Optics systems presented are arranged as high-performance imagers particularly characterized by their exceptional compactness in view of image quality. A plurality of lens and let's and or doublets are configured to cooperate with related mount systems optimized for compactness. To achieve very high resolution imaging despite somewhat abbreviated compound lens design, these systems include use of lens array elements proximate to an imaging plane. So placed lens array devices may be designed with lens elements which invariably operate on incident wave planes with radial dependence. That is, the focusing strength of lenses from which these lens arrays are comprised may depend upon its distance from system optic axis. This enables an imaging correction function that counters distortion and other undesirable imaging errors typically present in a simplified compound lens systems. When used together and in conjunction with special-purpose collapsing lens mounting systems, an imaging system of very high fidelity and very compact weight size is achieved to great advantage in system when a premium on lens size is necessitated.

The present technology relates to a power controller, a power control method, and a program which appropriately supply power to an actuator for driving a shutter and an actuator for camera shake correction. A power controller includes a shutter controller for controlling a shutter driving unit, a camera shake correction controller for controlling a camera shake correction driving unit, and a power amount setting unit for setting amounts of power to be allocated to the shutter driving unit and the camera shake correction driving unit according to a set shutter speed. The power amount setting unit allocates the amount of power to be supplied to the camera shake correction driving unit when the shutter speed is equal to or less than a predetermined speed to the shutter driving unit in a case where the shutter speed is faster than a predetermined speed. The present technology available for an image pickup device.

Systems are presented with special mechanical means to switch a set of lens elements to form a compound lens from a storage position to an imaging position, In the storage mode, these arrangements offer highly efficient space saving schemes suitable for use in application where space is a premium. In the imaging mode, a plurality of lens singlets are brought together on a common imagine axis whereby they operate to form very high quality images at a single image plane. Singlet lenses are held in a lens mount device of a disk element. A plurality of similar cooperating disk elements move against adjacent coupled disks to cause well-regulated desirable motion and positioning. Specifically, portions of the disk include a cam system which permits smooth movement as disk elements are counter rotated with respect to each other thus driving the preferred positioning.

A gear-skipping prevention mechanism including a first gear, a second gear, and a positioning member is provided. The first gear is sleeved on an axle. The second gear meshes with the first gear and has a first guiding groove. The positioning member includes at least one body and at least one engaging portion. Each of the at least one body has a sleeving hole. The sleeving hole is sleeved on the axle, and each of the at least one engaging portion is slidably disposed in the first guiding groove to limit a relative position between the first gear and the second gear.

Optical center calibration may include obtaining one or more parameters for optical center calibration, obtaining an input image captured by an image capture device using a lens, and determining a calibration circle using the parameters and the input image. Determining the calibration circle may include extracting rays using the input image, estimating contours using the input image and the rays, and estimating the calibration circle using the input image and the contours. The calibration may be iteratively improved by repeating calibration based on the input image and a previous iteration of optical center calibration.

The present disclosure generally relates to user interfaces. In some examples, the electronic device transitions between user interfaces for capturing photos based on data received from a first camera and a second camera. In some examples, the electronic device provides enhanced zooming capabilities that result in visual pleasing results for a displayed digital viewfinder and for captured videos. In some examples, the electronic device provides user interfaces for transitioning a digital viewfinder between a first camera with an applied digital zoom to a second camera with no digital zoom. In some examples, the electronic device prepares to capture media at various magnification levels. In some examples, the electronic device enhanced capabilities for navigating through a plurality of values.

An interchangeable lens apparatus attachable to an imaging apparatus configured to move an image sensor in an image stabilization includes an imaging optical system, a storage unit configured to store image circle information including a relationship between an imaging condition and position information of an image circle of the imaging optical system, and a transmission unit configured to transmit at least part of the image circle information to the imaging apparatus.

The disclosure relates to a camera, comprising a housing, an electronics unit comprising a processor, and an image sensor unit comprising an image sensor and a lens support, the electronics unit being fixed inside the housing, the image sensor unit being slidable inside the housing, the housing being provided with a window through which a scene is viewable for the image sensor, the image sensor unit being slidable relative to the housing so as to allow adjustment of a distance between the image sensor and the window along an adjustment direction, wherein the electronics unit and the image sensor unit are connected to each other via a flexible cable for transmittal of digital image sensor output from the image sensor to the processor in the electronics unit.

Provided are a lens driving device, a camera module, and a camera mounting device with which miniaturization and weight reduction can be achieved. This lens driving device is provided with: a stationary part; and a movable part configured to be capable of holding a lens part and movably connected to the stationary part, wherein the stationary part has a flat plate-like base, the base has a thick part and a thin part having a smaller thickness than the thick part, and a reinforcing plate is embedded into the thin part. Specifically, the reinforcing plate is formed of a metal material and is embedded into the resin base by insert-molding.

The lens barrel includes a first frame body, a second frame body, a support frame, and a retracting lens frame. The second frame body is supported by the first frame body. The support frame is supported by the second frame body and move with respect to the second frame body within a plane. The plane being perpendicular to the optical axis. The retracting lens frame is supported by the support frame and move around a retraction shaft during a transition period between an imaging enabled state and a housed state. The retraction shaft is substantially parallel to the optical axis. The second frame body, the support frame, and the retracting lens frame move in the optical axis direction with respect to the first frame body during the transition period. The first frame body restricts the movement of the support frame within the plane during the transition period.