The present disclosure embodiment may disclose glasses. The glasses may include a glasses frame and two speakers. The glasses frame may include a glasses rim and two glasses temples. The two glasses temples may be rotatably connected to the glasses rim, respectively. The two speakers may include an earphone core, respectively. The two speakers may be connected to the two glasses temples via hinge components of the two glasses temples, respectively. The hinge components may be rotatable to change a position of each of the speakers relative to connected one of the glasses temples to make the speaker abut in front of or behind ears of a user. The glasses temple may include a control circuit or a battery to drive the earphone core to vibrate to generate a sound.

A loudspeaker cabinet-attached folding screen structure includes: a folding screen, which includes a plurality of panels that are arranged in a parallel manner; and a loudspeaker cabinet, which is arranged between the plurality of panels. The plurality of panels are rotatably connected to the loudspeaker cabinet. The loudspeaker cabinet includes a loudspeaker, a driver circuit, and a first wireless transmission circuit that is electrically connected with the loudspeaker and the first wireless transmission circuit. As such, the user may simply adjust the folding screen to make the sound waves emitting from the loudspeaker cabinet impinging the plurality of panels to develop reflection, and the reflection of the sound waves by the plurality of panels induces delay to make the user hear clearer. Repetitive reflection of the sound waves by the plurality of panels induce reverberation, which makes the sound exhibiting a sense of distance and a sense of space.

An assembly may include a speaker supportable for movement relative to a reference external to the speaker and a speaker housing supporting speaker components operable to produce an audio output. A sensor is operable to sense a direction of movement of the speaker during movement of the speaker relative to the reference. Control components are operable to control the speaker components based on the direction of movement of the speaker relative to the reference. When the speaker is sensed to be moving in a first direction relative to the reference, an operational characteristic of the speaker components is controlled to increase or advance during movement in the first direction. When the speaker is sensed to be moving in a second direction relative to the reference different from the first direction, the operational characteristic of the speaker components is controlled to decrease or retreat during movement in the second direction.

Examples disclosed herein relate to a heat and sound deflector. An example device includes a housing having a top side; an audio system disposed in the housing to emit sound toward the top side of the housing; a heat dissipation system disposed in the housing to dissipate heat toward the top side of the housing. In examples, a deflector disposed on the top side of the housing is to deflect the sound and the dissipated heat.

A speaker device according to an embodiment includes a panel, a plurality of vibration elements, and a driving unit. The plurality of vibration elements vibrate the panel. The driving unit applies, to a first vibration element, a first driving signal that includes a modulated wave provided in such a manner that a carrier wave in an ultrasonic wave band is modulated by a sound signal in an audible wave band and applies, to a second vibration element, a second driving signal that includes the carrier wave and is different from the first driving signal, so that a vibrational region is formed on the panel.

The field of the invention relates to speaker devices, to speaker panels for speaker devices, to mechanical assemblies and mountings for speaker devices, to uses of speaker devices for example as products or as components for products, and to computer program products operable to control speaker devices. There is provided a speaker device, the speaker device including a body and a speaker panel assembly, the speaker panel assembly movable between an open configuration and a closed configuration, wherein in the open configuration the speaker panel assembly is displaced relative to the body, and in the closed configuration the speaker panel assembly is retracted into the body. The speaker device may be a smart device. The speaker device may be one configured to receive and to store a mobile device.

The present invention relates to a sensor arrangement, to a corresponding method of assembling such a sensor arrangement, and to a sensor system. The sensor arrangement comprises at least one transducer element for monitoring at least one measurand and generating an electrical output signal correlated with the at least one measurand; and a sensor substrate comprising the transducer element. The sensor substrate is mountable on a circuit carrier in a way that a media channel penetrating the circuit carrier allows access of the at least one measurand to the transducer element. The circuit carrier has an electrically conductive solderable first sealing pattern which surrounds the media channel at least partly and which is aligned with a solderable second sealing pattern arranged on the sensor substrate, so that a soldered sealing connection, which at least partly surrounds the media channel, is formed between the first sealing pattern and the second sealing pattern.

The present disclosure relates to a loudspeaker. The loudspeaker may include a loudspeaker mechanism, a fixing mechanism, and a connector. The loudspeaker mechanism may be configured to generate a vibration signal and transmit the vibration signal to the human body. The fixing mechanism may be configured to support and maintain the position of the loudspeaker mechanism. The connector may be configured to connect the loudspeaker mechanism with the fixing mechanism. The loudspeaker mechanism may at least include a first fixed position and a second fixed position. The first fixed position may be a fixed position of the loudspeaker when the loudspeaker is in a non-working state. The second fixed position may be a fixed position of the loudspeaker when the loudspeaker is in a working state. The connector may be configured to switch the loudspeaker mechanism between the first fixed position and the second fixed position.

One embodiment provides a microphone device with advanced functionalities. The microphone device comprises one or more microphone units, one or more sensor units, and an automatic control system. The one or more sensor units are configured for capturing contextual information indicative of one or more real-time conditions of an environment of the microphone device. The automatic control system is configured for detecting one or more real-time changes to the environment of the microphone device based on the contextual information, invoking display of a graphical user interface (GUI) comprising information indicative of the one or more real-time changes, and adjusting one or more settings for the microphone device in response to the one or more real-time changes.

A headset accessory comprises circuitry and is configured to mechanically attach to an audio headset. The circuitry of the headset may be operable to establish a link to the audio headset that supports conveyance of bias voltage, bias current, and/or information between the circuitry of the accessory and circuitry of the audio headset. The headset accessory may be configured to attach to a housing of the headset on a surface of the housing opposite an ear cup. A state of the circuitry of the accessory may be controlled based on the information received from the audio headset via the link. The information may include characteristics of audio being processed by the audio headset. The circuitry of the headset accessory may comprise non-volatile memory, and the non-volatile memory may store parameter settings for configuring audio processing circuitry of the audio headset.