Motion picture visual effects have relied heavily on blue screen and green screen compositing techniques. The use of high resolution video walls or displays to replace green screens is becoming more common. The video image relies on the principle of Red, Green and Blue LEDs (RGB) to render the image. Increasingly cinematographers are trying to use the RGB light emanating from the display screen as an illuminant for the foreground images they are photographing. The RGB spectrum is deficient in broad spectrum white light which is critical for properly rendered skin tones as well as other subject colors.
Conventional lighting apparatus are controlled from lighting dimmer boards that send a digital multiplex (DMX) signal for a light to behave in a predetermined manner. Lighting apparatus can consist of several independently controlled elements or pixels. A lighting board can be tailored to synchronize with a video signal but can only generate as many pixel controls as the lighting instrument is designed with. They are large in area and are not designed to reproduce a video image.
This invention sets out to create an Illumination apparatus operating on the principles of an RGB video display such as shown in
This invention sets out to remedy the color imbalance which exists in the prior art from the blending of RGB LEDs as well as their shadow enhancement capabilities. This invention utilizes a light source that operates from a video signal and uses the RGB data to illuminate foreground subject or subjects appearing in front of the video wall. This illumination apparatus operates on a video signal through pixels formed using RGB LEDs plus additional LEDs which are not RGB LEDs as shown in
The invented solution is to use a greater than three LED system (for example; Red, Green, Blue, Cool White and Warm White) for a video wall used as a light source for subjects captured on camera. This allows for higher quality white light compared to white light created by narrow FWHM (full width at half maximum) RGB LEDs. The pixelated nature of the video wall allows the light emanating from the video wall to be used to create specific effects and light movement that cannot be done with existing lighting systems.
To do this, the RGB video signal needs to be mapped to the greater than three LED system as shown in
The 3DLut is in the video pipeline right before the LED driver electronics. The 3DLut could be applied to the gamma encoded signal or a 1DLut could be used to modify the video signal and the 3DLut could be applied to the modified video. As to the specifics of a 3DLut (or 1DLut), such look up tables are well known mechanisms to map one color space to another to, for example, calculate preview colors for a monitor or digital projector of how an image will be reproduced on another display device, typically the final digitally projected image or a release print of a movie. More specifically, persons skilled in the art would readily know how to create a 3DLut which maps a set of three RGB values to another set of three RGB values, typically to adjust the output which is displayed on a particular display so that the colors appear closer to the actual RGB values than would otherwise be the case. According to the invention, instead of a 3 to 3 mapping, a 3 to 3+n mapping is used where n is the additional number of LEDs used to produce a full white spectrum with a higher quality white than would otherwise be the case. As one example, assume 3×8 bit color space with R=255, G=255 and B=255 which should be displayed as pure white. But due to the characteristics of the RGB LEDs of the display, the white as displayed is not of the highest quality. A person skilled in the art knowing the characteristics of the RGB, and non RGB LEDs of the display would know that the display produces a high quality pure white by transforming the 255 255 255 RGB values to 255 254 250 255 255 where the first three values are the values provided to the RGB pixels respectively and the last two values are respectively mapped to the two additional LEDs. A 3DLut is created in this manner. Of course, the specific mappings would depend on the characteristics of the LEDs in use and the desired lighting output. In an embodiment, instead of or in addition to a 3DLut, controls could be used to adjust the output values until the desired lighting effect is obtained. Separate control of the additional LEDs allows for the color quality to be adjusted to desired settings. The specifics of such a control mechanism which simply adjusts a value provided to each of the LEDs making up a pixel are well known to video lighting practitioners and is usually implemented via software in commercially available video wall processors. The 3DLut and control mechanism can be embedded in the panel or as a separate element which connects to the panel such as a commercially available receiver card.
Another objective of this invention is to be able to simulate moving image patterns from a scene in synchronization with the video image from the source. For example, walking or driving under a tree canopy results in patterns of sunlight penetrating the leaves. Simply using a synchronized display wall above an actor would project the green of the leaves as well as any sunlight in a blended fashion that would appear as a soft light wash over the foreground scene. The scene in its blended form would appear greener than daylight. There would not be any visible distinct pattern of sunlight through leaves. Direct beams of light need to be generated at a narrow beam angle. To lessen the influence of other colors, the light should be able to independently control and desaturate the RGB pixels while independently controlling the additional LEDs to simulate the sunlight.
The invention is directed to an LED display panel using more than three LEDs for each pixel. The LEDs would consist of Red, Green, Blue and at least one additional source LED. Each LED pixel in one embodiment is fitted with narrow beam lenses as shown in
The panel or panels operate at sufficient frequency to allow for the video to be genlocked or synchronized to a camera at various frame rates per second. Traditionally, cameras can be set to frame rates of, but not limited to 24 fps, 48 fps, 96 fps and 120 fps. The panel allows for separate control of the RGB portion of the video data stream from the one or more additional LEDs. The separate control over the RGB pixels would allow the colors to be desaturated while maintaining the visual pattern of the streaming video image.
The foregoing descriptions of specific embodiments and devices is used to illustrate the invention and how it may be implemented, but such embodiments and devices are not intended to limit the scope of the invention as defined by the following claims.
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Number | Date | Country | |
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20210125535 A1 | Apr 2021 | US |
Number | Date | Country | |
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62927019 | Oct 2019 | US |