A device includes several distinct laser sources each emitting an individual laser beam, a dispersive element, and a set of deflecting mirrors which, for each laser source, include a deflecting mirror associated to the source, the mirror reflecting the light beam emitted by the source towards the dispersive element, the mirror being positioned and oriented such that, after deflection by the dispersive element, the light beam is substantially centered on a common propagation axis, which is the same for the different light beams, the mirrors being integral with each other.

Disclosed systems and methods for the remote detection of atmospheric gas may include (1) receiving, at a collector, thermal infrared energy from at least one atmospheric column, (2) receiving, at optical subsystems, the thermal infrared energy over optical paths, (3) focusing the thermal infrared energy onto diffraction gratings that disperse the thermal infrared energy at a wavelength within a mid-wavelength infrared (MWIR) spectral region and a wavelength within a long-wavelength infrared (LWIR) spectral region, (4) receiving, at detectors, the thermal infrared energy dispersed from the diffraction gratings within the MWIR spectral region and the LWIR spectral region, (5) determining spectral component data associated with the thermal infrared energy in the MWIR spectral region and the LWIR spectral region, (6) sending the spectral component data to a computing device, and (7) identifying an atmospheric gas based on the spectral component data.

The present disclosure relates to an optical gas sensor including at least: an optical wave guide including a first elliptical mirror formed along at least part of a first 3-dimensional ellipsoid and having a first focal point and a second focal point, a second elliptical mirror formed along at least part of a second 3-dimensional ellipsoid and having the first focal point and a third focal point, and a third elliptical mirror formed along at least part of a third 3-dimensional ellipsoid and having the first focal point and a fourth focal point; one or more optical sensors installed at at least one of the first, second, third, and fourth focal points; and one or more light sources installed at at least one of the first, second, third, and fourth focal points where the one or more optical sensors are not installed.

A camera module includes: an image capturing unit configured to image an interior of a vehicle; and an illumination unit configured to illuminate the interior of the vehicle, in which the illumination unit includes a light source and an illumination lens configured to transmit a light beam from the light source, and the illumination lens sets an irradiation area having an irradiation width in a horizontal direction greater than an irradiation width in a vertical direction by reducing an area to which the light beam of the light source is transmitted in the vertical direction.

Systems and methods for optical narrowcasting are provided for transmitting various types of content. Optical narrowcasting content indicative of the presence of additional information along with identifying information may be transmitted. The additional information (which may include meaningful amounts of advertising information, media, or any other content) may also be transmitted as optical narrowcasting content. Elements of an optical narrowcasting system may include optical transmitters and optical receivers which can be configured to be operative at distances ranging from, e.g., 400 meters to 1200 meters. Additionally, the elements can be implemented on a miniaturized scale in conjunction with small, user devices such as smartphones. Moreover, optically narrowcast content may be filtered using at least identification data extracted from optical beacons received from optical transmitters such that only optically narrowcast content of interest is presented on a display and/or stored in a persistent storage.

An infrared light source component includes an infrared light source, a lens and a driving component. The infrared light source is configured to emit infrared light. The lens covers the infrared light source, and to guide the infrared light out of the infrared light source component. The driving component is configured to drive a motion of at least one of the infrared light source or the lens to enable the lens to guide the infrared light in a target direction. By the infrared light source component driving the motion of at least one of the infrared light source or the lens, the infrared light source component is able to change an emergent direction of the infrared light emitted by the infrared light source after it is projected by the lens, thereby enabling the lens to guide the infrared light in the target direction. An electronic device is further provided.

A light emitting control system is provided. The light emitting control system includes a housing, an IR emitter having a central axis and a lens structure. The housing has a receiving space, and the IR emitter is disposed in the receiving space of the housing. The lens structure is disposed on the reflector, the lens structure includes a lens facing the IR emitter, and a cross-sectional shape of the lens along a first cross-sectional line is asymmetric with respect to the central axis of the IR emitter.

A system includes a first optical communication interface and a second optical communication interface optically coupled via a free-space communication channel. The interfaces are spaced at variable distances. Each interface includes an optical source to provide a beam of electromagnetic energy and an optical receiver to receive the beam to bi-directionally communicate with the other interface via the channel. The first optical communication interface may be coupled to a sub-chassis. The second optical communication interface may be coupled to a device frame. The device frame may be movably coupled to the chassis. Communication may utilize multi-input, multi-output processing configured by a calibration matrix. A shutter may be positioned to receive the beam or be positioned clear of the beam depending on the distance between the interfaces.

A diverged beam optical transmitter is provided that includes a laser source configured to emit a light beam, and one or more lenses. The diverged beam optical transmitter also includes a diffuser placed between the laser source and the one or more lenses, and configured to increase an intrinsic divergence of the light beam and to fill some portion of the one or more lenses such that the light beam is eye safe after the one or more lenses.

A light shaping assembly comprises a printed circuit board (PCB), a two-dimensional (2D) array formed of a plurality of rows, each row comprising a plurality of light sources mounted on the PCB, and a Fresnel lens. The Fresnel lens redirects a light beam emitted by each light source at an angle that increases as a function of a distance between each light source and a selected point on the PCB, so that the light beams emitted by the light sources are collectively directed toward a common target.