An electronic device may include a noise shielding device that may include: a substrate including at least one heat generating component; a metallic shield cover that is disposed on the substrate to enclose the at least one heat generating component; a metal housing disposed around the shield cover; and a heat transfer member that is configured to transfer heat emitted from the heat generating component through an opening formed at a position corresponding to the heat generating component to the metal housing, wherein the metallic shield cover includes a plurality of tension fingers that protrude at predetermined intervals and contact a bottom face of the metal housing, and noise emitted from the heat generating component is shielded by a shielding region that is formed by the tension fingers and the metal housing.

An electronic device may include a noise shielding device that may include: a substrate including at least one heat generating component; a metallic shield cover that is disposed on the substrate to enclose the at least one heat generating component; a metal housing disposed around the shield cover; and a heat transfer member that is configured to transfer heat emitted from the heat generating component through an opening formed at a position corresponding to the heat generating component to the metal housing, wherein the metallic shield cover includes a plurality of tension fingers that protrude at predetermined intervals and contact a bottom face of the metal housing, and noise emitted from the heat generating component is shielded by a shielding region that is formed by the tension fingers and the metal housing.

At least one processor can detect a volume of a sound input to an upper microphone. The at least one processor can determine whether or not at least one of a sound emission hole for a rear speaker and a sound collection hole for the upper microphone is clogged, based on the detected volume. The at least one processor can give a notification about a result of determination.

An electronic device is provided. The electronic device includes a housing, a flexible display configured to move relative to at least a portion of the housing, and at least one noise detection circuitry disposed in the housing. The at least one noise detection circuitry may include a substrate, a microphone circuitry disposed on the substrate, a vibration detection sensor disposed on the substrate, a shielding member disposed on the substrate and surrounding at least a portion of the vibration detection sensor, and a waterproofing member disposed on the shielding member and covering the vibration detection sensor.

In an electronic device, a first sound generating module is disposed in a first accommodating cavity; and a second sound generating module is disposed in an accommodating space; when the first sound generating module is in a first operating state, the second sound generating module is in a second operating state, the first sound generating module outputs a first vibration signal to a housing, and the second sound generating module outputs a second vibration signal to the housing; or sound waves emitted by the first sound generating module form first sound waves in the first accommodating cavity, and sound waves emitted by the second sound generating module form second sound waves in the first accommodating cavity; or the first sound generating module outputs a first vibration signal to a housing, and sound waves emitted by the second sound generating module form second sound waves in the first accommodating cavity.

In an electronic device, a first sound generating module is disposed in a first accommodating cavity; and a second sound generating module is disposed in an accommodating space; when the first sound generating module is in a first operating state, the second sound generating module is in a second operating state, the first sound generating module outputs a first vibration signal to a housing, and the second sound generating module outputs a second vibration signal to the housing; or sound waves emitted by the first sound generating module form first sound waves in the first accommodating cavity, and sound waves emitted by the second sound generating module form second sound waves in the first accommodating cavity; or the first sound generating module outputs a first vibration signal to a housing, and sound waves emitted by the second sound generating module form second sound waves in the first accommodating cavity.

Headphones includes a pair of cups, each housing a speaker to be positioned over an ear of a user, a microphone, a processor, an actuator to move a member of at least one of the cups to uncover at least a portion of the ear of the user to expose the user to ambient sound, a user control to active a training mode of the headphones in which the processor operates the microphone to record relevant sounds occurring when the training mode is activated, the processor to subsequently analyze ambient sounds external to the headphones that are received by the microphone and compare those ambient sounds to the recorded relevant sounds and the processor to selectively activate the actuator to uncover at least a portion of the ear of the user to expose the user to ambient sound in response to determining that the ambient sounds match the relevant sounds.

Headphones includes a pair of cups, each housing a speaker to be positioned over an ear of a user, a microphone, a processor, an actuator to move a member of at least one of the cups to uncover at least a portion of the ear of the user to expose the user to ambient sound, a user control to active a training mode of the headphones in which the processor operates the microphone to record relevant sounds occurring when the training mode is activated, the processor to subsequently analyze ambient sounds external to the headphones that are received by the microphone and compare those ambient sounds to the recorded relevant sounds and the processor to selectively activate the actuator to uncover at least a portion of the ear of the user to expose the user to ambient sound in response to determining that the ambient sounds match the relevant sounds.

“COVERS OR COMPONENTS FOR CELL PHONES OR OTHER DIGITAL DEVICES FEATURING PHYSICAL CRYPTOGRAPHY TO FORWARD AND RECEIVE ENCRYPTED MESSAGES ON A TAMPER-PROOF BASIS”, more precisely, the present utility model addresses the use of physical cryptography for sending and receiving messages via cell phones or other digital devices (1), which allows messaging between two or more users, in a completely secure manner, without the possibility of message tampering or reading by third parties, since the decoding of the forwarded message takes place by overlaying (30) on the cell phone device or digital device (1) a key image cover (20) matching the forwarded matrix image (10).

A receiver control method includes: when a receiver of a terminal is at a first position of the terminal, picking up, by using a microphone, an audio signal sent by the receiver; and if there is a noise in the audio signal picked up by the microphone, moving the receiver to a second position of the terminal. When the receiver is at the first position, an orthographic projection of a first sound hole of the receiver along a first direction at least partially overlaps with a target component. When the receiver is at the second location, the orthographic projection of the first sound hole along the first direction does not overlap with the target component.