Provided is a lamp for a vehicle. The vehicle lamp comprises a light source unit for generating light, and a lens unit for forming a predetermined beam pattern by allowing the light incident through a plurality of incident lenses from the light source unit to be emitted through a plurality of emitting lenses corresponding to each of the plurality of incident lenses. The plurality of incident lenses comprises a first incident lens for allowing the light incident from the light source unit to be emitted in a first direction, and a second incident lens for allowing a first portion of the light incident from the light source unit to be emitted in the first direction, and a second portion of the light to be emitted in a second direction different from the first direction.

An image capture device includes a plurality of independently formed camera channels. Each of the plurality of independently formed camera channels includes a respective lens that receives incident light and transmits the incident light to a respective sensor without transmitting the incident light to respective sensor of other camera channels within the plurality of independently formed camera channels. Further, a processor that is communicatively coupled to the respective sensor of each of the plurality of independently formed camera channels. The processor is configured to control an integration time of the respective sensor of each of the plurality of independently formed camera channels individually with the receive respective images from the respective sensor of each of the plurality of independently formed camera channels, and form a combined image by combing each of the respective images.

A compressive/transform imager comprising a lens array positioned above input ports for collecting light into the input ports, waveguides routing the light from the input port to waveguide mixing regions (e.g. multi-mode interference couplers), and detectors for receiving outputs of the waveguide mixing regions.

An optical substrate having a structured prismatic surface and an opposing structured lenticular surface. The structured lenticular surface includes shallow-curved lens structures. Adjacent shallow-curved lens structure may be continuous or contiguous, or separated by a constant or variable spacing. The lens structure may have a longitudinal structure with a uniform or varying cross section. The lenticular lenses may have a laterally meandering structure. Sections of adjacent straight or meandering lenticular lenses may intersect or partially or completely overlap each other. The lenticular lenses may be in the form of discontinuous lenticular segments. The lenticular segments may have regular, symmetrical shapes, or irregular, asymmetrical shapes, which may be intersecting or overlapping, and may be textured. The lens structure may be provided with isolated ripples, in the form of a single knot, or a series of knots.

An optical engine for a projector according to an embodiment of the present invention comprises: a first light source unit; a second light source unit which outputs a light with a color which is different from that of the first light source unit; a third light source unit which outputs a light with a color which is different from those of the first and second light source units; a micro display panel which outputs a predetermined image; a fly-eye lens which equalizes lights and includes a plurality of cells, each of which is configured by a convex lens; and a projection lens which projects a generated projection image to the outside on the basis of an output light of the first to third light source units and an output image, wherein two or more cells among a plurality of cells have shapes different from shapes of other cells. Therefore, optical efficiency can be improved while simplifying a structure and a component of the projector so that manufacturing costs and an installation space can be reduced and display quality can be improved.

An imaging device may include single-photon avalanche diodes (SPADs). Each SPAD may be overlapped by multiple microlenses. The microlenses over each SPAD may include first microlenses having a first size over a central portion of the SPAD and second microlenses having a second size that is greater than the first size over a peripheral area of the SPAD. The second microlenses may be spherical microlenses or cylindrical microlenses. The first microlenses may be aligned with underlying light scattering structures to improve the efficiency of the light scattering structures. The second microlenses may partially overlap isolation structures to direct light away from the isolation structures and towards the SPAD.

Certain aspects relate to systems and techniques for folded optic stereoscopic imaging, wherein a number of folded optic paths each direct a different one of a corresponding number of stereoscopic images toward a portion of a single image sensor. Each folded optic path can include a set of optics including a first light folding surface positioned to receive light propagating from a scene along a first optical axis and redirect the light along a second optical axis, a second light folding surface positioned to redirect the light from the second optical axis to a third optical axis, and lens elements positioned along at least the first and second optical axes and including a first subset having telescopic optical characteristics and a second subset lengthening the optical path length. The sensor can be a three-dimensionally stacked backside illuminated sensor wafer and reconfigurable instruction cell array processing wafer that performs depth processing.

An optical apparatus includes plural optical lens groups, an optical sensor and a casing. After a light beam passes through any of the plural optical lens groups, a travelling direction of the light beam is changed. Moreover, after the light beam passes through at least one of the plural optical lens groups, the light beam is sensed by the optical sensor and converted into an image signal by the optical sensor. The plural optical lens groups and the optical sensor are accommodated and fixed within the casing. The optical apparatus has a single optical lens module, and is able to implement different optical function simultaneously. Consequently, the overall volume of the optical apparatus is minimized, and the fabricating cost of the optical apparatus is reduced.

A camera module includes a circuit board; an image sensor mounted on the circuit board and electrically connected with the circuit boards, the image sensor comprising an array of focal planes; a barrel mounted on the circuit board with a cavity formed between the barrel and the circuit board, the image sensor being received in the cavity; and a lens stack array mounted to the barrel and spaced from the image sensor, the lens stack array comprising a plurality of first lens stacks, second lens stacks, third lens stacks, each of the lens stacks corresponding to one of the focal planes. The first lens stacks, the second lens stacks and the third lens stacks have different field of view and are combined in a single camera module, which enables a compact solution in a form of single camera module that traditionally requires multiple camera modules.

A flexible display device includes a flexible display panel, a correction panel, and a flexible printed circuit board. The correction panel includes a shape memory polymer layer and a driver. The shape memory polymer layer includes microlenses and the driver control the microlenses. The flexible printed circuit board connects the driver to a driving circuit board.