A mount for a peripheral device including a first plate having an opening; a second plate coupled to the first plate via a first hinged joint so as to be pivotable between a closed configuration and an open configuration; and a levelling plate disposed in the opening and coupled to the first plate via a second hinged joint so as to be pivotable between a flushed configuration and an angled-off configuration. The first hinged joint and the second hinged joint being parallel and at opposite portions of the first plate. A free end of the second plate in the closed configuration and a free end of the levelling plate in the flushed configuration are directed in opposite directions along the first plate. The levelling plate includes a socket structure to receive an attachment assembly for attaching the peripheral device to the levelling plate. The first plate includes a lip portion.

Provided are an imaging apparatus, an imaging method, and a program capable of accurately and simply controlling a movement sensitivity of an index displayed on a finder monitor to a sensitivity desired by a user by using a touch panel installed on a rear monitor. The imaging apparatus (10) has a finder that includes the finder monitor (13), the touch panel (31) that receives a swipe operation for moving the index, and an image processing unit (24). The image processing unit (24) includes a sensitivity setting unit that sets a first sensitivity for coarsely moving the index by the swipe operation or a second sensitivity for finely moving the index by detecting a contact operation to the touch panel in the swipe operation, and a movement control unit that moves the index on the basis of the swipe operation on the touch panel and the sensitivity set by the sensitivity setting unit.

Virtual entities are displayed alongside real world entities in a wearable reality overlay device worn by the user. Information related to an environment proximate to the wearable device is determined. For example, a position of the wearable device may be determined, a camera may capture an image of the environment, etc. Virtual entity image information representative of an entity desired to be virtually displayed is processed based on the determined information. An image of the entity is generated based on the processed image information as a non-transparent region of a lens of the wearable device, enabling the entity to appear to be present in the environment to the user. The image of the entity may conceal a real world entity that would otherwise be visible to the user through the wearable device. Other real world entities may be visible to the user through the wearable device.

The present disclosure relates to an imaging apparatus, an information processing method, a program, and an interchangeable lens that enable depth-of-field adjustment.

The imaging apparatus includes a depth-of-field adjustment function that adjusts the depth of field of at least one monocular optical system among a plurality of monocular optical systems having optical paths independent of one another. For example, the depth-of-field adjustment function includes a mechanism that adjusts the depths of field of the monocular optical systems, and an optical system control unit that adjusts the depths of field of the monocular optical systems by driving the monocular optical systems on the basis of control information. The present disclosure can be applied to an imaging apparatus, an electronic apparatus, an interchangeable lens or a camera system that provides a plurality of monocular lenses, an information processing method, a program, or the like, for example.

An image capture device may include one or more optical elements. One or more lens covers may be used to cover the optical element(s). Usage of the lens cover(s) with respect to the optical element(s) may be determined. The operation of the image capture device may be changed based on whether the lens cover(s) are on or off the optical element(s).

[Object] To provide a control device which enables a flight vehicle device to obtain a highly precise image. [Solution] Provided is the control device including an illuminating control unit configured to adjust a light amount of an illuminating device according to an inclination of a body of a flight vehicle device that has an imaging device configured to photograph a photographing target and the illuminating device configured to illuminate the photographing target.

[Object] To provide a control device which enables a flight vehicle device to obtain a highly precise image. [Solution] Provided is the control device including an illuminating control unit configured to adjust a light amount of an illuminating device according to an inclination of a body of a flight vehicle device that has an imaging device configured to photograph a photographing target and the illuminating device configured to illuminate the photographing target.

Systems and methods are disclosed for lens water dispersion. For example, an image capture device may include a lens mounted on a body of the image capture device; an image sensor mounted within the body, behind the lens and configured to capture images based on light incident on the image sensor through the lens; and a dispersion structure around a perimeter of the lens on an external surface of the body, wherein the dispersion structure includes gaps sized to cause capillary action to move water away from the lens, from a first edge of the dispersion structure to a second edge of the dispersion structure.

The present disclosure generally relates to an electronic device accessory and a method of using such electrical device accessory to convert a built-in camera or webcam of the electronic device into an adjustable camera using the mirror reflection, allowing the built-in camera or webcam to operate, for example, as a document camera. The electronic device accessory comprises at least a foldable main body and a mirror adapted to attach to the main body. The electronic device accessory is configured to clip onto the electronic device. The electronic device includes a desktop computer, a laptop computer, a mobile phone, a tablet, an e-reader or any other electronic device that has a built-in camera. More particularly, the electronic device accessory is preferably a foldable laptop computer camera accessory.

A remote monitoring device and a remote monitoring method thereof are provided. An energy harvesting device converts energy harvested from the surrounding environment into electrical energy for storage. An image capturing device captures an image of a monitored object to generate a captured image. When the power stored in the energy harvesting device meets a preset condition, a control circuit outputs monitoring information based on the captured image.