An optical numerical computation method obtains operands that have respective values, and modulates light sources to output light at amplitudes proportional to the operands. The light output for a given operand depends on whether the operand is positive or negative. The positive operands are output at wavelengths different from the negative operands. For operands that have multiple digits, the digits are separately treated so that the least significant digits are modulated with light sources at one frequency, and the most significant digits in two-digit numbers are modulated at another frequency, with positive and negative operands modulated at different frequencies. The light from the light sources enters a light collection cavity where it is sensed with sensors that generate resultant outputs at values indicative of the sensed light value.

A first light guide guides first light in a first light guiding path. The first light is of light irradiated from the light source to a sheet. A first detection unit receives reflected light from the sheet and outputs an image signal indicating an image of a surface of the sheet. A second light guide guides second light in a second light guiding path different from the first light guiding path. The second light is of the light irradiated from the light source and is different from the first light. A second detection unit receives the second light and output a detection signal corresponding to a light amount of the second light. A control unit controls a light emission amount of the light source based on the detection signal.

A droplet sensor includes: an optical cover having an ellipsoid surface that is a portion of a spheroid; a light source disposed at or in proximity to a first focal point of the ellipsoid surface; and a light detector disposed at or in proximity to a second focal point of the ellipsoid surface, wherein the ellipsoid surface is an effective detection area configured to reflect light emitted from the light source toward the light detector, and an amount of light reflected by the effective detection area changes in accordance with adhesion of droplets on the ellipsoid surface, and wherein the optical cover has a curved surface that is tangentially connected to an outside of the effective detection area and having a curvature greater than a curvature of the ellipsoid surface.

A lens (200) for detecting light waves (110) is provided. The lens comprises a first part (210) configured to receive light waves, wherein the first part (210) has the form of a spherical cap of a first sphere with a first radius. The lens also comprises a second part (220) in the form of a spherical segment of a second sphere (220) with a second radius. The radius of the second sphere is equal to or larger than the radius of the first sphere, and the centers of the first and second spheres coincide in a point on the optical axis of the lens (200). In a base side that faces away from the first part (210), the second part (220) comprises a plurality of concentric sections 230), each having a first surface (230a) that faces away from the optical axis of the lens (200) and that has the form of a spherical zone of a third sphere with a center coinciding with the centers of the first and second spheres. The lens (200) is configured to focus light waves from different angles of incidence onto a common focal plane.

A laser scanning microscope includes: an objective that irradiates a specimen with a laser beam; a detection lens that condenses the laser beam that passes through the specimen, the detection lens being arranged so as to face the objective; an optical element that is removably arranged between an image plane on which the detection lens forms an image of the specimen and a first surface that is a lens surface closest to the specimen of the detection lens, the optical element converting the laser beam made incident on the optical element into diffused light or deflecting a portion of the laser beam made incident on the optical element; and a photodetector that detects detection light emitted from the optical element arranged between the image plane and the first surface to the image plane.

A transmitter unit for wireless transmission of power by way of a bundled laser beam is described. The transmitter unit has a laser fiber bundle having a plurality of laser fibers, wherein each laser fiber is designed to emit a laser beam; positioning optics for adjusting an emission direction of the bundled laser beam; a field lens and a primary lens. The plurality of laser fibers is designed to emit a laser beam from each, passing through the positioning optics, the collimator lens and the primary lens, in this order, so that the laser beam emitted by the transmitter unit is emitted in bundled form. A particularly efficient device with an unlimited flight time and a large radius of use is achieved by the hybrid drive with solar power and laser power from the ground and temporary storage of the power in batteries.

The disclosure relates to a Lidar apparatus. The Lidar apparatus includes an area array light source, an emitting lens group, a receiving lens group, and an area array detector, where the area array light source is located in the front focal plane of the emitting lens group, and the area array detector is located in the back focal plane of the receiving lens group; a laser beam emitted from the area array light source is transmitted, through the emitting lens group, to an object to be detected and reflected by the object to be detected, and a reflected laser beam is transmitted to the area array detector through the receiving lens group; and an F-Theta lens is used for each of the emitting lens group and the receiving lens group, and the image height of the F-Theta lens is directly proportional to a field of view, such that angular resolutions of the Lidar apparatus are approximately distributed evenly. The disclosure further relates to a Lidar device and a vehicle. The technical solutions of the Lidar apparatus proposed by the disclosure may implement long-range solid-state Lidar detection with a large field of view and equal angular resolutions.

An omnidirectional lens is disclosed of the type which captures light from virtually all angles of incidence, and also emits light in all directions. Embodiments are specifically disclosed as a two-way lens that receives light beams from all directions of the compass and directs those light beams to a photosensor. The same two-way lens acts in a “beacon mode” to produce light beams from one or more LEDs, and to emit such light beams (again) in all directions of the compass. The emitted light beams can also be used to signal various functions as visible signals to users on a jobsite.

A multi-beam LIDAR optical system, that in one example includes a plurality of single mode optical fibers configured to transmit and receive light beams, and a plurality of lenses configured to collimate and focus the light beams between the plurality of single mode optical fibers and an entrance pupil of the system, wherein the system is configured to transmit and receive the light beams over an angular field of view of at least 5°.

An optical apparatus includes plural optical lens groups, an optical sensor, at least one lighting member 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. After the light beam passes through at least one of the plural optical lens groups, the light beam is sensed and converted into an image signal by the optical sensor. The lighting member outputs a source beam. The plural optical lens groups, the optical sensor and the lighting member are accommodated within the casing. The optical apparatus has a single optical lens module, and is able to implement different optical functions simultaneously. Consequently, the overall volume of the optical apparatus is minimized, the fabricating cost of the optical apparatus is reduced, the assembling process is simplified, and the number of components to be assembled is reduced.