Method of mapping source colors of a source content represented by source coordinates comprising: applying a reference display forward color transform characterizing a reference display device, applying a virtual display inverse color transform configured to model a virtual display device having approximately the same color primaries as a mastering display device used to master said source content.

The invention is generally directed to an attraction which draws a visitor's attention from other visual attractions in a fashion which provides a stunning visual perspective including a collection of curated images organized and facilitated by a human ambassador providing narrative and visual content and varying the visual presentation in an interactive fashion with an audience utilizing a gesture-based language to manufacture a bespoke experience.

In general, the subject matter can be embodied in methods, systems, and program products for using a display of a computing device as a light source. The computing device receives a first image that was captured by a camera of the computing device, determines a brightness of at least part of the first image, selects an intensity of a light source that is to be presented by the display of the computing device, the intensity of the light source being selected based on the determined brightness of the at least part of the image, presents the light source by the display of the computing device, the presented light source having the selected intensity, and receives a second image that is captured by the camera of the computing device while the computing device is presenting the light source on the display using the selected intensity.

Color calibration of color image rendering devices, such as large color displays, which operate by either projection or emission of images, utilize internal color measurement instrument or external color measurement modules locatable on a wall or speaker. A dual use camera is provided for a portable or laptop computer, or a cellular phone, handset, personal digital assistant or other handheld device with a digital camera, in which one of the camera or a display is movable with respect to the other to enable the camera in a first mode to capture images of the display for enabling calibration of the display, and in a second mode for capturing image other than of the display. The displays may represent rendering devices for enabling virtual proofing in a network, or may be part of stand-alone systems and apparatuses for color calibration. Improved calibration is also provided for sensing and correcting for non-uniformities of rendering devices, such as color displays, printer, presses, or other color image rendering device.

Color calibration of color image rendering devices, such as large color displays, which operate by either projection or emission of images, utilize internal color measurement instrument or external color measurement modules locatable on a wall or speaker. A dual use camera is provided for a portable or laptop computer, or a cellular phone, handset, personal digital assistant or other handheld device with a digital camera, in which one of the camera or a display is movable with respect to the other to enable the camera in a first mode to capture images of the display for enabling calibration of the display, and in a second mode for capturing image other than of the display. The displays may represent rendering devices for enabling virtual proofing in a network, or may be part of stand-alone systems and apparatuses for color calibration. Improved calibration is also provided for sensing and correcting for non-uniformities of rendering devices, such as color displays, printer, presses, or other color image rendering device.

To provide an image display device in which the number of pixels of arranged light emitting elements or the like can be reduced and the cost can be drastically reduced while image degradation is minimized, and a display unit used therefor. In an image display device in which plural display units including pixels formed by light emitting elements or the like are arranged in a plane, the display unit is configured by two-dimensionally arranging lattice-shaped pixel groups formed by providing pixels in locations corresponding to three lattice points of a square lattice, respectively, and forming a space area in which no pixel exists in a location corresponding to the remaining lattice point.

To provide an image display device in which the number of pixels of arranged light emitting elements or the like can be reduced and the cost can be drastically reduced while image degradation is minimized, and a display unit used therefor. In an image display device in which plural display units including pixels formed by light emitting elements or the like are arranged in a plane, the display unit is configured by two-dimensionally arranging lattice-shaped pixel groups formed by providing pixels in locations corresponding to three lattice points of a square lattice, respectively, and forming a space area in which no pixel exists in a location corresponding to the remaining lattice point.

An aquarium device having a compartment for a video playing device that is viewable through an aquarium tank for conveniently enhancing the viewing experience. The device includes a filtration system that is concealed from the viewer and that filters the water around the video device without exposing the device to water or any other elements of the aquarium's habitat.

A liquid crystal display device includes LEDs, a liquid crystal panel 11, a chassis, a frame 13, positioning ribs 23, and step portions 30. The liquid crystal panel 11 is configured to display using light from the LEDs. The chassis is arranged on an opposite side of the liquid crystal panel 11 from a display surface that is for display. The frame 13 is arranged on the display surface side of the liquid crystal panel 11. The frame 13 holds at least the liquid crystal panel 11 and the LEDs with the chassis such that the liquid crystal panel 11 and the LEDs are sandwiched between the frame 13 and the chassis. The positioning rib 23 having a block-like shape projects from the frame 13 toward the chassis and includes a peripheral surface opposite a peripheral surface of the liquid crystal panel 11 for positioning the liquid crystal panel 11 relative to the display surface direction. The step portion 30 projects from a portion of a distal end surface of the positioning rib 23 toward the chassis so as to form a step. The step portion 30 includes a peripheral surface (the inner surface 30a) opposite the peripheral surface of the liquid crystal panel 11. The peripheral surface of the step portion 30 is on the same plane with the peripheral surface of the positioning rib 23 (the inner surface 23a) which is opposite the peripheral surface of the liquid crystal panel 11.

A liquid crystal display device includes LEDs, a liquid crystal panel 11, a chassis, a frame 13, positioning ribs 23, and step portions 30. The liquid crystal panel 11 is configured to display using light from the LEDs. The chassis is arranged on an opposite side of the liquid crystal panel 11 from a display surface that is for display. The frame 13 is arranged on the display surface side of the liquid crystal panel 11. The frame 13 holds at least the liquid crystal panel 11 and the LEDs with the chassis such that the liquid crystal panel 11 and the LEDs are sandwiched between the frame 13 and the chassis. The positioning rib 23 having a block-like shape projects from the frame 13 toward the chassis and includes a peripheral surface opposite a peripheral surface of the liquid crystal panel 11 for positioning the liquid crystal panel 11 relative to the display surface direction. The step portion 30 projects from a portion of a distal end surface of the positioning rib 23 toward the chassis so as to form a step. The step portion 30 includes a peripheral surface (the inner surface 30a) opposite the peripheral surface of the liquid crystal panel 11. The peripheral surface of the step portion 30 is on the same plane with the peripheral surface of the positioning rib 23 (the inner surface 23a) which is opposite the peripheral surface of the liquid crystal panel 11.