A method for determining a transportation mode acquires magnetometer and speed data from a mobile device, correlates the magnetometer to the speed data in groupings, and performs spectral analysis on the groups of magnetometer data. Energy calculated for each of a set of frequency components obtained from the spectral analysis is compared to a baseline value to generate a difference, and a transportation mode type is assigned to the vehicle based on the difference.

A projection module and a terminal are provided. The projection module includes a base, a housing, a first light source, a second light source and an optical element. The housing is disposed on the base, and defines an accommodating cavity together with the base. The first light source is disposed on the base and arranged in the accommodating cavity. The second light source is disposed on the base and arranged in the accommodating cavity. The optical element is disposed on the housing and includes a diffraction area and a diffusion area. The first light source aligns with the diffraction area, the second light source aligns with the diffusion area, the diffraction area is configured to diffract light passing through the diffraction area, and the diffusion area is configured to diffuse light passing through the diffusion area.

This document describes techniques and systems for radar-based gesture-recognition with context-sensitive gating and other context-sensitive controls. Sensor data from a proximity sensor and/or a movement sensor produces a context of a user equipment. The techniques and systems enable the user equipment to recognize contexts when a radar system can be unreliable and should not be used for gesture-recognition, enabling the user equipment to automatically disable or “gate” the output from the radar system according to context. The user equipment prevents the radar system from transitioning to a high-power state to perform gesture-recognition in contexts where radar data detected by the radar system is likely due to unintentional input. By so doing, the techniques conserve power, improve accuracy, or reduce latency relative to many common techniques and systems for radar-based gesture-recognition.

An electronic device according to various embodiments of the disclosure includes a front plate configured to form at least a part of a front surface of the electronic device, a speaker disposed in the electronic device, a barometric pressure sensor disposed in the electronic device to measure barometric pressure, a housing configured to form a side surface of the electronic device, and a first slit provided as a gap having a first interval between the housing and an edge portion of the front plate, wherein the housing includes a sound output hole provided at a position at which the speaker is disposed, and a through-hole provided at a position at which the barometric pressure sensor is disposed, and the housing is spaced apart from the front plate to provide a duct configured to connect the through-hole and a sound output passage which is a space for connecting the first slit and the sound output hole. In addition, various other embodiments identified through the specification are possible.

A wearable device that communicates with a host device can be used to initiate a communication functionality of the host device (e.g., telephone calls, text messages). The wearable device can obtain user input indicating a recipient of the communication and in some instances content for the communication and can provide an instruction to the host device. The host device can use the indicated recipient and content to initiate communication and where applicable to send the content. Recipients and/or content can be selected from predefined lists available on the wearable device.

Embodiments of the disclosure provided herein generally include a system and a method of configuring and/or controlling the transfer of information between two or more electronic devices due to the interaction of an electronic device and a host identifier signal generating system. Embodiments of the disclosure may include a system and a method of distributing useful information received by or contained within a memory of the electronic device based on the receipt of a host identifier signal. The electronic device may then perform one or more desirable functions or processes based the portable electronic device's interaction with the host identifier signal generating system. Some aspects of the invention may include an apparatus, method and/or one or more computing device software applications that are configured to more easily setup, configure and/or control the presentation, distribution, collection and/or analysis of program information residing in a first electronic device to a second electronic device based on the interaction of the first electronic device with the host identifier signal generating system.

A display screen and an electronic equipment are provided. The display screen comprises a middle frame, a display panel and an optical fingerprint sensor. The display panel is superimposed on the upper surface of the middle frame, and the through-hole provided on the middle frame and extending through the upper and lower surfaces of the middle frame is filled with a transparent body, the optical fingerprint sensor is disposed beneath the transparent body.

An electronic device is provided. The electronic device includes a housing comprising a front plate facing a first direction, a rear plate facing a second direction opposite to the first direction, and a side member configured to enclose a space between the front plate and the rear plate, a display panel having a first surface viewed through the front plate, a cover panel coupled to a second surface of the display panel and positioned at an inner area of the display panel, the cover panel comprising a hole formed adjacent to a first edge of the display panel, and a sensor comprising a light receiving portion positioned to correspond to a position of the hole of the cover panel, and a light emitting portion positioned at an outer area of the display panel.

A finger wiping device having a base portion and a wiping portion, the wiping portion extending over at least a portion of the base portion and configured with a plurality of flexible wiping elements extending from a top face of the base portion, the wiping elements disposed in close proximity to one another and disposed along at least a finger wiping path.

An electronic device according to various embodiments of the present invention may comprise: a housing including a hole formed therethrough; an earphone jack built in the housing such that an earphone plug is received therein through the hole; a gas sensor integrally formed with the earphone jack; a memory positioned inside the housing; and a processor positioned inside the housing and electrically connected with the earphone jack, the gas sensor, and the memory, wherein the memory stores instructions by which, when executed, the processor: controls the gas sensor to obtain data related to a specific component of the outside air; and causes the gas sensor to calculate a cleanliness level of the outside air on the basis of at least one of data obtained before a predetermined measurement disturbance element is generated and data obtained after the measurement disturbance element is removed. Other various embodiments are also possible.