accurate measurement of the current through a power transistor. A circuit arrangement is described. The circuit arrangement is configured to provide an indication of a current flowing through a pass switch, when the pass switch is arranged in parallel to the circuit arrangement. The circuit arrangement comprises a matching unit which comprises a switch bank comprising a plurality of parallel reference switches; a resistor bank comprising a plurality of serial reference resistors; and a reference current source configured to provide a reference current flowing through the switch bank and the resistor bank. The resistor bank and the switch bank are arranged in series.

Abstract: A converter and a method of operating a switching converter in a low power mode are presented. The invention relates to a III/V semiconductor switching converter. A switching converter contains a first power switch coupled to a second power switch via a switching node. There is an inductor coupled to the switching node, and a clamp circuit containing a third power switch is coupled in parallel to the first power switch. The switching converter is adapted to turn the first power switch off and to enable control of the third power switch upon identifying that the switching converter provides a low level of power.

Abstract: A driver circuit for generating a sequence of pulses of a drive voltage from a supply voltage is described. The drive voltage is used for operating an electrical actuator, such as an electrical engine or machine. The driver circuit comprises means for providing an amplitude indication of an amplitude of the supply voltage, which is used for generating a first pulse of the sequence of pulses. Furthermore, the driver circuit comprises an integration unit configured to integrate the amplitude indication for a duration of the first pulse, thereby generating an integrated voltage. In addition, the driver circuit comprises a comparator configured to compare the integrated voltage with a reference voltage, thereby generating a comparator signal. Furthermore, the driver circuit comprises a control unit configured to terminate the first pulse in dependence of the comparator signal.

Abstract: A method of monitoring a process of powering an electronic device through a cable assembly is proposed. The cable assembly comprises a cable which is connected between a power supply and the electronic device. The method comprises generating a synchronization signal, generating a test signal based on the synchronization signal and applying the test signal to one end of the cable, detecting a response signal at the one end of the cable, the response signal resulting from applying the test signal to the cable assembly, and determining, based on the response signal and the synchronization signal, a first and a second quantity indicative of a real part and an imaginary part of the impedance of the cable assembly, respectively. Further, an apparatus for monitoring a process of powering an electronic device through a cable assembly is proposed.

Abstract: Control circuit for a power converter that converts an input voltage into an output voltage is disclosed. The control circuit comprises a power switch; a power switch driver coupled with the power switch to control the switching state of the power switch so as to provide the output voltage at an output port of the power converter, the output port for coupling with a first terminal of a load; a load port for coupling with a second terminal of the load; a switching element coupled with the load port to selectively connect the load port to ground; and operating voltage supply means coupled with the load port, for providing an operating voltage to the control circuit.