I know an artist who is an expert of mixing colors and lightning. He spend his whole life mixing colors. In the past decades he created several color palettes to be use inside and/or outside buildings [1]. In 2013 and 2014 he created 21 works (consisting of pairs of paintings) that contain color palettes experimenting with variations of brightness and saturation of six evenly passed colors [2]. In 2020/2021, he created eight works with color palettes existing of twelve even passed colors with the same brightness and saturation (by daylight) [3].
He complains a lot about lightning in museums, that it deviates a lot from daylight, while many works of art are create by daylight. The light is often too yellow, based on some 'dubious' research that museum visitors prefer yellow light. LED lightning often causes mixtures of pigments that look the same under daylight to look different under LED lightning. LED lightning often is rather weak in the infra-red to red part of the spectrum cause most reds in painting to fade. He found a combination of a reddish and a blue TL-lamps supporting to LED lights to give a better approximation of daylight. When this was applied to some museum rooms, the son of a man who donated a work, asked what they did with it work as it looked again like how it looked at their home when it was hung close to the windows. (Shortly after this the museum director decided to use only LED lightning for the new wing that was going to be build.)
The problem of course is that we are so used to adapt our color vision to the lightning that most people do not see the difference. I guess that people who mix colors all the time, develop some kind of absolute color vision and do notice the effect of improper lightning on art works.
For all classical works, I reckon there’s no question the light they were created under would be some variant of black-body radiation: sun, incandescent bulb, fire. The distinguishing part of black-body radiation is that its spectrum is continuous throughout.
Compared to incandescent lamps, fluorescent sources including LEDs emit spectrum that is bumpy or even spiky. Those spikes fall within R, G and B and the resulting light looks white itself; but the objects or paints from which it reflects may not look the same[0]. At extremes, depending on what the paint is made of (not simply its colour!), the picture may look very different.
(Ever noticed how you may admire an amazingly vibrant flower in the field, but no photo seems to reproduce that brilliance? That’s another example of metameric failure.)
To see a work of art how it was intended to look, you should view it under the light it was created in. Unfortunately, it appears impossible to break from the shackles of LED these days. Depending on where you live, it may actually be impossible to source a tungsten filament bulb. You’d think it should be easy and worth the extra electricity expense to the management of any good gallery or museum, but apparently not.
> LED lightning often causes mixtures of pigments that look the same under daylight to look different under LED lightning.
I'm surprised that this extremely cool phenomenon is not embraced by artists and exploited as an essential part of their language. For example, they could use pigments with bizarre absorption spectra/fluorescent properties, so that the same painting looks completely different when put near a sunny window or under a led lamp.
Focusing only on color rendering under daylight seems a bit short-sighted, now that we master all sorts of synthetic lighting and fancy chemistry.
It’s a technique used heavily in psychedelic art and set design for festivals and events, particularly before projection mapping became the norm. When there’s spectral control of the lighting source this can be varied to bring out extremely contrasting detail in a surface or set of surfaces. As with most techniques its usage can range from pure gimmick to beautifully executed mastery.
You can get a decent idea of the color shifts from an LED light’s spectrum if the manufacturer publishes TM-30 data for it. This attempts to compare color rendering similarity vs a reference illuminant, based on 99 spectral reflectance distributions representing a variety of objects that might be illuminated. The standard has been around since 2015, but unfortunately many LED light manufacturers still don’t provide this.
The spectrum data gets boiled down (or not) in a couple of ways:
1) Rf, or “fidelity index” where a score closer to 100 means it renders colors more similarly to how they look under a reference illuminant (which standard illuminant is used for comparison depends on color temperature). But as you summarize more information down to fewer values, you of course get less detail - many different spectrums could provide an Rf of 95, with different visual effect. Rf only gives you an idea of whether the visual difference between this light source and the reference illuminant will be large or small. It’s a similar concept to “CRI” scores if you’re familiar with that, but based on a much better set of samples, and not as easily gamed for a high score by carefully designing an LED’s spectrum to correctly render CRI’s more limited set of color samples.
2) Color vector graphic, shown on page 28 of the PDF linked below, shows a smushed circle which broadly illustrates how different hues are shifted. For example, reds might be undersaturated and shifted toward orange. This is still summarizing, not all red objects will have the same shift, depending on their precise spectral reflectance distribution and the source’s spectral power distribution. But it gives a better idea of how the light will look than the Rf alone.
3) Color sample vectors shown on page 24 of the same PDF, which shows each of the individual 99 spectral reflectance samples used for TM-30 and how it will shift compared to when viewed under the standard illuminant. The color vector diagram in point 2 is a summary of these, but if you want more detail you could see them individually. I’m not sure anyone actually publishes this since these particular 99 samples aren’t likely applicable to whatever you’re doing. And ultimately it’s still not the full story, because this is all based on 99 specific color samples attempting to be a representative spread of materials you might encounter in the real world. But 99 samples certainly can’t represent all materials. To get real answers you’d need to go down the same rabbit hole that the article did and measure the spectral reflectance of every object you’re lighting.
He complains a lot about lightning in museums, that it deviates a lot from daylight, while many works of art are create by daylight. The light is often too yellow, based on some 'dubious' research that museum visitors prefer yellow light. LED lightning often causes mixtures of pigments that look the same under daylight to look different under LED lightning. LED lightning often is rather weak in the infra-red to red part of the spectrum cause most reds in painting to fade. He found a combination of a reddish and a blue TL-lamps supporting to LED lights to give a better approximation of daylight. When this was applied to some museum rooms, the son of a man who donated a work, asked what they did with it work as it looked again like how it looked at their home when it was hung close to the windows. (Shortly after this the museum director decided to use only LED lightning for the new wing that was going to be build.)
The problem of course is that we are so used to adapt our color vision to the lightning that most people do not see the difference. I guess that people who mix colors all the time, develop some kind of absolute color vision and do notice the effect of improper lightning on art works.
[1] https://www.pstruycken.nl/EnDyn.html?Li,tag=q&w
[2] https://www.pstruycken.nl/EnS14.html
[3] https://www.pstruycken.nl/EnS20.html