lol, so did someone here comment over at designingwithLEDs as
led_master cmi? After search the comment there, I found this thread through Google.
http://www.designingwithleds.com/review-hands-cree-linear-led-t8-fluorescent-replacement-lamp/
The spectrum graph in that review uncovers the huge chunk missing between green and blue and all current production LED lights are missing anything shorter than the blue LED's spectrum which means that its completely missing UVA and violet spectrum. This prevents currently available LED lighting products from correctly rendering anything that have fluorescence or colors sensitive to proper spectral power distribution.
Go buy a box of the same kind of Triscuit I am showing you here. Everything about this item is spectrum sensitive. The crackers themselves, the picture of the crackers and the blue-green to golden yellow transition all show color shifts under different lighting. It's in the gamut range that's very difficult for my camera to capture or the monitor to display so I can't really display what I am seeing on the screen. I told the camera to white balance to a neutral gray card before taking each picture rather than using the "preset" daylight.
Visually very close to the way it looks under natural daylight. It should look bluish cyan. This is under 5000K color matching fluorescent lamps with CRI spec of 90. Under natural sunlight, incandescent, or wide spectrum fluorescent lighting you will see bright, deep, greenish marine blue. To me, almost sickeningly vibrant. Ironically, it looks just the opposite in these pictures. It looks almost the same under incandescent once you give your eyes the chance to adjust to color temperature difference.
Philips brand 5000K LED bulb. Note the peculiar color shift of printed crackers towards yellow. To my eyes, the green tint on the box was lost. It looks like shades of blue under a 5000K 90 CRI CREE/Eco Smart downlight as well. I believe it has to do with the interaction of the pigments with the spectral range between green and blue where LEDs have a spectral defect.
Pigments and colored transparent plastics showed the biggest skew. Things look very close between sunlight and colormatch 5000K fluorescent lamps, but not so with 5000K 90 CRI LED.
If everything shifted in color at the same time, it's just a matter of viewing pleasure. Unfortunately, they don't. The worst is when you try to get two sections to have the same color and they match up under defective light spectrum like LED, then have it show up as two different colors in the sun light.
It's convenient to play with words to pitch the absence of ultraviolet as a benefit for the LED industry simply because it's extremely difficult for affordable LED products to produce it. You'll find that different materials have different fluorescence. Light up with a black light. Soda bottles and such glow dim orange or yellowish. Some white plastics don't glow. Some glow brightly. So why does it matter? The binder or clear coat from different brands or batch may have different levels or color of fluorescence. This means that sources with inherent spectral defects like
LEDs may show a good color match with rest of the vehicle, but you see a clear difference once you look at it in the sun light in the morning.
