A wireless power system has electronic devices that mate with each other to transfer wireless power. Each device may have a wireless power coil. Alignment magnets may be used to magnetically attach devices to each other so that the coils in the devices are aligned with respect to each other for wireless power transfer. The system may include first, second, and third devices. The first and third devices may have fixed alignment magnets with poles of opposite magnetic polarity that allow the first and third devices to be attached to each other so that their coils are aligned. The second device may have a reconfigurable alignment magnet that is operable in a first mode in which the second device is magnetically attached to the first device and a second mode in which the second device is magnetically attached to the third device.

Systems disclosed herein are directed to a display stand unit for a retail environment. The display stand unit includes a base having an interior and a display stand. The display stand includes a stem that connects to and extends upwardly from the base and a receiving surface that is suspended above and spaced away from the base by the stem. The receiving surface is configured to releasably hold an electronic device above and spaced away from the base. The display stand unit further includes a security cable that extends out from the base. The security cable is configured to attach to the electronic device to movably secure the electronic device to the base. The display stand unit further includes a retractor disposed within the interior of the base and connected to the security cable. The retractor automatically retracts the security cable.

In one example in accordance with the present disclosure, an electronic device is described. An example electronic device includes a battery to provide power to the electronic device, a keyboard, and a keyboard-based charger to charge the battery by actuation of the keyboard. The example electronic device also includes a processor and memory storing executable instructions that when executed cause the processor to determine that a battery power is less than a threshold battery power and a power source is unavailable. The instructions also cause the processor to activate keyboard-based charging to charge the battery in response to determining that the battery power is less than the threshold battery power and a power source is unavailable. The instructions further cause the processor to generate a user notification to request keystrokes on the keyboard to charge the battery with the keyboard-based charger.

Method for activating predefined functions, implemented in a host appliance integrating or linked to a wireless charging device, and including the steps of: detecting that a mobile appliance has just been positioned on a reception surface of the wireless charging device in order to be recharged; following the detection that the mobile appliance has just been positioned on the reception surface, activating or deactivating at least one predefined first function performed by the host appliance, in addition to recharging the mobile appliance; then, detecting that the mobile appliance has just been moved away from the reception surface; following the detection that the mobile appliance has just been moved away from the reception surface, activating or deactivating at least one predefined second function performed by the host appliance.

A charging control method includes: obtaining a battery electric quantity of the terminal device and current state information of the terminal device; determining a target charging strategy according to the battery electric quantity and/or the current state information; and controlling the terminal device to be charged according to the target charging strategy.

A microcontroller, processor, and/or software (SW) monitors a battery degradation indicator such as battery State-Of-Health (SOH), impedance or other attributes, and calculates battery degradation rate and regulates burst power, battery charging speed and/or battery charging limit to meet users' expectation of battery service life. The microcontroller, processor, and/or SW increases the burst power, battery charging speed and/or battery charging limit when 1/SOH or impedance change rate (or related parameter) is smaller than expected and there is more longevity budget than expected. In another example, the microcontroller, processor, and/or SW decreases the burst power, battery charging speed and/or battery charging limit when 1/SOH or impedance change rate (or related parameter) is greater than expected and there is less longevity budget than expected.

An ear-wearable electronic device includes one or more processors configured to detect presence of first and second hearing devices in a charging case, and to initiate a self-check protocol by at least one of the first and second hearing devices. The self-check protocol comprises wirelessly coupling the first and second hearing devices, selectively activating at least one electronic component of the first hearing device, and assessing performance of the second hearing device using an output or a response of the at least one electronic component of the first hearing device. The self-check protocol also comprises selectively activating at least one electronic component of the second hearing device, assessing performance of the first hearing device using an output or a response of the at least one electronic component of the second device, and storing results of the performance assessment in a memory.

A charging apparatus having a backup function includes a first connecting interface, a second connecting interface, a processing unit, a memory unit, and an authorizing unit. The first connecting interface is adapted to receive a power source. When the processing unit authorizes the first electronic device, the processing unit activates the backup function to back up data stored on a first electronic device connected to the second connecting interface into the memory unit. Hence, a user can use the charging apparatus to charge the first electronic device, and to back up the data stored on the first electronic device into the memory unit or to restore the data stored on the memory unit into the first electronic. The user of the first electronic device can effortlessly enjoy the data backup and restore functionality.

A surgical system includes a power supply, a surgical instrument, and a power and data interface assembly. The power and data interface assembly includes a transformer having a primary winding and a secondary winding, a first modulator coupled to the primary winding and configured to receive a power signal from the power supply, a first demodulator coupled to the secondary winding, a second modulator coupled to the secondary winding, a second demodulator coupled to the primary winding, and at least one capacitor configured to tune the primary winding to a first resonant frequency and tune the secondary winding to a second resonant frequency different than the first resonant frequency.

An electronic device is provided. The electronic device includes a battery and a power management module electrically connected to the battery and configured to manage a charging or a discharging of the battery. The power management module includes a first charging circuit configured to include a first switch group, a first capacitor, and a first inductor, a second charging circuit configured to include a second switch group, a second capacitor, and a second inductor, and a power path distributor configured to distribute power from a first external power supply device or a second external power supply device to the first charging circuit or the second charging circuit.