A light pattern projector with a pattern mask to spatially modulate an intensity of a wideband illumination source, such as an LED, and a projector lens to reimage the spatially modulated emission onto regions of a scene that is to be captured with an image sensor. The projector lens may comprise a microlens array (MLA) including a first lenslet to reimage the spatially modulated emission onto a first portion of a scene, and a second lenslet to reimage the spatially modulated emission onto a first portion of a scene. The MLA may have a fly's eye architecture with convex curvature over a diameter of the projector lens in addition to the lenslet curvature. The pattern mask may be an amplitude mask comprising a mask pattern of high and low amplitude transmittance regions. In the alternative, the pattern mask may be a phase mask, such as a refractive or diffractive mask.

An image capture apparatus includes an image capture element and a spatial filter. The spatial filter is disposed on the image capture element. The spatial filter includes a plurality of translucent substrates and a plurality of light shielding structures. The plurality of light shielding structures and the plurality of translucent substrates are alternately arranged along a first direction. Each of the light shielding structures at least includes a light absorbing layer, and the light absorbing layer has a plurality of first openings respectively corresponding to the pixel regions. At least one of the plurality of light shielding structures includes a reflective layer and a light absorbing layer stacked to each other. The reflective layer has a plurality of second openings respectively overlapped with the plurality of first openings of the light absorbing layer of the at least one of the plurality of light shielding structures.

With a projection device, a projection system including the projection device and a display device receives an image from the display device, projects the received image onto a projection target, captures a range including the projection target, and transmits the captured image to the display device. With the display device, the projection system receives the captured image from the projection device, displays the received captured image on the display, generates a drawing image based on a drawing operation, and transmits the generated drawing image to the projection device.

A method for controlling a projection device is disclosed, including steps of: receiving a projection instruction, and extracting projection information contained in the projection instruction, the projection information including destination position information and target projection position information; moving the projection device to a destination position in accordance with the destination position information and a predetermined map; and adjusting a projection height and/or a projection angle in accordance with the target projection position information, so as to adjust a projection position of the projection device to a target projection position.

The present disclosure provides an electronic device, a storage medium, and an image processing method, wherein, the electronic device includes a processing unit, a camera and a display screen covering the camera. Wherein, the display screen includes a light transmission area and a non-light transmission area, is configured to display a first image on the non-light transmission area under the control of the processing unit. The camera is disposed under the light transmission area, includes a projection assembly and an imaging assembly both electrically connected to the processing unit. The projection assembly is configured to project a second image on the display screen under the control of processing unit thereby to display the image on the light transmission area of the display screen, and the imaging assembly is configured to capture a third image through the light transmission area of the display screen.

A method, system, and apparatus, including a program encoded on computer-readable medium, for providing remote control of a light beam pointing device. The system includes a camera that captures at least one image at a first location and a light source that generates a light beam in a direction within a viewable area of the camera. At a second location, remote from the first location, a display screen displays images captured by the camera and a controller that controls pointing of the light source toward a desired target object at the first location.

Systems and methods for detecting and projecting obstructed content over touch screen obstructions are disclosed. In embodiments, a computer-implemented method, includes: displaying, by a computing device, content on a touch screen of the computing device; detecting, by the computing device, an obstruction of the content on one or more areas of the touch screen; determining, by the computing device, obstructed content in the one or more areas; determining, by the computing device, a display configuration for a portion of the obstructed content, wherein the display configuration defines a manner in which the portion of the obstructed content is to be projected by at least one wearable projector device; and sending, by the computing device, the display configuration to the at least one wearable projector device adapted to project the portion of the obstructed content over at least one object causing the obstruction of the content.

A method for controlling a projection device is disclosed, including steps of: receiving a projection instruction, and extracting projection information contained in the projection instruction, the projection information including destination position information and target projection position information; moving the projection device to a destination position in accordance with the destination position information and a predetermined map; and adjusting a projection height and/or a projection angle in accordance with the target projection position information, so as to adjust a projection position of the projection device to a target projection position.

Systems and methods for detecting and projecting obstructed content over touch screen obstructions are disclosed. In embodiments, a computer-implemented method, includes: displaying, by a computing device, content on a touch screen of the computing device; detecting, by the computing device, an obstruction of the content on one or more areas of the touch screen; determining, by the computing device, obstructed content in the one or more areas; determining, by the computing device, a display configuration for a portion of the obstructed content, wherein the display configuration defines a manner in which the portion of the obstructed content is to be projected by at least one wearable projector device; and sending, by the computing device, the display configuration to the at least one wearable projector device adapted to project the portion of the obstructed content over at least one object causing the obstruction of the content.

A light pattern projector with a pattern mask to spatially modulate an intensity of a wideband illumination source, such as an LED, and a projector lens to reimage the spatially modulated emission onto regions of a scene that is to be captured with an image sensor. The projector lens may comprise a microlens array (MLA) including a first lenslet to reimage the spatially modulated emission onto a first portion of a scene, and a second lenslet to reimage the spatially modulated emission onto a first portion of a scene. The MLA may have a fly's eye architecture with convex curvature over a diameter of the projector lens in addition to the lenslet curvature. The pattern mask may be an amplitude mask comprising a mask pattern of high and low amplitude transmittance regions. In the alternative, the pattern mask may be a phase mask, such as a refractive or diffractive mask.