An apparatus and method for recording a scene using two lighting setups in alternation so as to concurrently record motion picture footage of the scene for each lighting setup, the footage for the two lighting setups having minimized motion offset. The apparatus includes: a plurality of light sources, a controller to define two lighting setups using the plurality of light sources, and to actuate the lighting setups in alternation, a camera to capture a sequence of frames showing the scene illuminated by one of the two lighting setups in alternation, and optionally a processing module to process the sequence of frames to generate two clips of footage of the scene, each corresponding to a lighting setup. The timing of actuation of the lighting setups relative to the frame boundaries avoids the need to use optical flow algorithms to remove motion artifacts, and the need for a specialized high speed camera.

Aspects of the disclosure relate to an emitter for active depth sensing shared by multiple apertures. An example method for active depth sensing by a device including a first aperture, a second aperture, a first emitter, and an optical element includes identifying whether the optical element is to be in a first optical element (OE) mode or a second OE mode, and controlling the optical element based on the identified OE mode. The optical element directs light from the first emitter towards the first aperture in the first OE mode. Light is directed from the first emitter towards the second aperture in the second OE mode.

Provided is a camera module. A camera module according to one aspect of the present invention comprises: a first bracket including a first hole; a second bracket which includes a first groove and which is connected to the first bracket; a first lens module arranged in the first hole of the first bracket; and a second lens module arranged in the first groove of the second bracket, wherein the second lens module is formed to be smaller than the first groove, and the second bracket has a first protrusion being extended inwardly from the inner side surface of the first groove so as to fix the position of the second lens module.

A camera system includes two or more sensor arrays and an optical path. The sensor arrays are on the same sensor chip. Each sensor array includes the same field of view (FOV) as each other sensor array. The optical path includes a main lens and a metalens that are shared by each sensor array, and a microlens associated with each sensor array. The metalens splits incident light into different spectrums of light and directs each respective spectrum to a corresponding sensor array. The different spectrums of light include at least two of visible light, near infrared light, shortwave infrared and longwave infrared, and at least one sensor array includes single-photon avalanche diodes. The image processor that provides image processing, object recognition and object tracking and/or image fusion functionality may be on the same sensor chip as the sensor arrays.

Various embodiments include a chassis for a multi-camera system and techniques for forming such a chassis. The chassis may comprise multiple chassis portions that define cavities for mounting cameras. Some embodiments include a chassis portion comprising an integrated shield can-chassis that may be formed as a single component. According to some embodiments, subtractive manufacturing may be used to form one or more features of the chassis.

The present embodiment relates to a dual camera module comprising: a substrate; a first image sensor disposed on the substrate; a second image sensor disposed on the substrate while being spaced apart from the first image sensor; a housing disposed on the upper side of the substrate; a first bobbin disposed on the upper side of the first image sensor inside the housing; a second bobbin disposed on the upper side of the second image sensor inside the housing; a first coil disposed in the first bobbin; a second coil disposed in the second bobbin; and a first magnet which is disposed between the first coil and the second coil and faces the first coil and the second coil.

The present embodiment relates to a dual camera module comprising: a substrate; a first image sensor disposed on the substrate; a second image sensor disposed on the substrate while being spaced apart from the first image sensor; a housing disposed on the upper side of the substrate; a first bobbin disposed on the upper side of the first image sensor inside the housing; a second bobbin disposed on the upper side of the second image sensor inside the housing; a first coil disposed in the first bobbin; a second coil disposed in the second bobbin; and a first magnet which is disposed between the first coil and the second coil and faces the first coil and the second coil.

A lens module includes: a carrier having an internal space; a lens unit including a plurality of lens groups, the lens unit being installed on the carrier such that at least one of the lens groups is configured to move in a length direction of the carrier; a lens guide assembly including a plurality of guide members disposed on side surfaces of each of the lens groups, and configured to guide movement of at least two lens groups among the plurality of lens groups; and at least two driving wires connected to the plurality of guide members and formed of a shape memory alloy.

A system may include a processor, a night vision sensor, and an objective lens assembly comprising four lenses. Each of a first lens, a second lens, a third lens, and a fourth lens may be configured to project a real world scene onto one of four portions of the night vision sensor. The night vision sensor may be configured to provide four images of the real world scene from the objective lens assembly to the processor. The processor may be configured to: receive a first image, a second image, a third image, and a fourth image from the night vision sensor; generate color night vision image data based at least on the first image, the second image, the third image, and the fourth image; and output the color night vision image data.

Aspects of the disclosure relate to an apparatus including multiple image sensors sharing one or more optical paths for imaging. An example method includes identifying whether a device including a first aperture, a first image sensor, a second image sensor, and an optical element is to be in a first device mode or a second device mode. The method also includes controlling the optical element based on the identified device mode. The optical element directs light from the first aperture to the first image sensor in a first optical element mode. Light from the first aperture is directed to the second image sensor when the optical element is in the second optical element mode.