A method for user recognition and emotion monitoring based on a smart headset is provided. —The smart headset includes an earplug part and a main body, wherein the earplug part is provided with a first microphone and a wearing detection sensor, and a housing of the main body is provided with a signal amplification circuit, a communication module, and a microcontroller. The wearing detection sensor is to detect whether a user wears the smart headset, and the first microphone is to obtain a sound signal in an ear canal. The sound signal is amplified, and then is outputted to the microcontroller. The amplified sound signal is transmitted by the microcontroller to a smart terminal paired with the smart headset to extract a heart sound signal characteristic, and legality of—identity of the user is validated and emotional state of the user is inferred according to the heart sound signal characteristic.

A noise reduction communication system, which includes a sending and receiving device arranged in a control room, an acoustic-electro conversion device arranged in a scanning room, and an air tube microphone headset connected to the acoustic-electro conversion device. The sending and receiving device is connected with the acoustic-electro conversion device. The air tube microphone headset is used for communication between the control room and the scanning room, wherein the noise reduction module is provided after the acoustic signals of the air tube microphone headset and the acoustic-electro conversion device are converted into electrical signals. The present disclosure can not only realize two-way wireless transmission of voice messages between the control room and the scanning room of MRI, but also reduce the noise during the transmission, thus improving the quality of voice transmission.

Embodiments of this application provide a headset theme adaptation method, so that related information such as a device model and a device identifier of a headset case protective cover can be automatically obtained through multi-end linkage between a mobile phone, a headset, the headset case protective cover, and a cloud server (for example, a server of a cloud theme market), and a headset theme adapted to the protective cover is downloaded and applied based on the related information, to implement personalized experience of headset theme adaptation.

A portable electronic assembly and an adherable earphone structure thereof are provided. The adherable earphone structure includes a carrier substrate, an audio signal receiver, an audio signal processor, an audio signal player, a protective layer, and an adhesive layer. The audio signal receiver is configured for receiving an audio signal provided by a portable electronic device. The audio signal processor and the audio signal player are disposed on the carrier substrate and electrically connected to the audio signal processor. The protective layer is configured for covering the audio signal receiver, the audio signal processor and the audio signal player. The adhesive layer is disposed on the carrier substrate or the protective layer. When the adhesive layer is disposed on a face and near an ear of a user, the adherable earphone structure is disposed outside the ear of the user without touching the ear by the adhesive layer.

An ear cup housing has several reference microphones, an error microphone and a speaker. A processor drives the speaker for acoustic noise cancellation and transparency, by processing the microphone signals, and performs an oversight process by adjusting the reference microphone signals in response to detecting wind noise events and scratch events. In another aspect, the ear cup housing has an outside face that is joined to an inside face by a perimeter and the reference microphones are on the perimeter. Other aspects are also described and claimed.

The present disclosure relates to an in-ear wearable device and a panel assembly thereof. The panel assembly of the in-ear wearable device includes a panel, a mainboard, a manipulation device, a charging device, a battery, an antenna device, a sound pickup device, a speaker assembly, and a wireless communication module. In a plane perpendicular to the panel or the manipulation device, an orthographic projection of the manipulation device partially overlaps an orthographic projection of the charging device; in a plane where the panel or the manipulation device is located, minimum circumscribed circles of the orthographic projections of the manipulation device and the charging device at least partially overlap each other.

A flexible arm that is configured to be located between and physically and electrically connect an acoustic module of an open-ear headphone to a battery housing of the open-ear headphone. The flexible arm defines an original resting length and position between the acoustic module and the battery housing. The flexible arm includes a flexible printed circuit that extends through the entire original resting length of the flexible arm and comprises a conductor that is configured to carry electrical energy between the acoustic module and the battery housing. A first interface structure is coupled to one of the acoustic module and the battery housing. A flexible material encases at least some of the flexible printed circuit and at least some of the first interface structure.

Some headphone systems include two ear cups, a headband assembly, an interface system and a control system. Each ear cup may include an ear cup enclosure, an ear pad assembly, a speaker system and a hinge assembly. The hinge assembly may be disposed within the ear cup enclosure such that it is not visible from outside the ear cup. The headband assembly may connect with each of the ear cups via the hinge assembly. The interface system may include at least one interface and a plurality of input source buttons disposed on at least one of the ear cups. Each of the input source buttons may be configured for selecting a source of audio data received via the at least one interface. The control system may be configured for controlling the speaker system to reproduce audio data received via the interface and selected by one of the input source buttons.

Personal electronic devices are provided in the form of personal audio equipment. Devices of the present disclosure include readily-moldable ear inserts that are selectively formed to fit the shape of a user's ear and do not require heating, curing, setting, or other temperature manipulation. In some embodiments, the devices comprise wireless audio technology and wireless conductive charging.

An in-ear headphone includes a shell, a speaker, a circuit board, and a sensing structure. The shell has an accommodating space. The speaker is disposed in the accommodating space. The circuit board is disposed in the accommodating space, and the circuit board is electrically connected to the speaker. A sensing chip is disposed on the circuit board. The sensing structure includes a sensing member and a transmission member. The sensing member protrudes from a front end of the shell and has a conductor. The sensing member is electrically connected to the sensing chip by the transmission member. A material of the sensing member is different from a material of the shell.