Abstract: An athermal lens system includes a converging lens element having a negative first thermo-optic coefficient, and a diverging lens element having a second thermo-optic coefficient more negative than the first thermo-optic coefficient, wherein the diverging lens element is coupled with the converging lens element to form a converging athermal doublet lens.

Abstract: A camera module has light-field camera(s) and high resolution camera(s), the light-field camera(s) have multiple-lens arrays above an image sensor. The light-field camera(s) have a lens element at a same level as a lens element of the high resolution camera, the lens elements bearing apertures. The multiple-lens array of the light-field camera is above the image sensor at a same level as a flat transparent plate of the high resolution camera. The cameras lens cubes are made simultaneously by bonding molded lens plates and spacer plates, the lens plates and spacer plates including an upper lens plate having upper light-field camera lens elements and upper high resolution camera lens elements with applied apertures, multiple spacer plates, a microlens plate bearing an array of microlenses in the light-field cameras, the microlens plate being flat and transparent in areas of the high resolution camera.

Abstract: A camera module has light-field camera(s) and high resolution camera(s), the light-field camera(s) have multiple-lens arrays above an image sensor. The light-field camera(s) have a lens element at a same level as a lens element of the high resolution camera, the lens elements bearing apertures. The multiple-lens array of the light-field camera is above the image sensor at a same level as a flat transparent plate of the high resolution camera. The cameras lens cubes are made simultaneously by bonding molded lens plates and spacer plates, the lens plates and spacer plates including an upper lens plate having upper light-field camera lens elements and upper high resolution camera lens elements with applied apertures, multiple spacer plates, a microlens plate bearing an array of microlenses in the light-field cameras, the microlens plate being flat and transparent in areas of the high resolution camera.

Abstract: A bimodal zoom lens includes three coaxially aligned lenses including a first lens, a third lens, and a second lens therebetween. The first lens is a negative lens, each of the second lens and the third lens is a positive lens. The three coaxially aligned lenses form (i) a first configuration when the second lens and the first lens are separated by an axial distance L11 and (ii) a second configuration when the second lens and the first lens are separated by an axial distance L12, which exceeds axial distance L11. The second configuration has a second effective focal length that exceeds a first effective focal length of the first configuration.

Abstract: A near-eye display device includes (a) a display unit for displaying a display image, (b) a viewing unit for presenting the display image to the eye and transmitting ambient light from an ambient scene toward the eye, and (c) an eye imaging unit including (i) an illumination module for generating at least three infrared light beams propagating along at least three different, non-coplanar directions, respectively, (ii) a first beamsplitter interface, disposed between the display unit and the viewing unit, for merging at least a portion of each of the infrared light beams with visible display light to direct each portion toward the eye via the viewing unit, and (iii) a camera for imaging, via the viewing unit and the first beamsplitter interface, pupil of the eye and reflections of the infrared light beams incident on the eye, to form one or more images indicative of gaze direction of the eye.

Abstract: A projector assembly includes three coaxially aligned lenses and an aperture stop. The three coaxially aligned lenses include a first lens and, in order of increasing distance therefrom and on a same side thereof, a second lens and a positive meniscus lens. The first lens is a positive lens. The second lens is a negative lens. The second lens is located between the aperture stop and the positive meniscus lens. The projector assembly is one-sided telecentric at a plane proximate the positive meniscus lens.

Abstract: A low-height projector assembly includes a biconvex lens, a converging lens, an aperture stop, and a beam-steerer between the biconvex lens and the converging lens. The biconvex lens has a principal plane, a focal length, and a first optical axis. The converging lens has a second optical axis laterally offset from the first. The beam-steerer is configured to steer light from the biconvex lens to the converging lens. An aperture-stop plane intersects the second optical axis and the aperture stop. On the second optical axis, at least one of a front surface and a back surface of the converging lens is between the aperture-stop plane and the beam-steerer. The axial chief ray's propagation distance from the principal plane to the aperture stop differs from the focal length by less than half the depth of focus of the biconvex lens.

Abstract: A structure light module comprises: a VCSEL substrate comprising a VCSEL array comprising a plurality of individual VCSELs; a first spacer disposed on the VCSEL substrate; a first wafer level lens comprising a glass substrate and at least a replicated lens on a first surface of the glass substrate disposed on the first spacer; a FOE disposed on the first wafer level lens; a second spacer disposes on the FOE; a second wafer level lens comprising a glass substrate and at least a replicated lens on a first surface of the glass substrate disposed on the second spacer; a third spacer disposed on the second wafer level lens; a DOE disposed on the third spacer, where a structure light is projected from the DOE on a target surface for 3D imaging.

Abstract: A four-surface, near-infrared wafer-level lens system for imaging a scene onto an image plane includes (a) a first wafer-level lens having a first convex lens surface facing the scene and a second concave lens surface facing the image plane, and (b) a second wafer-level lens disposed between the first wafer-level lens and the image plane and including a third concave lens surface facing the scene and a fourth aspheric convex lens surface facing the image plane. The four-surface, near-infrared wafer-level lens system is further characterized by an image resolution corresponding to at least 60% contrast of 2 line pairs per millimeter in object plane across a scene portion having at least 10 millimeters extent in the object plane.

Abstract: A method for packaging applies to packaging a plurality of wafer-level lenses. Each wafer-level lens includes (a) a substrate with opposite facing first and second surfaces and (b) a respective lens element on at least one of the first and second surfaces. Each lens element has a lens surface facing away from the substrate. The method includes partially encasing the plurality of wafer-level lenses with a housing material to produce a wafer of packaged wafer-level lenses. In the wafer of packaged wafer-level lenses, the housing material supports each of the plurality of wafer-level lenses by contacting the respective substrate, and the housing is shaped to form a plurality of housings for the plurality of wafer-level lenses, respectively.

Abstract: A lensed beam-splitter prism array includes a beam-splitter substrate with a plurality of planar and parallel thin-film coatings each spanning a top substrate surface and a bottom substrate surface, and making an oblique angle therebetween, and a lens form layer formed on the top surface and having a plurality of lens forms, each lens form being above one of the plurality of coatings. A method for fabricating a lensed beam-splitter prism includes bonding a plurality of substrates to form a substrate stack having a coating between each adjacent substrate pair. The method also includes forming a stack slice by applying a plurality of parallel cuts at an oblique angle with respect to each coating. Each coating spans a first stack-slice surface and a second stack-slice surface opposing the first stack-slice surface. The method also includes forming a lens form layer on the first stack-slice surface spanning one or more coatings.

Abstract: A six-aspheric-surface lens has six coaxially aligned lenses including, in order, a positive first lens, a negative second lens, a negative third lens, a negative fourth lens, a negative fifth lens, and a plano-gull-wing sixth lens. The six-aspheric-surface lens also includes a first biplanar substrate between the first lens and the second lens, a second biplanar substrate between the third lens and the fourth lens, and a third biplanar substrate between the fifth lens and the sixth lens. The first lens may have an Abbe number exceeding 48, the second lens and the third lens each may have an Abbe number less than 35. The first lens may have a focal length f1 and the second lens may have a focal length f2 such that ?0.27<f1/f2<?0.17. The six-aspheric-surface lens may have an effective focal length feff and a total track length T such that 0.9<T/feff<1.1.

Abstract: A wide-angle lens system comprises a first lens having a concave aspheric surface and a planar surface, a second lens having a convex aspheric surface and a planar surface, a substrate, wherein the planar surface of the first lens is adjacent to a first side of the substrate and the planar surface of the second lens is adjacent to a second side of the substrate, a third lens behind the second lens having a concave aspheric surface and a planar surface, and a stop disposed between the first lens and the substrate. The planar surface of the third lens is secured to an outermost surface of an image sensor.

Abstract: An athermal compound lens includes a plano-concave lens and a plano-convex lens. The plano-concave lens has a first focal length, a first refractive index n1, and planar object-side surface opposite a concave image-side surface. The plano-convex lens is axially aligned with the plano-concave lens and has (i) a second focal length, (ii) a second refractive index n2, (iii) a planar image-side surface, and (iv) a convex object-side surface between the planar image-side surface and the concave image-side surface. In a free-space wavelength range and temperature range: (a) the first focal length divided by the second focal length is less than ?0.68, and (b) first and second refractive indices n1 and n2 have respective temperature dependences ? ? ? n 1 ? ? ? T ? ? and ? ? ? ? ? n 2 ? ? ? T that satisfy ( ? ? ? n 1 ? ? ? T ) / ( ? ? ? n 2 ? ? ? T ) ? 2.

Abstract: A cover-glass-free array camera with individually light-shielded cameras includes an image sensor array having a plurality of photosensitive pixel arrays formed in a silicon substrate, and a lens array bonded to the silicon substrate, wherein the lens array includes (a) a plurality of imaging objectives respectively registered to the photosensitive pixel arrays to form respective individual cameras therewith, and (b) a first opaque material between each of the imaging objectives to prevent crosstalk between individual cameras.

Abstract: A four-element athermal lens includes four coaxially aligned lenses including a (i) first lens and, in order of increasing distance therefrom and on a same side thereof, (ii) a second lens, a third lens, and a fourth lens. The first lens and the second lens are positive lenses. The third and fourth lenses are negative lenses. The first lens, second lens, third lens, and fourth lens have equal respective refractive indices n1, n2, n3, and n4. A difference between (i) the maximum of n1, n2, n3, and n4 and (ii) the minimum of n1, n2, n3, and n4 being less than 0.05 in a free-space wavelength range. Refractive indices n1, n2, n3, and n4 have respective temperature dependences ? ? ? n 1 ? ? ? T , ? ? ? n 2 ? ? ? T , ? ? ? n 3 ? ? ? T , ? ? ? n 4 ? ? ? T .

Abstract: A wide-angle lens system comprises a first lens having a concave aspheric surface and a planar surface, a second lens having a convex aspheric surface and a planar surface, a substrate, wherein the planar surface of the first lens is adjacent to a first side of the substrate and the planar surface of the second lens is adjacent to a second side of the substrate, a third lens behind the second lens having a concave aspheric surface and a planar surface, and a stop disposed between the first lens and the substrate. The planar surface of the third lens is secured to an outermost surface of an image sensor.

Abstract: In an embodiment, a slim imager is disclosed. The slim imager includes a substrate including an aperture, an image sensor, and an optics unit. The image sensor is on a bottom side of the substrate, spans the aperture, and has an aperture-facing top surface. The optics unit is on a top side of the substrate, spans the aperture, and includes a transmissive optical element having an aperture-facing bottom surface. A volume partially bound by the aperture-facing top surface and the aperture-facing bottom surface has a refractive index less than 1.01 at visible wavelengths.

Abstract: An athermal lens system includes a converging lens element having a negative first thermo-optic coefficient, and a diverging lens element having a second thermo-optic coefficient more negative than the first thermo-optic coefficient, wherein the diverging lens element is coupled with the converging lens element to form a converging athermal doublet lens.

Abstract: A four-surface, near-infrared wafer-level lens system for imaging a scene onto an image plane includes (a) a first wafer-level lens having a first convex lens surface facing the scene and a second concave lens surface facing the image plane, and (b) a second wafer-level lens disposed between the first wafer-level lens and the image plane and including a third concave lens surface facing the scene and a fourth aspheric convex lens surface facing the image plane. The four-surface, near-infrared wafer-level lens system is further characterized by an image resolution corresponding to at least 60% contrast of 2 line pairs per millimeter in object plane across a scene portion having at least 10 millimeters extent in the object plane.