Electronic apparatuses with suppressed deterioration image quality and reduced bezel width are disclosed. In one example, an electronic apparatus includes a display unit, imaging optical systems, and an image acquisition unit. The display unit has a displayable region that includes display optical systems disposed in an array in a first direction and a second direction intersecting the first direction. The imaging optical systems are disposed on a side opposite to a display surface of the display unit and overlapped with the displayable region in a third direction intersecting the first direction and the second direction, and include first and second imaging optical systems with different coordinates in at least one of the first direction and the second direction. The image acquisition unit acquires image data on the basis of information acquired by the first imaging optical system and the second imaging optical system.

An electronic device is disclosed. The electronic device may include an enclosure and a transparent cover. The electronic device may include a display assembly. The electronic device may further include an inductive charging unit designed to inductively charge a stylus, or other object suitable for use with the display assembly. The electronic device may further include audio modules, at least some of which are designed to cause resonation of the enclosure to produce acoustical energy in the form of audible sound. Some audio modules produce acoustical energy in relatively low frequencies, while other audio modules produce acoustical energy in relatively high frequencies. The electronic device may further include a vision system designed for facial recognition. The display assembly may include a metal chassis as well as antennae for wireless communication. In order to prevent antennae interference, the metal chassis can be electrically grounded to the enclosure.

A sleeve or case for a mobile device, such as a smartphone or tablet or other types of hand-held device or mobile smart device, has a sleeve part for at least partially enclosing the mobile device and an input device arranged in the sleeve part for controlling the mobile device which can be received in the sleeve part. The input device includes a movable control element and a magnetorheological brake. Any movement of the control element can be selectively damped by way of the magnetorheological brake.

Example implementations relate to motion based power states. For instance, in an example an electronic device includes input components, a motion detector separate from the input components, the motion detector to detect over a period of time an amount of motion of an object proximate to the electronic device, and a controller to compare the detected amount of motion of the object to a motion threshold, and alter a power state of an input component of the input components based on the comparison.

Provided are a display device. The display device comprises a display panel displaying an image, a main circuit board disposed under the display panel, a first vibration element attached to a lower surface of the display panel and providing first vibration in accordance with a first vibration signal, a second vibration element disposed on the main circuit board and providing second vibration in accordance with a second vibration signal, and a first vibration driver circuit providing the first vibration signal to the first vibration element, wherein a phase of the second vibration signal is opposite to a phase of the first vibration signal.

A system for generating processed audio signals may include an earphone comprising a microphone configured to capture sounds from an environment of the earphone, a first communication component, and a first processor; and an earphone case comprising an earphone compartment configured to receive the earphone, a second communication component, and a second processor. The first processor may be programmed to receive a captured audio signal representative of the sounds captured by the microphone; and transmit the captured audio signal via the first communication component. The second processor may be programmed to receive the captured audio signal via the second communication component; generate a processed audio signal based on analysis of the captured audio signal; and transmit the processed audio signal via the second communication component to the first communication component.

An electronic device includes a substrate, a circuit layer disposed on the substrate and including a plurality of insulating layers, a plurality of conductive layers, and at least one semiconductor layer, a light emitting element layer disposed on the circuit layer and including a light emitting element, an encapsulation layer disposed on the light emitting element layer, and a sensor layer disposed on the encapsulation layer and including a plurality of sensor conductive layers. A first layer of the conductive layers, the at least one semiconductor layer, and the sensor conductive layers includes a first sensor, a second layer different from the first layer of the conductive layers, the at least one semiconductor layer, and the sensor conductive layers includes a second sensor, and the first sensor and the second sensor overlap a second area.

An example electronic device according to various embodiments may include a fingerprint sensor, a touch sensor, a memory storing at least one instruction, and a processor operatively connected to the fingerprint sensor, the touch sensor, and the memory. The processor may determine whether a touch input is generated in a fingerprint recognition area in which a fingerprint sensor is disposed using a touch sensor, may determine whether the generated touch input continues for a given time or more, may generate first data by accumulating the touch input generated based on the touch input continuing for the given time or more, may determine whether an inputted fingerprint corresponds to a registered fingerprint of a registered user by analyzing the touch input in the fingerprint recognition area, using the fingerprint sensor, may analyze the first data using a first AI model based on the inputted fingerprint corresponding to the fingerprint of a registered user, may analyze the first data using a second AI model based on the inputted fingerprint not corresponding to the fingerprint of a registered user, may identify a form of the touch input based on analysis of the first data, and may perform a function corresponding to the identified form of the touch input and/or executing a user interface corresponding to the identified form of the touch input.

In some aspects, mobile devices with foldable and rollable displays can use a sensor to detect vertical acceleration with respect to the ground to determine if the mobile device has been dropped. If the sensor detects that the mobile device has been dropped the foldable device can fold or retract at least partially to afford protection from the fragile display from striking the ground. Even folding the display to an angle less the 180 degrees can afford some protection because the mobile device can strike edges of the mobile device instead of the display itself. In various embodiments, a rollable device can retract the display if predetermined acceleration limits are exceeded.

Improvement of quality and improvement of a design property is achieved. A display (2) that displays an image on a display surface (2a), a back chassis (3) disposed on a side, of the display (2), opposite to the display surface (2a), a sealing body (5) disposed between the display (2) and the back chassis (3), and an outer frame (6) that is provided as a resin portion (13) at least partly including a resin material, and covers the display (2) and the back chassis (3) from an outer periphery side are included. An inner peripheral surface of the resin portion (13) is brought into close contact with an outer peripheral surface of the display (2) and an outer peripheral surface of the back chassis (3).