A removably attachable optical device includes a clamp comprising an upper clamp member and a lower clamp member. When the clamp is mounted on a mobile device, the upper member extends over a device side to enable an orifice formed by the upper clamp member to be positioned over an aperture of the mobile device. An optical element housing has a portion configured to engage the an upper clamp member. A non-uniform optical element is rotatably mounted to the optical element housing. Rotation of the non-uniform optical element causes light passing through the non-uniform optical element as the non-uniform optical element is rotated to be correspondingly altered to create optical effects.

An adaptive 3D imaging system comprising an imaging part and a lens part detachably connected thereto; the imaging part comprising a sensor and a reflector configured to transmit a plurality of captured light field images to the sensor; wherein the lens part comprising a first camera lens positioned at a first end of the lens part, a second camera lens positioned at a second end of the lens part, an entrance pupil plane and matching device positioned between the first camera lens and the second camera lens and being adaptive to different focal lengths of the second camera lens, an internal reflection unit positioned between the first camera lens and the entrance pupil plane and matching device and configured to decompose the captured light field images and refract them into a plurality of multiple secondary images with different angular offsets. Methods and uses involving the 3D imaging system are included.

An imaging device for converting a first image into a plurality of second images, the imaging device comprising a light receiving unit having a first aperture configured to receive light of the first image, a light reflecting unit configured to reflect the light received by the light receiving unit along a number of paths having a predetermined number of reflections within the light reflecting unit according to a portion of the first aperture from which the light originated, and a light output unit configured to output at least a subset of the paths of light reflected by the light reflecting unit as a plurality of second images, the second images having a focal length associated with the predetermined number of reflections experienced by the corresponding paths of light through the light reflecting unit.

A projection kaleidoscope has a shell, a light supply device, a rotating device, a film unit, a reflex cone, and a projecting convex lens. The light supply device is mounted in the shell and has a light-emitting part and a light converging unit. The rotating device is mounted in the shell and has a driver and a transmission connected to the driver. The film unit is mounted on the transmission of the rotating device and faces the light converging unit of the light supply device. The reflex cone is mounted on the transmission of the rotating device and faces the film unit and the projecting opening. The projecting convex lens is mounted in the shell and faces the reflex cone. The rotating device drives the film unit and the reflex cone to rotate in reverse to each other.

A projection kaleidoscope has a shell, a light supply device, a rotating device, a film unit, a reflex cone, and a projecting convex lens. The light supply device is mounted in the shell and has a light-emitting part and a light converging unit. The rotating device is mounted in the shell and has a driver and a transmission connected to the driver. The film unit is mounted on the transmission of the rotating device and faces the light converging unit of the light supply device. The reflex cone is mounted on the transmission of the rotating device and faces the film unit and the projecting opening. The projecting convex lens is mounted in the shell and faces the reflex cone. The rotating device drives the film unit and the reflex cone to rotate in reverse to each other.

The anti-dazzle component included in the display module includes an anti-dazzle module, a selective reflecting sheet and a first phase-difference film; the selective reflecting sheet is overlaid on a first surface of the display component, and the first phase-difference film is arranged between the anti-dazzle module and the selective reflecting sheet, the anti-dazzle module is configured to pass through a first polarized light or a second polarized light, a polarization vector of the first polarized light is located in a plane formed by an incident light and a corresponding reflected light, and a polarization vector of the second polarized light is perpendicular to the plane; and a polarization direction of a light reflected by the selective reflecting sheet is the same as that of a light passing through the first phase-difference film, and is opposite to that of a light passing through the selective reflecting sheet.

A plenoptic imaging device includes an image multiplier for obtaining a multitude of optical images of an object or scene; and a diffuser screen. The image multiplier may be a kaleidoscope. The device may include an array of optical filters for filtering the multitude of optical images.

The anti-dazzle component included in the display module includes an anti-dazzle module, a selective reflecting sheet and a first phase-difference film; the selective reflecting sheet is overlaid on a first surface of the display component, and the first phase-difference film is arranged between the anti-dazzle module and the selective reflecting sheet, the anti-dazzle module is configured to pass through a first polarized light or a second polarized light, a polarization vector of the first polarized light is located in a plane formed by an incident light and a corresponding reflected light, and a polarization vector of the second polarized light is perpendicular to the plane; and a polarization direction of a light reflected by the selective reflecting sheet is the same as that of a light passing through the first phase-difference film, and is opposite to that of a light passing through the selective reflecting sheet.

A plenoptic imaging device according to the invention comprises an image multiplier (130) for obtaining a multitude of optical images of an object or scene and a pick-up system (140) for imaging at least some of the multitude of images to a common image sensor (170) during the same exposure of the sensor.

A lens moving apparatus, according to one embodiment, comprises: a bobbin having a first coil installed on the outer circumferential surface thereof; a location detection sensor equipped to the bobbin; a housing in which the bobbin is provided; an upper elastic member disposed on the upper side of the housing; and a support member that supports the housing such that the housing can move in a second or third direction that is perpendicular to a first direction, wherein the upper elastic member is divided into a plurality of parts, at least two of which are disposed parallel to each other on the x-y plane in the second or third direction and are disposed such that end portions thereof face each other.