An imaging system includes an array of photodetectors configured to produce an array of intensity values corresponding to light intensity at the photodetectors. The imaging system can include a display for display images acquired with the array of photodetectors, after some image and display processing. The image and display processing components of the imaging system produce an array of display-formatted pixels for display on the imaging system display. The display-formatted pixels include at least a first plurality of pixels formatted for display using a first lookup table and a second plurality of pixels formatted for display using a second lookup table. Threshold criteria for choosing which pixels belong to which plurality are determined from analysis of a scene indicated by a user as a background scene. Once the threshold criteria are determined from the background the criteria are applied to pixels in subsequent image frames, and the pixels that meet the criteria are displayed in at least one color table LUT and the pixels that do not are displayed in a at least one different color table LUT. In a particular embodiment. The criteria may be above or below the max scene value (or temperature) from the background scene and pixels below the criteria may be displayed in a monochrome or non-vivid color table and pixels above the criteria are displayed in a vivid color table.

An imaging system includes an array of photodetectors configured to produce an array of intensity values corresponding to light intensity at the photodetectors. The imaging system can include a display for display images acquired with the array of photodetectors, after some image and display processing. The image and display processing components of the imaging system produce an array of display-formatted pixels for display on the imaging system display. The display-formatted pixels include at least a first plurality of pixels formatted for display using a first lookup table and a second plurality of pixels formatted for display using a second lookup table. Threshold criteria for choosing which pixels belong to which plurality are determined from analysis of a scene indicated by a user as a background scene. Once the threshold criteria are determined from the background the criteria are applied to pixels in subsequent image frames, and the pixels that meet the criteria are displayed in at least one color table LUT and the pixels that do not are displayed in a at least one different color table LUT. In a particular embodiment. The criteria may be above or below the max scene value (or temperature) from the background scene and pixels below the criteria may be displayed in a monochrome or non-vivid color table and pixels above the criteria are displayed in a vivid color table.

The present invention relates to a digital device digital device may comprise: an input unit; a display unit; and a control unit for displaying a color gain adjustment window on the display unit according to a first input, extracting, when a certain color is selected in the color gain adjustment window, unique R, G, and B values of the selected color respectively, increasing or decreasing each of the extracted unique R, G, and B values according to a second input, increasing the gain value of the corresponding color when at least one of the increased unique R, G, and B values is equal to or greater than a first reference value, and decreasing the gain value of the corresponding color when at least one of the decreased unique R, G, and B values is equal to or less than a second reference value.

The present invention is a method for enabling virtual reality interaction with gesture control, comprising the following steps: displaying a photographed second image in response to a gesture detecting signal; recognizing an actual gesture action in the second image and converting the same into a graphic pointer; and displaying a first image and displaying the graphic pointer at a position corresponding to the first image for interaction. A user may conduct control directly with a gesture to enable virtual reality, thereby solving the problem where the user cannot see an actual scenario as well as increasing the ease of use for virtual reality.

Methods of forming display structures, and structures formed thereby are described. Display structures formed may include a display device comprising an emissive layer that includes an array of pixels, wherein each of the individual pixels of the pixel array are capable of emitting light in at least two directions. A controllable opacity layer may be disposed on the emissive layer, wherein the controllable opacity layer is capable of at least partially blocking light emission from the array of pixels.

Methods of forming display structures, and structures formed thereby are described. Display structures formed may include a display device comprising an emissive layer that includes an array of pixels, wherein each of the individual pixels of the pixel array are capable of emitting light in at least two directions. A controllable opacity layer may be disposed on the emissive layer, wherein the controllable opacity layer is capable of at least partially blocking light emission from the array of pixels.

The system is comprised of a hub which in turn is made of a housing, at least one video input port, at least two video output ports, a digital card enabling communication between a computer and at least one display without a direct physical connection and a processor. The hub is used to make a video wall.

The system is comprised of a hub which in turn is made of a housing, at least one video input port, at least two video output ports, a digital card enabling communication between a computer and at least one display without a direct physical connection and a processor. The hub is used to make a video wall.

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.