An optoelectronic system includes a concentration layer, a modulation layer including an array of light modulators, an exit layer that receives the modulation layer output having a modulation layer output spatial distribution and remaps the modulation layer output spatial distribution to a modified spatial distribution. A collector layer receives the modified spatial distribution to produce a collector layer output. A detector receives the collector layer output. A processor controls the modulation layer and receives the detector output to generate an image. The collector layer can receive the modified spatial distribution at a plurality of collector layer inputs and combine the plurality of collector layer inputs at a collector layer output. Modulators can be configured to direct couple modulated light to a collector layer, without using an exit layer. Configurations with spatial light modulator modules and sub-modules are described.

A light-emitting device includes: a plurality of light-emitting elements arranged in an array on a base member; and a compound eye lens that comprises at least four Fresnel lenses disposed above the base member and facing the plurality of light-emitting elements. In a top plan view, a center of each of the plurality of light-emitting elements is offset from a lens center of the corresponding one of the Fresnel lenses of the compound eye lens in a direction toward a center of the compound eye lens. The plurality of light-emitting elements include at least two first light-emitting elements and at least two second light-emitting elements, wherein an emission color of the first light-emitting elements is different from an emission color of the second light-emitting elements.

Provided is an imaging device including a sensing array including a plurality of sensing elements, an imaging lens array including a plurality of imaging optical lenses, each of the plurality of imaging optical lenses having a non-circular cross-section perpendicular to an optical axis, and configured to transmit light received from an outside of the imaging device, and a condensing lens array including a plurality of condensing lenses disposed between the imaging lens array and the sensing array, and configured to transmit the light passing through the imaging lens array to the sensing elements, wherein a number of the plurality of imaging optical lenses is less than a number of the plurality of condensing lenses.

Disclosed are systems and methods for manufacturing energy directing systems for directing energy of multiple energy domains. Energy relays and energy waveguides are disclosed for directing energy of multiple energy domains, including electromagnetic energy, acoustic energy, and haptic energy. Systems are disclosed for projecting and sensing 4D energy-fields comprising multiple energy domains.

An illumination device includes a display panel including a first surface on which an image is displayed, a second surface opposite to the first surface, display pixels interposed between the first surface and the second surface, and a transmitting window interposed between the first surface and the second surface. The illumination device further includes a light source disposed on a side of the second surface of the display panel, and emitting light toward the second surface, and a light transmitter interposed between the light source and the display panel, and transmitting the emitted light to the transmitting window, the transmitted light being incident on the second surface of the display panel and being transmitted through the transmitting window toward the first surface of the display panel. The illumination device further includes a diffuser diffusing the light transmitted through the transmitting window.

An image sensor of the present disclosure includes a two-dimensional pixel array in which a plurality of pixels including photoelectric conversion elements are arranged in the form of an array on a substrate, a transparent layer formed on the two-dimensional pixel array, and a two-dimensional spectroscopic element array in which a plurality of spectroscopic elements are arranged in the form of an array inside or on the transparent layer. Each spectroscopic element includes a plurality of microstructures made of a material having a higher refractive index than a refractive index of the transparent layer. The plurality of microstructures have a microstructure pattern. Each of the spectroscopic elements splits incident light into first to fourth deflected lights, which have different transmission directions, according to the wavelength region. A first to fourth pixels, which are adjacent to each other and are located directly below each of the spectroscopic elements, respectively detect the first to fourth deflected lights.

An illuminator apparatus can include: an optical source a collimator lens located on an optical axis of the optical source, for receiving emitted light from the optical source to emit collimated light; and a diffusion lens, located on an emitting surface side of the collimator lens, for receiving the collimated light to diffuse the collimated light. The diffusion lens can be provided with a diffusion section for diffusing central light of the collimated light emitted from a central portion of an emitting surface of the collimator lens and a non-diffusion section for transmitting peripheral light of the collimated light emitted from an outside of the central portion of the emitting surface of the collimator lens, without diffusing the peripheral light.

The present disclosure provides a method for manufacturing a diffusion cover that diffuses and transmits light from a semiconductor light-emitting element. The method includes the steps of preparing a base member having an obverse surface and a reverse surface that face away from each other in a thickness direction; forming a lens material on the obverse surface, the lens material containing a photosensitive transparent resin; and removing a portion of the lens material by performing grayscale exposure and development, and forming a lens having a plurality of lens members. Such a configuration can provide a diffusion cover suitable for reducing the manufacturing cost.

A light field near eye display device including a display element, a micro-lens array, a first lens, and a second lens is provided. The display element provides an image light beam. The micro-lens array is located on a transmission path of the image light beam, and has multiple micro-lenses. The first lens is located on the transmission path of the image light beam, where the micro-lens array is located between the first lens and the display element. The second lens is located on the transmission path of the image light beam, and located between the micro-lens array and the display element. The following formulas are satisfied: $.Math.\frac{1}{f_{\mathrm{MLA}}}.Math.>.Math.\frac{1}{f_1}.Math.,$
and $.Math.\frac{1}{f_{\mathrm{MLA}}}.Math.>.Math.\frac{1}{f_2}.Math.,$
where f.sub.MLA is an equivalent focal length of the micro-lenses, f.sub.1 is an equivalent focal length o

An image sensor includes a color sensor chip configured to generate a color image by sensing visible light in incident light; a light transfer layer disposed under the color sensor chip, and including an infrared light pass filter which filters infrared light from light having passed through the color sensor chip; and a depth sensor chip disposed under the light transfer layer, and configured to generate a depth image by sensing the infrared light.