Abstract: A light beam can be steered using a non-mechanical beam steerer structure. For example, a combination of sub-aperture and full-aperture beam steering structures can be used (e.g., corresponding to regions of controlled variation in an index of refraction). The sub-aperture elements can include tapered structures defining a saw-tooth or triangular footprint in the plane in which the in-plane steering is performed. Respective rows of sub-aperture tapered structures can be configured to controllably steer the light beam in the first in-plane direction, wherein at least one row of sub-aperture tapered structures defines a first base region edge that is tipped at a first specified in-plane angle relative to a second base region edge defined by another row. Use of the tipped configuration can simplify a configuration of the beam steerer structure, such as allowing a configuration lacking a compensation plate at the input.

Abstract: A lidar system and method includes a photodiode array, a wafer, and a plurality of structures integrated on the wafer to form a metasurface lens. The metasurface lens is configured to focus the light pulses to the photodiode array and each of the plurality of structures includes at least one dimension that is less than a wavelength of the light pulses.

Abstract: A detector for use in detecting reflected or scattered light pulses for a lidar system includes a primary lens, a secondary lens, and a photodiode array. The primary lens is configured to collect and focus the light pulses, the secondary lens is configured to receive and further focus the light pulses from the primary lens, and the photodiode array is configured to receive and sense the light pulses from the secondary lens.

Abstract: A non-mechanical beamsteerer can be provided to adjust an angle of a light beam, such as to scan the light beam over a field of regard. The non-mechanical beamsteerer can include a first collection of steering elements that are smaller than a size of a light beam. The first collection of steering elements can adjust the angle of the light beam by diffracting the light beam. The non-mechanical beamsteerer can also include a second collection of steering elements that are larger than a size of the light beam. The second collection of steering elements can adjust an angle of the light beam by refracting the light beam. The non-mechanical beamsteerer can operate without a compensation plate, such as to provide a reduced size of the beamsteerer and an increased acceptance angle of the beamsteerer.

Abstract: The present subject matter includes apparatus and techniques that can be used to reduce losses in systems that perform steering of a light beam. Such steering can be performed in a non-mechanical manner, such as using an electrically-controlled optical structure (e.g., an electro-optical structure). For example, a waveguide can be used to adjust an angle of a light beam (e.g., steer the light beam). The waveguide can include a core, a cladding including an electro-optic material, and electrodes defining an arrangement that, when selectively energized, adjusts an index of refraction of the electro-optic material. In particular, electrode arrangements as described herein can be used to reduce losses, such as losses that would occur due to diffraction.

Abstract: The present subject matter includes apparatus and techniques that can be used to reduce losses in systems that perform steering of a light beam. Such steering can be performed in a non-mechanical manner, such as using an electrically-controlled optical structure (e.g., an electro-optical structure). For example, a waveguide can be used to adjust an angle of a light beam (e.g., steer the light beam). The waveguide can include a core, a cladding including an electro-optic material, and electrodes defining an arrangement that, when selectively energized, adjusts an index of refraction of the electro-optic material. In particular, electrode arrangements as described herein can be used to reduce losses, such as losses that would occur due to diffraction.

Abstract: Technologies are described for a segment eraser, where predefined graphical shapes or ink entries (hand drawn shapes through touch, gesture, or similar input) are modified through deletion of one or more segments, rotation, resizing, color changes, and comparable ones. Binary shape operations such as union combination, fragmenting intersection, and subtraction are performed on underlying shapes to create new shapes in predictable ways. A segment eraser according to embodiments works from endpoint to endpoint of the underlying shape outlines, on dosed shape areas when the shapes have no outline, and on dry ink strokes up to intersections with other ink entries.

Abstract: Techniques for implementing smart annotation of digital content on a computing device are described in this document. In one embodiment, a method includes receiving an annotation to a document displayed in an application on a computing device. The application is in an annotation mode in which any received user input is recognized as annotations but not a part of the underlying content. The method also includes determining whether the annotation is related to an editing mark applicable to the underlying content of the document. In response to determining that the received annotation is related to an editing mark, determining an editing operation corresponding to the editing mark and performing the editing operation to the underlying content in the displayed document without exiting the annotation mode of the application.

Abstract: A touchless water control system having at least one sensor capable of determining hand movement from point A to point B in a first direction, from point C to point D in a second direction and from point E to point F in a third direction thereby establishing a spatial field spaced away from a faucet through which a user's hand can be moved to initiate or terminate water flow, water temperature and water pressure.

Abstract: A touchless water control system having at least one sensor capable of determining hand movement from point A to point B in a first direction, from point C to point D in a second direction and from point E to point F in a third direction thereby establishing a spatial field spaced away from a faucet through which a user's hand can be moved to initiate or terminate water flow, water temperature and water pressure.

Abstract: A water purification and dispensing apparatus includes a water reservoir, a recirculation line having an inlet end connected to the reservoir and an outlet end connected to the reservoir, a pump connected to the recirculation line for pumping water through the recirculation line, and a water treatment mechanism in the recirculation line between the inlet end and the outlet end. The treatment mechanism includes an ultraviolet lamp. Further, a first water dispensing outlet is connected to the reservoir, and a second water dispensing outlet is connected to the reservoir.