A power supply device including a first charging accommodation, a second charging accommodation, a first interface electrically connected to a first power receiving device, and disposed in the first charging accommodation, a second interface electrically connected to a second power receiving device, and disposed in the second charging accommodation, a battery, and a processor configured to receive, via the first interface, first state of charge (SOC) information of the first power receiving device which is mounted in the first charging accommodation, receive, via the second interface, second SOC information of the second power receiving device which is mounted in the second charging accommodation, determine at least one charging parameter based on the first SOC information and the second SOC information, and charge the first power receiving device and the second power receiving device through the first interface and the second interface, respectively, based on the at least one charging parameter.

A method for wirelessly charging at least one hearing device (4) via at least one power transmission unit (14) is disclosed. The method comprises: Charging at least one power receiving and storing unit of the at least one hearing device (4) via a wireless charge field of the at least one power transmission unit (14); Turning off the at least one hearing device (4) when the at least one power receiving and storing unit of the at least one hearing device (4) is substantially fully charged; Rebooting the at least one hearing device (4) when the at least one wireless charge field is removed; and Determining the resonance frequency of a coil element of the at least one hearing device (4) after rebooting. Further, a hearing aid system is disclosed.

The present disclosure relates to compact hearing aids, components thereof, and support systems therefor, as well as methods of insertion and removal thereof. The compact hearing aids generally include a sensor, such as a microphone, an actuation mass, an energy source for providing power to the compact hearing aid, a processor, and an actuator enclosed in a housing that is designed to be inserted through the tympanic membrane during a minimally-invasive outpatient procedure. In operation, the microphone receives sound waves and converts the sound waves into electrical signals. A processor then modifies the electrical signals and provides the electrical signals to the actuator. The actuator converts the electrical signals into mechanical motion, which actuates the actuation mass to modulate the velocity or the position of the tympanic membrane.

A headset case includes a base providing a cavity for stowing a headset, the base including a bottom region configured to rest on a surface; a lid; and a hinge pivotably connecting the lid to the base. When the headset case is in a closed configuration, the lid covers the cavity. When the headset case is in an open configuration, a first section of the lid at least partially rests on the surface, and a second section of the lid, extending from the first section of the lid, is configured to prop up a smartphone by mechanically supporting the smartphone leaning against the second section of the lid while resting on the base.

A housing that has a first portion and a second portion having outer shapes of different sizes, the first portion being larger in the outer shape than the second portion; and a speaker that is disposed inside the housing and outputs sound are included. The first portion has a first bulging portion and a second bulging portion, each of which bulges toward an outer peripheral side with respect to the second portion, and fitted to an ear is achieved with the first bulging portion partially inserted into a space ranging from an ear concha to an intertragic notch in each of inside a tragus and inside an antitragus, and the second bulging portion inserted into the ear concha inside an antihelix.

An electronic device including a housing configured to accommodate a first portion of a bracket, the bracket defining a second portion having seating space in which the at least one earbud is at least partially accommodated; and a cover rotatably connected to the housing and configured to cover the second portion of the bracket, a third portion of the bracket being exposed to an exterior of the housing while covering an edge portion of the housing, the third portion includes at least one protrusion protruding inward toward the edge of the housing, the edge portion of the housing includes at least one groove, corresponding to the at least one protrusion and providing a space in which the at least one protrusion is movable, and the bracket transitions between a first position and a second position depending on positions of the at least one groove and the at least one protrusion.

A case (100) is provided for housing and charging one or more wireless devices (180), such as wireless earbuds. The case (100) includes capacitive sensing circuitry (120) for detecting whether the wireless devices (180) are positioned inside the case (100) based on a capacitance of the wireless devices (180). The case (100) also includes a transceiver (150) for transmitting data to and receiving data from the wireless devices (180). When the wireless devices (180) are positioned inside the case (100), an electrical component (110) inside the case operatively connects the capacitive sensing circuitry (120) and the transceiver (150) of the case (100) to the wireless devices (180). The case (100) further includes one or more processors (140) for controlling the capacitive sensing circuitry (120), the transceiver (150), and the electrical component (110).

Disclosed are a TWS earphone, a method and apparatus for reducing earphone energy consumption, and a computer-readable storage medium. The method for reducing earphone energy consumption comprises: determining whether a target earphone is in an off-ear state and is not placed in a charging case; if so, acquiring a timekeeping duration since the target earphone is taken off of an ear; determining whether the timekeeping duration exceeds a first preset threshold value; and if the timekeeping duration exceeds the first preset threshold value, performing energy consumption reduction processing on the earphone. According to the present application, the duration since an earphone is taken off of an ear is evaluated for the earphone that is taken off of the ear and is not placed in a charging case, so as to perform energy consumption reduction processing on the earphone that has been taken off of the ear for a relatively long duration, such that unnecessary power consumption of the earphone when same is in a not-in-use state can be effectively reduced, and the effective service time of the earphone after charging is prolonged.

An in-the-ear hearing device includes: a microphone configured to receive an audio signal; a signal processor configured to process the audio signal for compensating a hearing loss; a wireless communication unit being connected to the signal processor; a feeding network; a hearing device shell accommodating the microphone and the signal processor; a face plate positioned at the hearing device shell; and an antenna for electromagnetic field emission and electromagnetic field reception, the antenna coupled with the wireless communications unit, wherein the antenna has a first end, and wherein the feeding network is configured to feed the antenna via the first end of the antenna; wherein the antenna extends through the face plate at a first position; at least a part of the antenna extending from the faceplate being arch-shaped; and wherein a second end of the antenna is an electrically open end, or is coupled to a ground potential.

An apparatus includes a ear piece case housing, a receptacle within the ear piece case housing and configured to hold an earpiece, an earpiece connector at the receptacle and configured to electrically connect with the earpiece, and electromagnetic shielding materials integrated into the ear piece case housing to electromagnetically isolate the earpiece while the earpiece is contained within the case housing. The ear piece case housing may include a charger and a removable slide cover adapted for sliding over the charger.