Provided are a directional acoustic sensor that detects a direction of sound, a method of detecting a direction of sound, and an electronic device including the directional acoustic sensor. The directional acoustic sensor includes a sound inlet through which a sound is received, a sound outlet through which the sound received through the sound inlet is output, and a plurality of vibration bodies arranged between the sound inlet and the sound outlet, in which one or more of the plurality of vibration bodies selectively react to the sound received by the sound inlet according to a direction of the received sound.

Disclosed is a wireless audio device, which includes at least one microphone, at least one speaker, at least one sensor, a processor, and a memory storing instructions, and the instructions that, when executed by the processor, cause the wireless audio device, while the wireless audio device outputs a sound for reducing an outside sound acquired through the at least one microphone through the at least one speaker, to identify a specified outside sound of the outside sound acquired through the at least one microphone, to output a notification sound for indicating that the specified outside sound is identified through the at least one speaker, to identify a motion of a user of the wireless audio device through the at least one sensor, in response to outputting the notification sound, and to stop the output of the sound for reducing the outside sound based on the identified motion.

Systems and methods are disclosed that provide directional speakers and haptic devices for each guest of a ride vehicle. A controller may receive a vehicle location, seat location data, input audio data, and input haptic data. The seat location data may include a guest's seat location in the ride vehicle and/or the guest's preferences (e.g., a preferred language, volume preferences, or content rating preference). The controller may generate different audio output signals corresponding to different guests based on the input audio data, the vehicle location, and/or the seat location data, and generate different haptic output signals corresponding to different guests based on the input haptic data, the vehicle location, and/or the seat location data. The controller may then instruct directional speaker directed at the seat locations of the different guests to output the different audio output signals and instruct haptic devices directed at the seat locations to output the different haptic output signals.

Embodiments for a speaker system that produces a near-field sound pattern for rendering immersive audio content in a portable device. An array of drivers projects sound upwards from a top surface of the portable device to form upward-firing speakers; a set of speakers projects sound downwards from a bottom surface of the portable device to form downward-firing speakers. A decoder/renderer component receives immersive audio content, decodes height audio signals from the content and sends direct audio signals to the downward-firing speakers. A crossover performs a high-pass filter function to pass high frequency components of the decoded height audio signals to the upward-firing speakers and low frequency components of the decoded height audio signals to the downward-firing speakers.

A vehicular apparatus having at least one of a voice calling function and a voice recognition function, the apparatus comprising a voice input unit including a plurality of microphones, the voice input unit being disposed between a driver's seat and a passenger seat with respect to a vehicle width direction; and a control unit configured to control a directionality direction and a gain level of each of the plurality of microphones, wherein the control unit controls the directionality directions of the plurality of microphones in two directions, the two directions being a driver's seat side and a passenger seat side, and controls a gain level on the passenger seat side to be lower than a gain level on the driver's seat side.

Various implementations include seats and related loudspeakers. In particular cases, a seat includes: a seat headrest portion; a seat backrest portion; and a loudspeaker assembly. The loudspeaker assembly includes at least one driver for generating an acoustic output; and an acoustic exit fixed in the seat backrest portion and angled to provide the acoustic output to a location below a nominal ear position of an occupant of the seat, wherein a firing angle of the at least one driver provides the acoustic output to achieve a consistent frequency response across a range of positions deviating from the nominal ear position.

An electronic device according to various embodiments may include: a housing, an acoustic hole formed in a first direction of the housing, an instrument installed in the housing in a second direction perpendicular to the first direction, a mic, and a mic holder including a body installed in the housing, a seat formed in the body part to receive the mic, a first opening formed in one surface of the body and connected to the seat, a second opening formed in another surface of the body, and a third opening formed in the body and connected to the acoustic hole. As the second opening of the mic holder is closed by an instrument of the electronic device closely attached to the other surface of the body part, an acoustic channel in which a sound introduced into the third opening is delivered to a mic hole of the mic may be formed.

A skin audible watch for orientation identification includes a dial (1) and a strap (2). A plurality of sound collection modules (3) are arranged along a circumference of the dial (1), and the sound collection modules (3) are sequentially connected with a digital filter (4), an analog-to-digital converter (5), a single-chip microcomputer (6), and a row and column drive module (7); the single-chip microcomputer (6) is also connected with vibration motors (8) and a gyroscope (9); a number of the vibration motors corresponds to a number of orientations; the digital filter (4), analog-to-digital converter, single-chip microcomputer, row and column drive module, the vibration motors and the gyroscope are located inside the dial; the row and column drive module is connected with a current contact pin (12), and a free end of the current contact pin extends out of a surface of the vibration motors.

The present invention contributes to reducing the burden on a user while preventing speeches translated into a plurality of languages from interfering with each other. A translation system comprises a camera that obtains surroundings information; a directional speaker that is movable so as to output sound toward a specified position; a directional microphone that is movable so as to receive sound from a specified position; and a translation apparatus that determines a location of a user from the surroundings information obtained by the camera, moves the directional speaker and the directional microphone toward the location of the user, identifies the language of a speech received by the directional microphone, translates the language into another language to output the translated language from another directional speaker, and retranslates the translation in the another language into the language to output the retranslated language from the directional speaker.

An electronic device according to various embodiments of the disclosure includes: a first housing; a second housing configured to be unfolded by a specified angle with respect to the first housing and to rotate about a folding axis; at least one hinge structure including a hinge providing the folding axis and disposed between the first housing and the second housing to rotatably connect the first housing and the second housing; a hinge cover accommodating at least a portion of the hinge structure therein and selectively exposed based on the rotation of the second housing; a first speaker module including a speaker accommodated in the first housing; and a second speaker module including a speaker accommodated in the second housing, wherein in the first state, the first speaker module is configured to discharge sound to the outside of the electronic device via a first area provided in the first housing, a second area provided in the hinge structure and contact with the first area, and a first through-hole extending through the hinge cover, is exposed to the outside in the first state, and is configured to be selectively closed based on the rotation of the second housing.