A paint composition comprises a carrier material, a plurality of ambient light absorbing pigment particles dispersed in the carrier material comprising a component that absorbs predetermined visible wavelengths, and a plurality of fluorescent pigment particles dispersed in the carrier material, wherein the fluorescent pigment particles emit a first color and the paint composition emits a second color different from the first color when illuminated by an ultraviolet light source. The paint composition can act as a video projection surface with usable screen gain.

A video display system includes a light source configured to generate light and a substrate having a plurality of pixels deposited on a first side of the substrate. Each of the pixels is formed from a plurality of photo-luminescent dyes, and the light source is configured to project light onto the first side of the substrate to illuminate at least a subset of the photo-luminescent dyes in a raster pattern to generate an image. In another embodiment omitting the substrate, the photo-luminescent dyes forming the pixels are deposited directly onto a screen.

A display screen includes a filter layer, a fluorescent layer having parallel fluorescent stripes, and an attachment layer between an excitation side of the fluorescent layer and a first side of the filter layer to attach the excitation side of fluorescent layer to the filter layer while providing vertical separation therebetween. The attachment layer includes attachment regions that are separated from each other by lateral spacings such that excitation-side air gaps are formed between areas of the fluorescent layer and the filter layer that correspond to the lateral spacings. During display operation, excitation light received on a second side of the filter layer propagates through to the first side of the filter layer, and at least a portion of the excitation light that propagates from the second side of the filter layer travels through the excitation-side air gaps to excite the fluorescent stripes.

Disclosed are a projection device and a light source driving method thereof. The projection device includes a light source module. The light source driving method includes: driving a blue light source of a light source module to output a blue light beam at a first power and a second power respectively, and driving a red light source of the light source module to output a first red light beam at the first power and the second power respectively, wherein a color wheel module of the light source module converts the blue light beam to generate a second red light beam; sensing luminance of the first red light beam and the second red light beam, and correspondingly generating red light luminance information; calculating red light driving parameters of the red light source and the blue light source according to luminance information of the first red light beam and the second red light beam; and controlling, according to the red light driving parameters, electrical signals for driving the blue light source and the red light source, so as to maintain the sum of luminance of the red light beams to be approximate to or equal to a target red light luminance.

Chromatic aberration can be reduced and extreme projection angles can be allowed in a projection system by modifying one color channel of light having a wavelength bandwidth with image data to produce imaged light, causing the imaged light to spread angularly when displaying the imaged light through an optical distorting element onto a screen, and reducing angular spread of the imaged light exiting the optical distorting element by adjusting the wavelength bandwidth.

Disclosed are a projection device and a light source driving method thereof. The projection device includes a light source module. The light source driving method includes: driving a blue light source of a light source module to output a blue light beam at a first power and a second power respectively, and driving a red light source of the light source module to output a first red light beam at the first power and the second power respectively, wherein a color wheel module of the light source module converts the blue light beam to generate a second red light beam; sensing luminance of the first red light beam and the second red light beam, and correspondingly generating red light luminance information; calculating red light driving parameters of the red light source and the blue light source according to luminance information of the first red light beam and the second red light beam; and controlling, according to the red light driving parameters, electrical signals for driving the blue light source and the red light source, so as to maintain the sum of luminance of the red light beams to be approximate to or equal to a target red light luminance.

A multi-layer display screen capable of being tiled without a visible gap between tiled screens and methods of using said device are described herein. In one embodiment, a system includes a light generator configured to produce light and a multi-layer screen with a plurality of layers. The multi-layer screen can be configured to permit the light from the light generator to propagate therethrough. The plurality of layers can include an opaque region layer having a plurality of opaque regions and a first layer comprising one or more abutted layers disposed within a common plane, the abutted layers spaced apart by a gap, wherein the gap is coincident with the opaque region.

Systems, methods, and computer-readable media are disclosed for mountable clear displays and projection systems. In one embodiment, a system may include a mirror surface and a transparent display sheet adhered to the mirror surface. The transparent display sheet may include a blue phosphor layer that absorbs light having the first wavelength and emits light having a fourth wavelength of about 460 nm, a green phosphor layer that absorbs light having the second wavelength and emits light having a fifth wavelength of about 530 nm, a red phosphor layer that absorbs light having the third wavelength and emits light having a sixth wavelength of about 625 nm, and a blue light blocking layer attached to the red phosphor layer of the transparent display sheet, the blue light blocking layer configured to absorb blue light passing through the transparent display sheet.

A display system configured to provide projection mapped augmentation of mechanically animated objects. These mechanically animated objects may take the form of a screen assembly with a projection surface, and a screen actuator may be included in the display system that is operated by a controller to move, to expand, or other otherwise operate the screen assembly so as to modify or morph the projection surface to move and/or change its shape and/or size. Hence, the screen assembly is animated. The display system further includes a projector operated by the controller, in a synchronized manner with the screen actuator, to project content onto the projection surface as it is moved and/or has its shape and/or size changed over time. The projected content is mapped to the various states and movement of the projection surface to avoid blow-by and to suit the changes of the projection surface.

There is provided a screen capable of sufficiently reducing speckles. A screen for displaying an image by being irradiated with a light beam from a projector, is provided with a plurality of particles each including a first part and a second part different in dielectric constant, a particle layer having the plurality of particles, and electrodes which form an electric field for driving the particles of the particle layer by applying a voltage to the particle layer.