Abstract: An electrical switching system includes a constant-power controller and a switching device electrically coupled between a first node and a second node. The constant-power controller is configured to (a) generate a digital control signal to control the switching device, (b) control a duration of an active phase of the digital control signal at least partially based on a voltage across the switching device, and (c) control a peak value of the digital control signal to regulate a peak magnitude of current flowing through the switching device.

Abstract: A resonant power converter includes a capacitive divider circuit, a coupled inductor, and N switching stages, where N is an integer greater than two. The coupled inductor includes N windings, and total leakage inductance of the coupled inductor and equivalent capacitance of the capacitive divider circuit collectively form a resonant tank circuit of the resonant power converter. Each switching stage is electrically coupled between a respective one of the N windings of the coupled inductor and the capacitive divider circuit. The capacitive divider circuit may include one or more resonant capacitors.

Abstract: An electrical switching system includes a constant-power controller and a switching device electrically coupled between a first node and a second node. The constant-power controller is configured to (a) generate a digital control signal to control the switching device, (b) control a duration of an active phase of the digital control signal at least partially based on a voltage across the switching device, and (c) control a peak value of the digital control signal to regulate a peak magnitude of current flowing through the switching device.

Abstract: An electrical switching system includes a constant-power controller and a switching device electrically coupled between a first node and a second node. The constant-power controller is configured to (a) generate a digital control signal to control the switching device, (b) control a duration of an active phase of the digital control signal at least partially based on a voltage across the switching device, and (c) control a peak value of the digital control signal to regulate a peak magnitude of current flowing through the switching device.

Abstract: A resonant power converter includes a capacitive divider circuit, a coupled inductor, and N switching stages, where N is an integer greater than two. The coupled inductor includes N windings, and total leakage inductance of the coupled inductor and equivalent capacitance of the capacitive divider circuit collectively form a resonant tank circuit of the resonant power converter. Each switching stage is electrically coupled between a respective one of the N windings of the coupled inductor and the capacitive divider circuit. The capacitive divider circuit may include one or more resonant capacitors.

Abstract: An electrical switching system includes a constant-power controller and a switching device electrically coupled between a first node and a second node. The constant-power controller is configured to (a) generate a digital control signal to control the switching device, (b) control a duration of an active phase of the digital control signal at least partially based on a voltage across the switching device, and (c) control a peak value of the digital control signal to regulate a peak magnitude of current flowing through the switching device.

Abstract: A differential signal transfer system includes a dynamic level-shifter and a common-mode rejection device. The dynamic level-shifter is configured to (a) receive an input signal including a differential-mode component and a first common-mode component and (b) generate a level-shifted signal from the input signal, the level-shifted signal including the differential-mode component and a second common-mode component that is different from the first common-mode component. The common-mode rejection device is configured to receive the level-shifted signal and generate an output signal therefrom, where the output signal includes the differential-mode component.

Abstract: Methods and systems are provided for managing knowledge. Users of the knowledge management (KM) service or system may provide post questions, provide answers or search for answers via a user interface. For a given question, users may collectively construct and refine an answer hierarchy that may include multiple answer paths or solutions to the same question. To this end, users may add, remove and/or modify nodes of the answer hierarchy. The nodes may be of predefined types such as Step, Goto or Fork. In addition, users may provide or modify content specific to individual nodes of the answer hierarchy such as attachments, questions, references or comments. Given an answer hierarchy, users may preview alternate paths and compare different answer paths representing different solutions based on user-specific fact patterns or requirements before making their selections along a particular path to a solution.

Abstract: A differential signal transfer system includes a dynamic level-shifter and a common-mode rejection device. The dynamic level-shifter is configured to (a) receive an input signal including a differential-mode component and a first common-mode component and (b) generate a level-shifted signal from the input signal, the level-shifted signal including the differential-mode component and a second common-mode component that is different from the first common-mode component. The common-mode rejection device is configured to receive the level-shifted signal and generate an output signal therefrom, where the output signal includes the differential-mode component.

Abstract: Methods and systems are provided for managing knowledge. Users of a knowledge management (KM) service or system may post questions, provide answers or search for answers via a user interface. For a given question, users may collectively construct and refine an answer hierarchy that may include multiple answer paths or solutions to the same question. To this end, users may add, remove and/or modify nodes of the answer hierarchy. The nodes may be of predefined types such as Step, Fork, and Goto. In addition, users may interact with a particular node and provide or modify content specific to individual nodes of the answer hierarchy such as attachments, questions, comments, or references. Given an answer hierarchy, users may select different answer paths or solutions comprising a subset of nodes in the answer hierarchy, for example, based on user-specific fact patterns or requirements.

Abstract: An electric circuit comprising means for communicating with an external device coupled to means for measuring the charge condition of an external battery. In some embodiments, the circuit comprises at least one level shifter for changing the reference voltage of communication signals. In some embodiments, the circuit comprises a first driver and a second driver for driving external switching elements for the controlled charge and discharge of the battery.

Abstract: A high side circuit includes at least one power device having a first non-drivable terminal connected to a supply voltage, at least one load connected between a second non-drivable terminal of the power device and ground, and driving circuitry. The driving circuitry includes transistors which are connected to each other and to a higher voltage than the supply voltage in order to control the turning on and the turning off of the power device and to reduce or minimize the potential difference between the second non-drivable terminal and a drivable terminal of the power device during the turning off state to avoid the re-turning on of the same power device.

Abstract: A current control method controls current for drive systems of multi-phase brushless motors, in particular at phase switching, wherein the motor coils coupled to a common node are driven by applying a respective drive voltage to the free end of each coil via corresponding power stages. The method comprises switching the current flow from one phase to the next in the direction of rotation of the motor at the phase switch, thereby forcing the unaffected one of said coils by the phase switch into a state of high impedance. Advantageously, the decreasing rate of the current in the coil unaffected by the phase switch can be twice as high as the decreasing rate of the current in the phase being switched from.

Abstract: The device and method monitor the current delivered to a load through a power transistor including a sense transistor. The circuit includes a disturbances attenuating circuit that has a differential stage, and first, second and third stages referenced to ground, the respective input nodes of which are connected in common to an output node of the differential stage. The third stage is formed by a transistor identical to a transistor of the first stage and delivers a current signal through a current terminal thereof, proportional to the current being delivered to the load.

Abstract: The device and method monitor the current delivered to a load through a power transistor including a sense transistor. The circuit includes a disturbances attenuating circuit that has a differential stage, and first, second and third stages referenced to ground, the respective input nodes of which are connected in common to an output node of the differential stage. The third stage is formed by a transistor identical to a transistor of the first stage and delivers a current signal through a current terminal thereof, proportional to the current being delivered to the load.

Abstract: A current control method controls current for drive systems of multi-phase brushless motors, in particular at phase switching, wherein the motor coils coupled to a common node are driven by applying a respective drive voltage to the free end of each coil via corresponding power stages. The method comprises switching the current flow from one phase to the next in the direction of rotation of the motor at the phase switch, thereby forcing the unaffected one of said coils by the phase switch into a state of high impedance. Advantageously, the decreasing rate of the current in the coil unaffected by the phase switch can be twice as high as the decreasing rate of the current in the phase being switched from.

Abstract: An integrated device for a switching system is disclosed. The device includes control circuitry for generating at least one switching control signal, reference circuitry for generating at least one reference quantity, a using circuit for using the reference quantity, a circuit for storing the reference quantity, and a switch which, in a first operative condition, connects the reference circuit to the using circuit and to the storage circuit in order to apply the reference quantity thereto. In a second operative condition, the switch disconnects the reference circuit from the using circuit and connects the storage circuit to the using circuit in order to apply the stored reference quantity thereto. Finally, the device includes filtering circuitry for keeping the switch in the second operative condition for a filtering period in accordance with the switching of the control signal.

Abstract: A circuit for charging a capacitance using an LDMOS integrated transistor functioning as a source follower and controlled, in a manner to emulate a high voltage charging diode of the capacitance. The LDMOS transistor is controlled via a bootstrap capacitor charged by a diode at the supply voltage of the circuit, and by an inverter driven by a logic control circuit as a function of a Low Gate Drive Signal and of a second logic signal which is active during a phase wherein the supply voltage is lower than the minimum switch-on voltage of the integrated circuit. The circuit uses a first zener diode to charge the bootstrap capacitor and the source of the transistor is connected to the supply node through a second zener diode.

Abstract: A circuit for charging a capacitance using an LDMOS integrated transistor functioning as a source follower stage and controlled, in a manner to emulate a high voltage charging diode of the capacitance via a bootstrap capacitor charged by a diode connected to the supply node of the circuit, and by an inverter driven by a logic control circuit as a function of a first Low Gate Drive Signal and of a second logic signal. The second logic signal is active during a phase where the supply voltage is lower than the minimum switch-on voltage of the integrated circuit. The circuit further includes a second inverter functionally referred to the charging node of the bootstrap capacitor and to the voltage of the output node of the inverter. The second inverter has an input coupled to the second logic signal and an output coupled to the gate node of the LDMOS transistor for preventing accidental undue switch-on of the LDMOS transistor.

Abstract: A circuit for charging a capacitance using an LDMOS integrated transistor controlled in a manner to emulate a high voltage charging diode of the capacitance. The circuit avoids the switch-on of parasitic bipolar transistors of the LDMOS structure during transient states. The circuit includes a number of junctions directly biased between a source node and a body node of the LDMOS transistor, a current generator referred to a ground of the circuit, at least one switch between the source and a first junction of a chain of directly biased junctions, and a limiting resistor connected between the body and the current generator referred to ground. The switch is open during a charging phase of the capacitance and is closed when the charging voltage of the capacitance exceeds a preestablished threshold responsive to a control signal.