Disclosed herein are methods and systems for combining foreground video and background video using chromatic matching. In an embodiment, a system obtains foreground video data. The system obtains background video data. The system determines a color-distribution dimensionality of the background video data to be either high-dimensional chromatic or low-dimensional chromatic. The system selects a chromatic-adjustment technique from a set of chromatic-adjustment techniques based on the determined color-distribution dimensionality of the background video data. The system adjusts the foreground video data using the selected chromatic-adjustment technique. The system generates combined video data at least in part by combining the background video data with the adjusted foreground video data. The system outputs the combined video for display.

A liquid crystal display device includes an LED that emits blue light having a light emission spectrum with a half value width less than 25 nm, green light having a light emission spectrum with a half value width less than 52 nm, and red light having a light emission spectrum with a half value width less than 40 nm, and a color filter including a blue coloring unit having a transmission spectrum with a peak wavelength from 440 nm to 461.5 nm and a half value width less than 100 nm, a green coloring unit having a transmission spectrum with a peak wavelength from 510 nm to 533.5 nm and a half value width less than 90 nm, and a red coloring unit having a transmission spectrum with a wavelength greater than or equal to 580 nm for the half value of a peak.

A liquid crystal display device includes an LED that emits blue light having a light emission spectrum with a half value width less than 25 nm, green light having a light emission spectrum with a half value width less than 52 nm, and red light having a light emission spectrum with a half value width less than 40 nm, and a color filter including a blue coloring unit having a transmission spectrum with a peak wavelength from 440 nm to 461.5 nm and a half value width less than 100 nm, a green coloring unit having a transmission spectrum with a peak wavelength from 510 nm to 533.5 nm and a half value width less than 90 nm, and a red coloring unit having a transmission spectrum with a wavelength greater than or equal to 580 nm for the half value of a peak.

Various embodiments relate to an apparatus for controlling a lighting device. A light control circuit can use a controlled lighting sequence control and drive viewed sections of a lighting device to display chroma key color or emit infrared light, while driving other unviewed portions of the lighting device to display ambient and incident lighting. The viewed and unviewed lighting sections can be based on the field of vision of an image capture device and can change in relation to movements of the image capture device. A sensor can make measurements to determine the field of vision of the image capture device and can be used to generate or modify the controlled lighting sequence. An image processing circuit can generate a composite image using the chroma key while maintaining the subjects that are captured using ambient and incident lighting.

Various embodiments relate to an apparatus for controlling a lighting device. A light control circuit can use a controlled lighting sequence control and drive viewed sections of a lighting device to display chroma key color or emit infrared light, while driving other unviewed portions of the lighting device to display ambient and incident lighting. The viewed and unviewed lighting sections can be based on the field of vision of an image capture device and can change in relation to movements of the image capture device. A sensor can make measurements to determine the field of vision of the image capture device and can be used to generate or modify the controlled lighting sequence. An image processing circuit can generate a composite image using the chroma key while maintaining the subjects that are captured using ambient and incident lighting.

Violet narrowband light Vn and green narrowband light Gn produced by a light source device are supplied to a complementary color type endoscope, and simultaneously applied to an observation object. In a complementary color type imaging device, first mixed pixels and second mixed pixels, which sense both of the violet narrowband light Vn and the green narrowband light Gn, are read out. The light amount ratio Z of the violet narrowband light Vn to the green narrowband light Gn is set in such a range as to make the light amount of the violet narrowband light Vn larger than the light amount of the green narrowband light Gn, and make a signal value of the second mixed pixel higher than a signal value of the first mixed pixel.

Violet narrowband light Vn and green narrowband light Gn produced by a light source device are supplied to a complementary color type endoscope, and simultaneously applied to an observation object. In a complementary color type imaging device, first mixed pixels and second mixed pixels, which sense both of the violet narrowband light Vn and the green narrowband light Gn, are read out. The light amount ratio Z of the violet narrowband light Vn to the green narrowband light Gn is set in such a range as to make the light amount of the violet narrowband light Vn larger than the light amount of the green narrowband light Gn, and make a signal value of the second mixed pixel higher than a signal value of the first mixed pixel.

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.

Techniques for identifying usable projection areas within an environment and projecting content onto these areas are described herein. The systems described herein may include one or more projectors, one or more cameras, and one or more computing devices. In some instances, the described techniques may utilize the one or more cameras to identify a flat projection surface. After identifying this surface, the techniques may use depth detection, edge detection, or other techniques to determine whether the surface includes any objects protruding there from. If so, then the techniques may identify the size and location of these objects and may store an indication that these objects occlude a portion of the flat projection surface and, therefore, that the locations associated with these objects are not usable projection areas. The techniques may then deduct the locations of the objects from the initially identified projection surface to determine the usable projection areas.

The systems and methods of illuminating instrument features disclosed herein provide for the illumination of the interior of an instrument, such as an acoustic guitar with a sound hole, and a drum, among others, with an illumination source (a non-limiting example is light emitting diodes (LEDs)). One or more illumination sources may be attached to the inside of the instrument to direct light such that the hole is illuminated. The illuminated opening may reveal as non-limiting examples, logos, art work, messages, wording, and text, among others.