Systems and methods in accordance with embodiments of the invention actively align a lens stack array with an array of focal planes to construct an array camera module. In one embodiment, a method for actively aligning a lens stack array with a sensor that has a focal plane array includes: aligning the lens stack array relative to the sensor in an initial position; varying the spatial relationship between the lens stack array and the sensor; capturing images of a known target that has a region of interest using a plurality of active focal planes at different spatial relationships; scoring the images based on the extent to which the region of interest is focused in the images; selecting a spatial relationship between the lens stack array and the sensor based on a comparison of the scores; and forming an array camera subassembly based on the selected spatial relationship.

An optical assembly includes a beam path, passing, in succession, through multiple microlens arrays and a Fourier lens assembly. The microlens arrays have a uniform aperture of their microlenses, and the entirety of the microlens arrays has an effective focal length. The optical assembly further includes an adjustment mechanism, configured to adjust a mutual optical distance of at least some of the microlens arrays in the beam path, thereby setting the effective focal length of the entirety of the microlens arrays. The adjustment mechanism has multiple adjustment positions i=1, . . . , M wherein M is a natural number ≥2, i is an adjustment position index, at which the term

[00001]$\frac{a^2}{\lambda .Math.f_{\mathrm{ML},i}}$

in each case essentially smoothly results in a natural number Ni. λ is a center wavelength, fML,i is an effective focal length fML of the entirety of the microlens arrays set by the adjustment position i.

A star scanner is provided that uses miniaturized high-speed electronics and an ultra-compact freeform optical design. The star scanner reduces instrument volume, reduces power consumption, and reduces costs, relative to existing star scanners. The optics can be used with a credit card-like footprint, electronics sensor board with optimally packed electronics.

A light-source device includes a plurality of light emitters; and a plurality of optical elements through which laser beams emitted from the plurality of light emitters pass. The plurality of optical elements includes: a first optical element configured to emit a laser beam of a first divergence angle; and a second optical element configured to emit a laser beam of a second divergence angle smaller than the first divergence angle.

Disclosed herein are techniques for aligning a collimator assembly with an array of LEDs. According to certain embodiments, a method includes using lithography to form a first plurality of contact pads and a second plurality of contact pads on a backplane; bonding a plurality of dies to the first plurality of contact pads, wherein each of the plurality of dies comprises a plurality of light emitting diodes; forming a first plurality of features on the second plurality of contact pads; and aligning a plurality of lenses on an assembly with the plurality of dies by coupling a second plurality of features on the assembly with the first plurality of features on the second plurality of contact pads.

An optically effective element includes a carrier, a first optically effective structure arranged on a top side of the carrier, and a cover arranged above the first optically effective structure. A method of producing an optically effective element includes providing a carrier, forming a first optically effective structure on a top side of the carrier, and arranging a cover above the top side of the carrier and the first optically effective structure.

A lens assembly includes a lens including an optical portion refracting light and a flange portion extending along a portion of a circumference of the optical portion, a blocking member disposed in front of the lens and having an opening to allow light to be incident on the lens, and a lens barrel accommodating the lens. The optical portion is noncircular and a portion of the blocking member facing the optical portion in an optical axis direction is located to be higher than a portion of the blocking member facing the flange portion in the optical axis direction.

The present disclosure relates to a lens coating fixture. The lens coating fixture includes: a fixture upper plate and a fixture lower plate that is arranged to be opposite to the fixture upper late and clamps a lens to be coated together with the fixture upper plate; wherein the fixture upper plate is provided with a plurality of first lends receiving holes, the fixture lower plate is provided with a plurality of second lens receiving holes that correspond to the first lens receiving holes and have the same size with the first lens receiving holes, the fixture upper plate is provided with recess portions surrounding the first lends receiving holes, protrusion portions are arranged at positions of the fixture lower plate corresponding to the recess portions, the protrusion portions being configured to be received in the recess portions when the fixture upper plate and the fixture lower plate are attached.

A lens array includes a plurality of lens parts arranged on a curved surface in a two-dimensional array. Each of the plurality of lens parts includes: a base part provided with a tapered side surface having an outer diameter that becomes smaller in a height direction away from the curved surface; and an apex part located on the base part and having a lens surface. There is an angular difference Δθ between height directions of two adjacent lens parts of the plurality of lens parts. The angular difference Δθ is smaller than an amount double a taper angle θ of the side surface of each of the two adjacent lens parts.

An image capture device includes a first housing, a second housing, a first integrated sensor-lens assembly (ISLA), and a second ISLA. The second housing is coupled to the first housing to form an internal compartment. The first ISLA includes a first image sensor coupled to a first lens in fixed alignment. The second ISLA includes a second image sensor coupled to a second lens in fixed alignment. The first ISLA is positively statically connected to the first housing, and the second ISLA is coupled to the first housing indirectly via the first ISLA.