Abstract: A control circuit for a switch, configured to measure the drain-to-source current of the switch is described. The control circuit is configured to control an external transistor and comprises a control pin coupled to the gate of an external transistor. The external transistor and a level shifting unit are coupled to the control pin and configured to isolate an AC current from the control pin; at a time instant subsequent to the first pulse duration, the isolated AC component of the voltage potential is indicative of a drain-to-source current through the external transistor.

Abstract: A driver circuit for programmable solid state light bulb assemblies including light emitting diodes is operable to provide a drive current to a light source of the light bulb assembly. The controller comprises a data storage unit storing a test scenario for calibration of the light bulb assembly; wherein the test scenario indicates a sequence of states of the light source; wherein a state of the light source is associated with settings of the driver circuit; a data input unit receiving a command signal via a modulated electricity supply signal; and a data processing unit retrieving the test scenario from the data storage unit; in dependence of the received command signal, generating a control signal for operating the light source in at least one state of the sequence of states of the test scenario; and to output the control signal.

Abstract: The present document discloses a driver circuit for the high side switch of a half bridge at ultra-high voltage. The half bridge comprises the high side switch coupled to an input voltage Vin and to a midpoint of a low side switch. The driver circuit comprises a control signal generation unit generating a stream of control pulses and a control logic generating a gate voltage for the high side switch using a supply voltage Vcc based on the control pulses, a supply voltage capacitor generating the supply voltage Vcc, and a decoupling capacitor coupled on a first side to the control signal generation unit and on a second side to the control logic, to the midpoint of the half bridge via a first charging switch, and to the supply voltage capacitor via a second charging switch.

Abstract: The present document relates to the compensation of voltage variations within power converters. A driver circuit for a solid state light source is described. The driver circuit comprises a switched-mode power converter comprising a switch; wherein the switched-mode power converter is configured to convert an input voltage at an input of the switched-mode power converter into an output voltage at an output of the switched-mode power converter. Furthermore, the driver circuit comprises current sensing means configured to determine a sensed current signal indicative of a current through the switch; and voltage sensing means configured to determine a sensed voltage signal indicative of the input voltage. In addition, the driver circuit comprises a control unit configured to determine a gate control signal for putting the switch into an off-state, based on the sensed current signal and based on the sensed voltage signal.

Abstract: A digital color imager providing an extended luminance range, an improved color implementation and enabling a method for an easy transformation into another color space having luminance as a component has been achieved. Key of the invention is the addition of white pixels to red, green and blue pixels. These white pixels have either an extended dynamic range as described by (U.S. Pat. No. 6,441,852 to Levine et al.) or have a larger size than the red, green, or blue pixels used. The output of said white pixels can be directly used for the luminance values Y of the destination color space. Therefore only the color values and have to be calculated from the RGB values, leading to an easier and faster calculation. As an example chosen by the inventor the conversion to YCbCr color space has been shown in detail.

Abstract: Controllers for driver circuits of solid state light bulb assemblies including light emitting diodes comprise a power converter, a data storage unit operable to store data items relating to an operating behavior of the light bulb assembly, a temperature sensor operable to determine a chip temperature of the controller, and a data processing unit operable to receive the chip temperature, to retrieve the stored data items from the data storage unit, to generate a control signal in dependence upon the chip temperature and the retrieved data items, and to output the control signal to the power converter for operation of the light source.

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: The present document relates to driver circuits and/or power converters, e.g. for Solid State Lighting (SSL) devices, such as Light Emitting Diodes (LEDs). A controller for a driver circuit which is configured to provide a drive voltage to a load subject to an input voltage is described. The driver circuit comprises a power converter network and a power transistor. The controller comprises a control transistor which is configured to couple or to decouple a low voltage terminal of the power transistor to or from a low voltage potential, to put the power transistor to a conduction-state or an off-state, respectively. Furthermore, the controller comprises a charging transistor, arranged in parallel to the control transistor, and configured to couple or to decouple the low voltage terminal of the power transistor to a supply voltage capacitor, to put the power transistor to the conduction-state or off-state, respectively.

Abstract: The present document relates to voltage regulators. In particular, the present document relates to a method and a corresponding voltage regulator with improved performance subject to load transients. A regulator configured to provide a load current at an output voltage in dependence of an input voltage is described. The regulator comprises a core regulator configured to provide a core current at a core output voltage in dependence of the input voltage. Furthermore, the regulator comprises current sensing means configured to provide an indication of the core current. The output voltage is dependent on the core output voltage and on a voltage drop at the current sensing means. In addition, the regulator comprises a current source configured to provide an auxiliary current based on the indication of the core current. The load current is dependent on the core current and on the auxiliary current.

Abstract: The present document relates to Direct Current (DC) to DC power converters. In particular, the present document relates to DC to DC power converters which comprise one or more bipolar transistors as power switches. A control circuit configured to control a power switch of a switched-mode power converter is described. The power switch comprises a bipolar transistor. The control circuit is configured to determine an indication of a time instant, at which the power switch is switched off; and to adjust a basis current for controlling the power switch based on the determined indication of the time instant.

Abstract: Driver circuits to reduce or remove flicker of SSL devices are presented. A controller for a power converter which converts electrical power at an input voltage into electrical power at an output voltage is described. The controller is configured to determine whether the input voltage is greater or smaller than a pre-determined voltage threshold ; to operate a first switcher stage to transfer electrical power from the input of the power converter to the output of the power converter, during a first time period when the input voltage is greater than the pre-determined voltage threshold; and to operate a second switcher stage to transfer electrical power from the reservoir capacitor to the output of the power converter, during a second time period when the input voltage is smaller than the pre-determined voltage threshold.

Abstract: A light bulb assembly comprises an electrical connection module, a driver circuit configured to provide electrical energy at a drive voltage, and a light source. The driver circuit converts electrical energy at an input voltage to the electrical energy at the drive voltage. A controller is configured to control the power converter to provide electrical energy at the drive voltage. The controller stops operation at an interruption of electrical energy to the driver circuit. The controller is configured to resume operation subsequent restoration of electrical energy to the driver circuit. The controller is configured to maintain the timing voltage above a first voltage level when the controller is in operation and to determine the duration of an interruption of electrical energy to the driver circuit.

Abstract: Described is a rectification circuit to generate a direct current at an output of the rectification circuit subject to an alternating voltage at an input of the rectification circuit. The rectification circuit comprises: coupling means at the input to receive the alternating voltage from a galvanically decoupled electronic subsystem; a first switch arranged between the coupling means and the output to block current in a first direction and to conduct current in a second direction, wherein a resistance of the first switch is adjustable; a first modulation unit to receive encoded information; mapping the encoded information to a first modulation state, wherein each modulation state specifies a resistance value and/or a temporal evolution of the resistance value; adjusting the resistance of the first switch, thereby modulating the current conducted by the first switch according to the first modulation state.

Abstract: Techniques for controlled dimming of an illuminant such as, for example, a light-emitting diode (LED), an organic light-emitting diode (OLED) or gas discharge lamp are described herein. In one example, a control difference formed by subtracting actual values from desired values (dimming values) is smaller than actual values fed back by the lamp. Thus, without directly digitizing an analog feedback variable, the example digitizes a control difference (control deviation) determined in the analog domain, in order to process the latter in a digital control algorithm that determines a digital manipulated variable that influences power to the illuminant.

Abstract: The present document relates to the programming of programmable memory devices, e.g. one-time programmable (OTP) memory device. In particular, the present document relates to efficient methods and systems for generating the supply voltage for programming a programmable memory device. A controller configured to control the programming of a data word into a programmable memory device is described. The controller is configured to set one or more digital control signals for programming the data word into the programmable memory device. Furthermore, the controller is configured to, subsequent to setting the one or more digital control signals, increasing a device supply voltage for the programmable memory device from a default operation level to a programming level.

Abstract: The present document relates to the control of high side switches, e.g. the high side switches of half bridges. In particular, the present document relates to an efficient control circuit for controlling a plurality of high side switches. A control circuit for controlling a plurality of parallel high side switches of a respective plurality of parallel bridges is described. The control circuit comprises a charge provisioning unit configured to provide an electrical charge. Furthermore, the control circuit comprises a plurality of sets of high control switches for the plurality of high side switches, respectively; wherein each set of high control switches is configured to arrange the charge provisioning unit in parallel to a gate-source capacitance of the respective high side switch.

Abstract: The present document relates to providing power for driving SSL devices. A power converter converts a varying input voltage to supply an output voltage to a SSL device in series with a current source. The power converter comprises one or more capacitors; a plurality of switches to couple the capacitors in a plurality of configurations. A control unit operates the power converter in a plurality of operational modes providing a corresponding plurality of different conversion ratios between the input/output voltages. The operational modes comprise a first phase and a second phase, during which the capacitors are differently arranged. The control unit controls the switches to alternate between the phases at a commutation cycle rate. The control unit sets the operational mode based on the varying input voltage.

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 power supply or driver circuit configured to provide electrical energy at a drive voltage. The driver circuit converts electrical energy at an input voltage to the electrical energy at the drive voltage. A controller is configured to control the power converter to provide electrical energy at the drive voltage. The controller stops operation at an interruption of electrical energy to the driver circuit. The controller is configured to resume operation subsequent restoration of electrical energy to the driver circuit. The controller is configured to maintain the timing voltage above a first voltage level when the controller is in operation and to determine the duration of an interruption of electrical energy to the driver circuit.

Abstract: A driver circuit using a power converter allows free-wheeling detection and/or provision of supply voltage. A circuit controls a switching state of a power switch. A first port of the switch is coupled to an inductor. The circuit is coupled to a control port of the switch wherein the control port of the switch is different from the first port of the switch. The circuit comprises a unit generating a signal for controlling the switching state of the switch wherein the signal is provided to the control port of the switch. Furthermore, the circuit comprises free-wheeling sensing means to detect an oscillation of a voltage at a measurement port of the switch wherein the measurement port of the switch is different from the first port of the switch and wherein the oscillation of the voltage at the measurement port indicates free-wheeling of the inductor.