Abstract: The present disclosure describes a system with a power management device, a wakeup circuit, a battery management device, and a connector. During a powered down mode of operation, the battery management device can provide, via the connector, a bias voltage to the wakeup circuit. In response to a wakeup switch being activated, the battery management device can provide a power supply (e.g., from a battery) to the power management device. Benefits of the wakeup circuit include (1) a reduction of battery consumption—and thus improving battery lifetime—when the electronic system is in a powered down mode of operation because the wakeup circuit has lower number of active components compared to other designs and (2) a non-complex wakeup circuit design because one or more existing connector interconnects between the power management device and the battery management device can be re-used during electronic system's powered down mode of operation.

Abstract: A DC-DC converter includes a first differential voltage sensor to detect a first inductor current by sensing a first differential voltage across a first power stage of the DC-DC converter. A second differential voltage sensor detects a second inductor current by sensing a second differential voltage across a second power stage of the DC-DC converter. An integrator stage combines the first differential voltage from the first power stage and the second differential voltage from the second power stage to generate a compensation signal to adjust current balancing for the DC-DC converter.

Abstract: A DC-DC converter includes a first differential voltage sensor to detect a first inductor current by sensing a first differential voltage across a first power stage of the DC-DC converter. A second differential voltage sensor detects a second inductor current by sensing a second differential voltage across a second power stage of the DC-DC converter. An integrator stage combines the first differential voltage from the first power stage and the second differential voltage from the second power stage to generate a compensation signal to adjust current balancing for the DC-DC converter.

Abstract: A method is disclosed for controlling a first transistor in a half-bridge circuit which also includes a second transistor. The transistors can be controlled by applying drive voltages to their gates. During a switch-off operation of the second transistor, the amplitude of the drive voltage of the second transistor is compared with a first threshold value and a second threshold value. A switch-on operation for the first transistor is started following a specified first period which begins at a first time when the drive voltage of the second transistor undershoots the first threshold value. The first threshold value is set in accordance with a second period which begins at a second time when the amplitude of the drive voltage of the second transistor undershoots the second threshold value. The second period ends at another time when the first transistor adopts a specified initial operating state during the switch-on operation.

Abstract: Actions from multiple devices are synchronized to generate a representation that may be used for collaboration. Synchronization may include a roll-back procedure that allows an action on the representation, which may have been performed by another device at an earlier time, to be included in the representation. Also, a non-user of an application may be invited to use the application through an automated procedure that downloads and installs the application and establishes communication with the sender of the invitation, causing the new user to have an up-to-date representation. The automated procedure may be invoked by a single click on the invitation.

Abstract: A method and a device is provided for controlling a switching converter comprising a high side switch and a low side switch. The method comprises testing the high side switch for a short circuit, and upon detection of a short circuit in the high side switch, leaving the switching converter in an operationally reliable state or shifting the converter to an operationally reliable state.

Abstract: A method is disclosed for controlling a first transistor in a half-bridge circuit which also includes a second transistor. The transistors can be controlled by applying drive voltages to their gates. During a switch-off operation of the second transistor, the amplitude of the drive voltage of the second transistor is compared with a first threshold value and a second threshold value. A switch-on operation for the first transistor is started following a specified first period which begins at a first time when the drive voltage of the second transistor undershoots the first threshold value. The first threshold value is set in accordance with a second period which begins at a second time when the amplitude of the drive voltage of the second transistor undershoots the second threshold value. The second period ends at another time when the first transistor adopts a specified initial operating state during the switch-on operation.

Abstract: The invention relates to a method and a device for controlling a switching converter comprising a high side switch and a low side switch. According to the invention, means are provided which test the high side switch for a short circuit, and means are provided which, upon detection of a short circuit in the high side switch, leave the switching converter in an operationally reliable state or shift the converter to an operationally reliable state.