An illuminator including a plurality of light emitting elements and a lens having a concave cylindrical first optical surface and a second optical surface, such that a thickness between the first and second optical surfaces is non-uniform along first and second orthogonal directions.

Digital camera comprising an upright Wide camera configured to provide a Wide image with a Wide image resolution and a folded Tele camera configured to provide a Tele image with a Tele image resolution higher than the Wide image resolution, the Wide and Tele cameras having respective Wide and Tele fields of view FOV.sub.W and FOV.sub.T and respective Wide and Tele image sensors, the digital camera further comprising a rotating OPFE operative to provide a folded optical path between an object or scene and the Tele image sensor, wherein rotation of the OPFE moves FOV.sub.T relative to FOV.sub.W. In some embodiments, a rectangular FOV.sub.T is orthogonal to a rectangular FOV.sub.W. When included in a host device having a user interface that displays FOV.sub.T within FOV.sub.W, the user interface may be used to position FOV.sub.T relative to FOV.sub.W, scan FOV.sub.T across FOV.sub.W and acquire, store and display separate Wide and Tele images, composite Wide plus Tele images and stitched Tele images. The positioning of FOV.sub.T within FOV.sub.W, can be done automatically (autonomously) by continuously tracking an object of interest.

Digital camera comprising an upright Wide camera configured to provide a Wide image with a Wide image resolution and a folded Tele camera configured to provide a Tele image with a Tele image resolution higher than the Wide image resolution, the Wide and Tele cameras having respective Wide and Tele fields of view FOV.sub.W and FOV.sub.T and respective Wide and Tele image sensors, the digital camera further comprising a rotating OPFE operative to provide a folded optical path between an object or scene and the Tele image sensor, wherein rotation of the OPFE moves FOV.sub.T relative to FOV.sub.W. In some embodiments, a rectangular FOV.sub.T is orthogonal to a rectangular FOV.sub.W. When included in a host device having a user interface that displays FOV.sub.T within FOV.sub.W, the user interface may be used to position FOV.sub.T relative to FOV.sub.W, scan FOV.sub.T across FOV.sub.W and acquire, store and display separate Wide and Tele images, composite Wide plus Tele images and stitched Tele images. The positioning of FOV.sub.T within FOV.sub.W, can be done automatically (autonomously) by continuously tracking an object of interest.

An imaging system positioned relative to a three-dimensional area for capturing an image includes an image sensor having an X-Y plane and an aspect ratio defined by the quantity of pixels in the X-Y plane; and a non-linear light focusing element constructed with a profile to form an altered view of a three-dimensional desired zone of the area with a desired pixel distribution. The non-linear light focusing element redirects the pixels of the image sensor from an undesired zone of the area to within a frame that encompasses the three-dimensional desired zone of the area to form the altered view of the desired zone. The image sensor captures the altered view of the desired zone to match the aspect ratio of the image sensor.

A rear view device for a motor vehicle includes a base assembly for arrangement on the motor vehicle, a head assembly attached to the base assembly and configured to move with respect to the base assembly, a camera and a camera cradle which is configured to be secured to the base assembly or the head assembly for securing the camera to the base assembly or the head assembly, the camera cradle being removably secured to the base assembly or the head assembly by a friction fit and without any separable attachment element.

The present invention relates to a camera and a terminal comprising same. A camera and a terminal comprising same according to an embodiment of the present invention comprise: a lens device including a micromirror array; and a processor for outputting, to the micromirror array in the lens device, a curvature control signal for curvature change, wherein the micromirror array includes a plurality of micromirrors including a first micromirror and a second micromirror, and the second micromirror is closer to the outer periphery thereof than the first micromirror and has a larger tilting angle according to the control signal than the first micromirror. Accordingly, focus can be changed using the micromirror array.

An optical arrangement includes a stack structure comprising at least three prisms. The optical arrangement includes a main optical path and for each of the prisms, a secondary optical path. The optical arrangement also includes at least one interface. Each of the at least one interface is arranged between a corresponding first stack section of the stack structure and a corresponding second stack section of the stack structure. Each of the at least one interface is configured to enable relative movement of the corresponding first stack section and of the corresponding second stack section with respect to one another.

An optical arrangement includes a stack structure comprising at least three prisms. The optical arrangement includes a main optical path and for each of the prisms, a secondary optical path. The optical arrangement also includes at least one interface. Each of the at least one interface is arranged between a corresponding first stack section of the stack structure and a corresponding second stack section of the stack structure. Each of the at least one interface is configured to enable relative movement of the corresponding first stack section and of the corresponding second stack section with respect to one another.

Digital camera comprising an upright Wide camera configured to provide a Wide image with a Wide image resolution and a folded Tele camera configured to provide a Tele image with a Tele image resolution higher than the Wide image resolution, the Wide and Tele cameras having respective Wide and Tele fields of view FOV.sub.W and FOV.sub.T and respective Wide and Tele image sensors, the digital camera further comprising a rotating OPFE operative to provide a folded optical path between an object or scene and the Tele image sensor, wherein rotation of the OPFE moves FOV.sub.T relative to FOV.sub.W. In some embodiments, a rectangular FOV.sub.T is orthogonal to a rectangular FOV.sub.W. When included in a host device having a user interface that displays FOV.sub.T within FOV.sub.W, the user interface may be used to position FOV.sub.T relative to FOV.sub.W, scan FOV.sub.T across FOV.sub.W and acquire, store and display separate Wide and Tele images, composite Wide plus Tele images and stitched Tele images. The positioning of FOV.sub.T within FOV.sub.W, can be done automatically (autonomously) by continuously tracking an object of interest.

Digital camera comprising an upright Wide camera configured to provide a Wide image with a Wide image resolution and a folded Tele camera configured to provide a Tele image with a Tele image resolution higher than the Wide image resolution, the Wide and Tele cameras having respective Wide and Tele fields of view FOV.sub.W and FOV.sub.T and respective Wide and Tele image sensors, the digital camera further comprising a rotating OPFE operative to provide a folded optical path between an object or scene and the Tele image sensor, wherein rotation of the OPFE moves FOV.sub.T relative to FOV.sub.W. In some embodiments, a rectangular FOV.sub.T is orthogonal to a rectangular FOV.sub.W. When included in a host device having a user interface that displays FOV.sub.T within FOV.sub.W, the user interface may be used to position FOV.sub.T relative to FOV.sub.W, scan FOV.sub.T across FOV.sub.W and acquire, store and display separate Wide and Tele images, composite Wide plus Tele images and stitched Tele images. The positioning of FOV.sub.T within FOV.sub.W, can be done automatically (autonomously) by continuously tracking an object of interest.