Various implementations include portable speakers with dynamic display characteristics. In some particular aspects, a portable speaker includes an enclosure housing: at least one electro-acoustic transducer for providing an audio output; a processor coupled with the at least one transducer; an audio input module coupled with the processor for receiving audio input signals; and a battery configured to power the at least one transducer, the processor, and the audio input module; an input channel for receiving a hard-wired audio input connection; at least one wireless input channel for receiving an audio input from a source device via a wireless connection; and a display on the enclosure coupled with the processor, wherein the processor adjusts an orientation of the display between a first orientation and a second orientation in response to detecting a change in orientation of the portable speaker.

Various implementations include portable speakers with detachable wireless transmitters. In some particular aspects, a portable speaker includes an enclosure housing: at least one electro-acoustic transducer for providing an audio output, a processor coupled with the at least one transducer; an audio input module coupled with the processor for receiving audio input signals; and an input channel for receiving a hard-wired audio input connection at the enclosure; at least one wireless transmitter detachably housed in the enclosure and in communication with a corresponding wireless input channel for receiving audio input from a source device.

An electronic device is disclosed. The electronic device according to the present disclosure includes a body, a neck formed at one side of the body, and a head formed on the neck, wherein the head comprises: a circular part connected to the neck; a protrusion part protruding from one side of the circular part and having a curvature that is greater than a curvature of the circular part; a speaker hole formed at at least one of the circular part and the protrusion part; and a band part formed at the periphery of the speaker hole, and the thickness of the band part may be greater than the thickness of the circular part or the protrusion part around the band part.

Various implementations include portable speakers configured to adjust audio output based on detected input connections. In certain cases, a portable speaker includes: an enclosure housing: at least one electro-acoustic transducer for providing an audio output; a processor coupled with the transducer; an audio input module coupled with the processor for receiving audio input signals; and a battery configured to power the at least one transducer, the processor, and the audio input module; an input channel for receiving a hard-wired audio input connection; and at least one wireless input channel for receiving an audio input from a source device via a wireless connection, where the processor is configured to: adjust an audio signal received from the hard-wired audio input connection if a source device is already connected via the wireless connection.

The present invention provides a control method of an electronic device, wherein the control method includes the steps of: wirelessly connecting to a first device; performing a service discovery to the first device to retrieve a plurality of attribute handles from the first device; storing the plurality of attribute handles of the first device into a database cache; wirelessly connecting to a second device; determining whether the second device and the first device have the same attribute handles; and in response to the second device having the same attribute handles as the first device, directly using the plurality of attribute handles of the first device stored in the database cache, for using services of the second device.

The present application provides an audio transmission method and an electronic device. When the audio transmission method is performed by a first electronic device, the audio transmission method includes: obtaining target audio; and transmitting an audio signal of the target audio to a first channel playback apparatus or a second channel playback apparatus of a second electronic device through an Ultra Wide Band transport protocol.

A multifunctional earphone system for sports activities is described which comprises the following: a first apparatus configured to be carried in one of a user's ears, the first apparatus comprising a first data communication unit and a first loudspeaker, and a second apparatus configured to be carried in the user's other ear, the second apparatus comprising a second data communication unit and a second loudspeaker, wherein at least one of the first apparatus and the second apparatus comprises a sensor unit and a data processing unit, wherein the data processing unit is configured to generate performance data based on measurement data acquired by the sensor unit, wherein the first apparatus further comprises a signal processing unit configured to generate a binaural audio signal based on the performance data, the binaural audio signal comprising a first signal part to be output by the first loudspeaker and a second signal part to be output by the second loudspeaker, and wherein the first data communication unit is configured to communicate the second signal part of the binaural audio signal to the second data communication unit. Furthermore, a method is described.

A voice controlled assistant has a housing to hold one or more microphones, one or more speakers, and various computing components. The housing has an elongated cylindrical body extending along a center axis between a base end and a top end. The microphone(s) are mounted in the top end and the speaker(s) are mounted proximal to the base end. The microphone(s) and speaker(s) are coaxially aligned along the center axis. The speaker(s) are oriented to output sound directionally toward the base end and opposite to the microphone(s) in the top end. The sound may then be redirected in a radial outward direction from the center axis at the base end so that the sound is output symmetric to, and equidistance from, the microphone(s).

A wearable electronic device is provided that includes a battery, at least one solar panel configured to charge the battery, an output charger connected through a wire to the out least one solar panel, and a controller configured to charge an external electronic device through the output charger.

Disclosed is an apparatus for determining goodness of fit related to microphone placement capable of communicating with other electronic devices and an external server in a 5G communication network, in which an artificial intelligence (AI) algorithm and/or a machine learning algorithm are executed. The apparatus includes an inputter, a communicator, a storage, and a processor. As the apparatus is provided, sound recognition effects can be improved.