An image projector includes an image forming element that is illuminated by a light from a light source, a projection optical system that projects a light output from the image forming element, a shifter that shifts the projection optical system with respect to the image forming element so as to shift a projection position, a deforming part that deforms an image formed on the image forming element, and a corrector that corrects a shift direction with the shifter on the basis of a deformation state by the deforming part.

A wearable device, which comprises: a ring-shaped case having an opening part formed in the middle thereof; a projector mounted at one side of the case and outputting an image; a lens part adjusting the direction and the size of the image, which is projected from the projector, so as to project the image; and a control unit for adjusting the projector and the lens part according to an image signal, can deliver visual information to a user wearing the wearable device even without a separate display unit by outputting the image onto the hand of the user.

A projector includes: a light source that emits light of a first color and a second color; a first image formation element that forms a first image light of the first color; a second image formation element that forms a second image light of the second color; a projection lens that projects the first image light and the second image light to the outside; a first optical system that guides light of the first color that is emitted from the light source to the first image formation element, and guides light of the first color from the first image formation element to the projection lens; and a second optical system that guides light of the second color that is emitted from the light source to the second image formation element, and guides light of the second color from the second image formation element to the projection lens; wherein the first optical system has a convex lens between the first image formation element and the projection lens, wherein f-number of the first optical system is greater than f-number of the second optical system.

Objects and their placement within a particular scene may be characterized using structured light with no or minimal manual intervention or calibration to the scene. The structured light pattern may be rendered with visible light, yet imperceptible to users, by generating a set of opposing excursions in one or more image properties for durations which are shorter than the integration time of the human eye. A set of assumptions and ongoing testing of those assumptions against physical objects identified within the environment allows characterization of the scene and the objects therein.

A projection apparatus configured to project a projection image based on image data through a projection optical system that includes a field curvature adjustment lens unit configured to adjust a field curvature in order to focus on a nonplanar projection surface includes a processor configured to generate the image data including information on a focus fixed position where a focus does not change on the projection surface in adjusting the field curvature.

A projection system including a safety detection system for a protected space, said projection system including a projection light source, a projection imaging system, a projection lens system, a detection source comprising at least of a detection light source and a detection camera comprising at least of a detection sensor, characterized by the fact that the optical axis of the projection source is identical to the optical axis of the detection source and the detection camera at least in the protected space.

A system and method for facilitating keystone correction in a given model of projector having an attached camera is disclosed. System calibration determines intrinsic and extrinsic parameters of the projector and camera; then control points are identified within a three-dimensional space in front of a screen. The three-dimensional space defines a throw range and maximum pitch and yaw offsets for the projector/screen combination. At each control point, the projector projects a group of structured light elements on the screen and the camera captures an image of the projected pattern. These images are used to create three-dimensional look-up tables that identify a relationship between each image and at least one of (i) pitch and yaw offset angles for the respective control point and (ii) a focal length and a principal point for the respective control point. The given model projectors use the tables in effectuating keystone correction.

There is provided an information processing device, an information processing method, a program, a projection device, and an information processing system capable of correcting distortion of a projection image by use of any image capturing device. The information processing device detects corresponding points on a projection image and a plurality of captured images on the basis of the projection image and the plurality of captured images, the projection image being projected on a projection surface by a projection device, the plurality of captured images having been obtained by image capturing of the projection image at a plurality of image capturing positions, estimates image capturing parameters including the plurality of image capturing positions and attitudes during image capturing at each of the image capturing positions and projection parameters including a position and an attitude of the projection device on the basis of corresponding point information indicating a relationship between the corresponding points, generates correction data used for geometric correction of an input image on the basis of the corresponding point information, the image capturing parameters, and the projection parameters, and transmits the correction data. The present technology can be applied to an information processing device that controls projection of a projector.

A light source device for generating laser light that is incident on a microlens array comprising a plurality of microlenses arranged in two directions orthogonal to each other includes a plurality of light sources that emits laser light. The light source image of the light source on the irradiated surface of the microlens array is elliptical, the long axis direction of the light source image intersects with both the two directions.

Systems integrating display resolution-multiplication solutions can be implemented in a variety of different ways. In many embodiments, the system includes an image projector for projecting image light, an image processor for computing a native image and at least one image shifted in a predefined direction, and at least one switchable grating capable of being switched between diffracting and non-diffracting states. In some embodiments, the switchable grating is optically coupled to the image projector. In a number of embodiments, the switchable gratings have a first configuration for propagating the native image light and at least one other configuration for propagating shifted image light having an angular displacement corresponding to the image shift in a predefined direction. By displaying the native and shifted images sequentially within a human eye integration period, the display resolution can be multiplied.