Devices are described herein for extending the use of mobile devices in mixed-media environments. The devices include a transparent hemisphere including a base opposite an apex of the transparent hemisphere and a substantially planar surface configured to be positioned over a circumference of the base of the transparent hemisphere and affixed thereto creating a sealed cavity within the transparent hemisphere. The substantially planar surface includes a transparent portion configured to allow light within an environment to pass through the transparent hemisphere and the transparent portion to reach a recording device.

Devices are described herein for extending the use of mobile devices in mixed-media environments. The devices include a transparent hemisphere including a base opposite an apex of the transparent hemisphere and a substantially planar surface configured to be positioned over a circumference of the base of the transparent hemisphere and affixed thereto creating a sealed cavity within the transparent hemisphere. The substantially planar surface includes a transparent portion configured to allow light within an environment to pass through the transparent hemisphere and the transparent portion to reach a recording device.

The present embodiment relates to a camera module comprising a front body, a lens, a rear body, a first substrate, an image sensor, a second substrate, a connector and a cover, wherein the cover includes a bottom plate having a hole in which the connector is to be disposed, side plates extending from the bottom plate, and pressing unit disposed at the bottom plate and elastically supporting the connector, the connector includes a first surface facing the inner surface of the bottom plate of the cover, and a second surface extending from the first surface and disposed in the hole, and the pressing unit includes a first pressing part for pressing the first surface of the connector, and a second pressing part for pressing the second surface of the connector.

Camera operations are controlled by motion patterns determined from the outputs of an internal motion sensor. These methods remove the need for a nob, button, touch screen, or other mechanical control devices with movable components. This effectively removes common water leakage weak points for electronic devices with cameras. Motion patterns determined from the outputs of an internal motion sensor are also used to adjust camera operation parameters such as the brightness of a supporting light source, shutter speed, aperture opening, and contrast. These methods are also applicable for land operations.

Camera operations are controlled by motion patterns determined from the outputs of an internal motion sensor. These methods remove the need for a nob, button, touch screen, or other mechanical control devices with movable components. This effectively removes common water leakage weak points for electronic devices with cameras. Motion patterns determined from the outputs of an internal motion sensor are also used to adjust camera operation parameters such as the brightness of a supporting light source, shutter speed, aperture opening, and contrast. These methods are also applicable for land operations.

An electronic device includes a body frame formed by mating first to third members. The first and second members each include first to third mating surfaces. The first and second mating surfaces face corresponding surfaces in a first direction and the third mating surfaces face each other in a second direction orthogonal to the first direction. The first to third members each include fourth to sixth mating surfaces. Between the first and second members and the third member, the fourth and fifth mating surfaces face corresponding surfaces in a third direction orthogonal to the first and second directions, and the sixth mating surfaces face each other in the second direction. Microstructures for a liquid repellency are provided on at least one of the first to third mating surfaces and at least one of the fourth to sixth mating surfaces.

An electronic device includes a body frame formed by mating first to third members. The first and second members each include first to third mating surfaces. The first and second mating surfaces face corresponding surfaces in a first direction and the third mating surfaces face each other in a second direction orthogonal to the first direction. The first to third members each include fourth to sixth mating surfaces. Between the first and second members and the third member, the fourth and fifth mating surfaces face corresponding surfaces in a third direction orthogonal to the first and second directions, and the sixth mating surfaces face each other in the second direction. Microstructures for a liquid repellency are provided on at least one of the first to third mating surfaces and at least one of the fourth to sixth mating surfaces.

Systems and methods for providing a distortion-free pool-surface display beneath a swimmer. In one embodiment, projectors are positioned below a water level at opposite walls of a pool, and are configured to project images to a display surface at the bottom of the pool beneath a swimmer. A camera is used to view images projected by the projectors and to provide corresponding image data to an image correction platform on a graphics processing unit (GPU). The image correction platform identifies distortions in the images, generates image corrections that counter the identified distortions, and applies the corrections to subsequently projected images. The image correction platform also generates image adjustment that cause overlapping portions of the projected images to match seamlessly. The projected images may provide immersive experiences, coaching/training interfaces or other interactive displays.

A sleeve for absorbing moisture from lenses is revealed. A sleeve body is divided into an upper space and a lower space for mounting a lens by a partition. A mounting cavity in which a moisture absorption material is disposed is in the upper space. An upper cover with a moisture detecting unit is fastened on an open end of the mounting cavity. The lower space provides a stretchable space to have a tight fit on the lens with different sizes. The moisture absorption range of the moisture absorption material extends to the periphery of the lens through air channels so that the moisture absorption material absorbs moisture from the lens through gaps of a lens end, a focus ring, and an iris ring of the lens for keeping the lens dry. The moisture detecting unit allows users to replace or treat the moisture absorption material in time.

In a method, it is determined that a detachable lens is mounted on an image capture device in a first orientation. A first image of a controlled scene is captured with the detachable lens mounted in the first orientation. It is determined that the detachable lens is mounted on the image capture device in a second orientation that is rotated approximately 180 degrees from the first orientation. A second image of the controlled scene is captured with the detachable lens in the second orientation. A first image circle center of the first image is determined. A second image circle center of the second image is determined. An average image circle center is determined, based on the first image circle center and the second image circle center. The average image circle center is provided to an image stabilization algorithm when the detachable lens is mounted on the image capture device.