Abstract: The present disclosure relates to titanium or titanium alloy (e.g., titanium/copper alloy) mobile phone chassis, and methods for making and using same.

Abstract: Various embodiments concern techniques for intelligently switching between multiple sources of USB signals. More specifically, user devices are described that include a physical USB port for receiving a USB connector and one or more wireless transceivers that communicate with an accessory. The wireless transceiver(s) may communicate with the accessory using a USB-based protocol (e.g., Wireless USB). The user devices described herein can intelligently switch between these different sources of USB signals so that USB signals can be simultaneously or sequentially received from a peripheral (via the USB port) and an accessory (via the wireless transceiver(s)). In some embodiments, a switching routine is executed (e.g., by a processor or signal switch) that determines which peripheral and/or accessory is connected to a user device at a given point in time.

Abstract: Techniques are described for mounting a display and/or display cover to a housing of a display device, such as a mobile phone. In an embodiment, the housing and display cover include chamfered edges at complementary angles to allow for an “edge-to-edge” display. The display cover and housing are affixed to each other at the chamfered edges using curable liquid adhesive.

Abstract: The technology disclosed here maximizes the size of the display area associated with the mobile device by various camera placement. In one embodiment, the camera is placed inside the mobile device, and can pop outside the mobile device when the camera is activated. When the camera is inactive the camera retracts inside the mobile device, and becomes unnoticeable to the user. In another embodiment, the camera is integrated into the mobile device display as a camera icon. The integrated camera serves two purposes: to record pictures, and to act as a camera icon, that when selected activates the camera. By removing the camera from the front side of the mobile device, or by integrating the camera into the display screen of the mobile device, the size of the mobile device display screen can be increased.

Abstract: The technology disclosed here maximizes the size of the display area associated with the mobile device by various camera placement. In one embodiment, the camera is placed inside the mobile device, and can pop outside the mobile device when the camera is activated. When the camera is inactive the camera retracts inside the mobile device, and becomes unnoticeable to the user. In another embodiment, the camera is integrated into the mobile device display as a camera icon. The integrated camera serves two purposes: to record pictures, and to act as a camera icon, that when selected activates the camera. By removing the camera from the front side of the mobile device, or by integrating the camera into the display screen of the mobile device, the size of the mobile device display screen can be increased.

Abstract: Presented here are manufacturing techniques to create an irregularly shaped electronic display, including a hollow within which a sensor, such as a camera, can be placed. The manufacturing techniques enable the creation of the hollow anytime during the manufacturing process. The resulting electronic display occupies the full side of the mobile device, with the sensors placed within and surrounded by the display.

Abstract: Several embodiments include a mobile device. The mobile device can include a circuit board configured to interconnect one or more electronic components and a chassis shell adapted to form an outer perimeter of the mobile device and to enclose the circuit board. The chassis shell can have an integral unibody that includes a contact feature integral to the chassis shell. A sensor system can be in contact with the chassis shell on an opposite side of the contact feature. The contact feature enables the sensor system to detect touch events when a user interacts with the contact feature.

Abstract: Various embodiments concern fingerprint sensors for mobile devices. By modifying one or more layers of a display assembly, a fingerprint sensor can be positioned directly beneath the display. For example, the air gap within the backlight structure could be replaced by an optically clear adhesive that allows waves emitted by a fingerprint sensor to properly propagate through the display assembly. In some embodiments, a fingerprint sensor is set within a recess in the display assembly. For example, a depression could be created in the protective substrate, and the fingerprint sensor could be set within the depression using an optically clear adhesive. The functionality of a fingerprint sensor could also be replicated by increasing the density of touch-sensing elements in certain areas of a display assembly that utilizes in-cell technology.

Abstract: Some embodiments include a mobile device with a light sensor overlaid under a display (e.g., a touchscreen). The mobile device can identify a command to capture an image. The mobile device can adjust at least a target portion of an opaqueness adjustable region of the display directly over the light sensor. The opaqueness adjustable region is capable of transforming from substantially opaque to substantially transparent. The mobile device can capture the image utilizing at least the light sensor while the target portion of the opaqueness adjustable region is substantially transparent.

Abstract: Several embodiments include a mobile device. The mobile device can include a circuit board configured to interconnect one or more electronic components and a chassis shell adapted to form an outer perimeter of the mobile device and to enclose the circuit board. The chassis shell can have an integral unibody that includes a contact feature integral to the chassis shell. A sensor system can be in contact with the chassis shell on an opposite side of the contact feature. The contact feature enables the sensor system to detect touch events when a user interacts with the contact feature.

Abstract: Disclosed herein are various embodiments of an imaging device having a wide field of view configured to connect to another device. According to one embodiment, the wide field of view camera can include an array of cameras for recording a wide view (e.g., 360° view) of the surrounding environment and generate a 360° image of the surrounding environment. The wide field of view camera can be configured to connect and/or attach to another device, including a mobile device. Embodiments include a wired or wireless connection mechanism to facilitate communication between the wide field of view camera and another device. The connection mechanism may enable transmission of data associated with the wide field of view camera to another device. Embodiments include an attachment mechanism to fasten the wide field of view camera to another device.

Abstract: Certain aspects of the technology disclosed herein involve combining images to generate a wide view image of a surrounding environment. Images can be recorded using an stand-alone imaging device having wide angle lenses and/or normal lenses. Images from the imaging device can be combined using methods described herein. In an embodiment, a pixel correspondence between a first image and a second image can be determined, based on a corresponding overlap area associated with the first image and the second image. Corresponding pixels in the corresponding overlap area associated with the first image and the second image can be merged based on a weight assigned to each of the corresponding pixels.

Abstract: A mobile device can include a support frame adapted to support one or more electronic components of the mobile device. The mobile device includes a chassis shell adapted to form an exterior of the mobile device. The mobile device can include a tray exposed on the exterior and having at least two functional components of the mobile device attached thereon serving at least two different functions (e.g., an electronic function, an input or output function, and/or a mechanical function to support a permanent or temporary component). The chassis shell exposes one of the functional components on the exterior. The tray is capable of sliding outward to further expose the other one of the functional components.

Abstract: The technology disclosed here integrates a light sensor with a dual-mode display, thus increasing the size of the dual-mode display. The light sensor can be a camera, an ambient sensor, a proximity sensor, etc. The light sensor is placed beneath the dual-mode display and can detect incoming light while the dual-mode display is displaying a display image. The dual-mode display and the light sensor can operate at the same time. For example, a camera placed beneath the dual-mode display can record an image of the environment, while at the same time the dual-mode display is showing the display image. Further, multiple light sensors can be placed at various locations beneath the dual-mode display.

Abstract: The technology presented here reduces the number of ports associated with the mobile device by combining a plurality of ports into a single multipurpose port. In one embodiment, the multipurpose port includes multiple sensors that detect various properties associated with a light beam, and a light guide that transmits the light beam between the environment outside and the multiple sensors inside the mobile device. In another embodiment, a multipurpose camera includes one or more pixels, different from the rest of the multipurpose camera pixels, where the one or more pixels receive a unique control signal. The unique control signal, sent by a processor coupled to the multipurpose camera, includes an instruction to perform an action different from the rest of the pixels, e.g., to turn on when the rest of the pixels are off. The active pixels can detect coarse properties of the light while saving mobile device battery life.

Abstract: Some embodiments include a mobile device with a light sensor overlaid under a display (e.g., a touchscreen). The mobile device can identify a command to capture an image. The mobile device can adjust at least a target portion of an opaqueness adjustable region of the display directly over the light sensor. The opaqueness adjustable region is capable of transforming from substantially opaque to substantially transparent. The mobile device can capture the image utilizing at least the light sensor while the target portion of the opaqueness adjustable region is substantially transparent.

Abstract: Disclosed are structures, methods and systems for wireless devices that are configured to allow the transmission of light through an enhanced antenna break for a wide variety of purposes. In an illustrative embodiment, an antenna break is configured to allow the passage of both wireless communication signals and light, such as to notify the user of one or more conditions. The light transmission can be integrated with other functions of the wireless device, such as to provide a flash for operation of a camera, to provide a light source for scanning or 3D sensing, to provide light in conjunction to acoustic or vibration output, or to sense light for other integrated functions.

Abstract: Various embodiments concern fingerprint sensors for mobile devices. By modifying one or more layers of a display assembly, a fingerprint sensor can be positioned directly beneath the display. For example, the air gap within the backlight structure could be replaced by an optically clear adhesive that allows waves emitted by a fingerprint sensor to properly propagate through the display assembly. In some embodiments, a fingerprint sensor is set within a recess in the display assembly. For example, a depression could be created in the protective substrate, and the fingerprint sensor could be set within the depression using an optically clear adhesive. The functionality of a fingerprint sensor could also be replicated by increasing the density of touch-sensing elements in certain areas of a display assembly that utilizes in-cell technology.

Abstract: Certain aspects of the technology disclosed herein combine wide angle lenses with normal lenses to create an undistorted 360° view of the surrounding environment. The normal lenses record an image of the surrounding environment in the areas where the wide angle lenses provide a distorted view. The wide angle lenses and the normal lenses can be part of a stand-alone imaging device, can be accessories to a mobile device, or can be integrated into a mobile device. Various ways to integrate the wide lenses and/or the normal lenses into the camera are disclosed herein.

Abstract: A handheld device can include an encasing, one or more appurtenances associated with the encasing, communications circuitry contained within the encasing, and antenna elements. The antenna elements can be electrically coupled to the communications circuitry and integrated with the encasing and the one or more appurtenances. The appurtenances can include any of a touch-sensitive display screen, a button, a joystick, a click wheel, a scrolling wheel, a touchpad, a keypad, a keyboard, a microphone, a speaker, a camera, a sensor, a light-emitting diode, a data port, or a power port.