A wearable device includes a strap, a base connected to the strap, a display detachably connected to the base, and a camera embedded within the display. The display is configured to rotate around a perimeter of the base to adjust the orientation of the camera with respect to the base. Rotating the display allows the camera to capture one or more fields-of-view at different positions with respect to the base. In some embodiments, the display includes two or more cameras having distinct lenses. In some embodiments, the lenses of the two or more cameras are macro lenses, prime telephoto lenses, optical zoom lenses, or normal lenses. In some embodiments, the wearable device includes a second alternative display having one or more embedded second cameras. The second display is configured to detachably couple to the base after detaching the first display.

Oftentimes a site owner requires onsite capture devices (e.g., still or video cameras, microphones) for reasons of security, increasing revenue (e.g., streaming content to subscribed users), or otherwise. In the current state of the art various capture devices come from a variety of vendors and are often only adapted to work with software from the same manufacturer. It can be frustrating for a site owner to attempt to cobble together a capture and distribution system from individual parts and devices. Discussed herein is an approach to producing a capture and distribution system customized to an owner's particular needs and a site's particular characteristics in which capture devices are at least partially factory wired, aimed, and commissioned so to reduce both time on site to install of said capture devices and potential errors in the installation, and in a manner that in at least some cases adds value for the owner.

Oftentimes a site owner requires onsite capture devices (e.g., still or video cameras, microphones) for reasons of security, increasing revenue (e.g., streaming content to subscribed users), or otherwise. In the current state of the art various capture devices come from a variety of vendors and are often only adapted to work with software from the same manufacturer. It can be frustrating for a site owner to attempt to cobble together a capture and distribution system from individual parts and devices. Discussed herein is an approach to producing a capture and distribution system customized to an owner's particular needs and a site's particular characteristics in which capture devices are at least partially factory wired, aimed, and commissioned so to reduce both time on site to install of said capture devices and potential errors in the installation, and in a manner that in at least some cases adds value for the owner.

Provided are a blur detection device, an imaging device, a lens device, an imaging device main body, a blur detection method, and a blur detection program capable of appropriately detecting blurring of an imaging device. An angular velocity of a digital camera and a posture of the digital camera with respect to an Earth's rotation axis are detected. An Earth's rotation angular velocity component superimposed on a detection result of the angular velocity is calculated. The Earth's rotation angular velocity component is subtracted from the detection result of the angular velocity, and a blur amount of the digital camera is calculated based on the subtracted angular velocity.

Described herein is a mount assembly for mounting a device to a surface, including: a socket assembly; a mounting element including a mounting ball formation receivable by the socket assembly to pivotally couple the mounting element to the socket assembly, where the socket assembly includes a resilient member configured to define a socket to receive and engage the mounting ball formation, the member configured to permit the mounting ball formation to be urged into the socket against a resilient bias; the mount assembly further including a surface interface member configured to provide a frictional interface between the outer surface of the mounting ball formation and an inner wall of the socket defined by the resilient member.

It is an object to prevent erroneous operations not intended by a user and to improve operability of an operation control device.

The operation control device includes an operation detection unit that detects a first type operation and a second type operation having an operation area common to the first type operation, an operation response processing unit that performs response processing corresponding to the first type operation and the second type operation detected by the operation detection unit, and an operation determination unit that determines whether the second type operation detected by the operation detection unit is a valid operation or an invalid operation in a determination period corresponding to that the operation detection unit has detected the first type operation.

A camera module has a magnet which is held by a magnet holder included in an optical device part together with a lens holder and which is used in common as a magnet in collaboration with a first coil to move an imaging device and the lens holder relative to each other in a direction of an optical axis, a magnet in collaboration with a second coil to move the imaging device and the optical device part relative to each other in a direction orthogonal to the optical axis, and a magnet of which a magnetic force is detected by a Hall device.

A camera module has a magnet which is held by a magnet holder included in an optical device part together with a lens holder and which is used in common as a magnet in collaboration with a first coil to move an imaging device and the lens holder relative to each other in a direction of an optical axis, a magnet in collaboration with a second coil to move the imaging device and the optical device part relative to each other in a direction orthogonal to the optical axis, and a magnet of which a magnetic force is detected by a Hall device.

The present embodiment relates to a camera module and a vehicle comprising the camera module, the camera module comprising: a first exterior member comprising a lens holder; a lens module disposed in the lens holder; a second exterior member disposed at one side of the first exterior member; an electronic component part disposed inside the second exterior member; a cable electrically connected to the electronic component part; a cable accommodating part extending from the second exterior member toward the outside of the second exterior member; a closure comprising a first closure part disposed inside the cable accommodating part, and a second closure part extending from the first closure part in the extension direction of the cable accommodating part and disposed at one side of the cable accommodating part; and a cap disposed at one side of the second exterior member, and accommodating the cable accommodating part and the closure, wherein the cable passes through the second exterior member, the closure and the cap from the electronic component part and extends toward the outside of the second exterior member.

The purpose of the present invention is to reduce the number of components of an external device to reduce the cost of the external device. The electronic device according to the present technique is provided with: a battery installed unit in which a secondary battery is installed; a charging unit for charging the secondary battery on the basis of an external input power; and a connection unit for electrically connecting an external device in which a secondary battery is installed. The secondary battery installed in the external device is charged by means of the charging unit via the connection unit.