Non-photo blue(en.wikipedia.org) |
Non-photo blue(en.wikipedia.org) |
"""
The reason older photocopiers don't copy blue is very simply that the drum was activated by reflected light from the scanner. The chemical process that creates the "semiconductor" on the drum surface is sensitive to a fair proportion of the light spectrum, but frequently lost sensitivity t the blue portion of the range. Organic photoconductors had a better response to blues but still cut off a portion of the spectrum. Newer Photocopiers (Digital) operate differently and are dependent on the frequency range of the CCD in the scanner, they are usually pretty good at the blues, and frequently have settings that enable Text enhancement, enabling a setting of a contrast point, anything darker than that point is registered as black anything lighter as white.
"""
In practice the original was about as much a pain to read as the photocopy.
EDIT: I remember the letters in the copy having a sort of lighter colour halo around them, which made it readable. I figured was due to the blackness of the letters pulling the limited amount of toner towards them...
It sort of reminds me of the old graphics method of using RGB(255,0,255) for sections of a sprite that should be transparent, since an alpha channel wasn't an option, because it's such a hot pink and such a precise color it would never naturally appear in artwork.
https://en.wikipedia.org/wiki/International_Klein_Blue
Also I fondly remember Hubertus Bigend's IKB suit…
Is there a spectral notch filter applied to the CCD, or is the article a troll?
"Scanning in black-and-white makes it possible for the non-photo blue still to serve its original purpose, as notes and rough sketching lines can be placed throughout the image being scanned and remain undetected by the scan head."
Any black-and-white scanner should have a spectrally-flat response, picking up blue just as black and white photographs see the sky as darker than white.
It's entirely possible that older lithographic film didn't have much response in the blue, but there's really no way that a modern imaging system won't pick it up.
What am I missing?
Edit: Experiment is the arbiter of truth: I took a picture of the screen with my digital SLR. As expected, every color swatch in the article is blue. Desaturated the RAW image. Looks grey.
The old printing press easily took up half of our little room, and old supplies still littered the shelves and floor. I loved digging through papers (we had copies dating back to the first half of the 20th century) and learning tidbits about the old way of doing things. The rest of the workers had been there 30+ years and would reminisce about late nights spent pasting strips of paper with text and images onto a board, annotating it with a pen that wouldn't show up, taking and developing the photographs, and running the press.
I don't really have anything to contribute, but it's cool to see this pop up on here and learn a little more about it.
If that's correct, you're close(r).
The goal was to compose a layout into a single image.
You created a layout by literally cutting and pasting things onto a board. Then you placed that board in the area at the bottom and took a picture of it that was transferred to film loaded in the top.
You're right that the film was special; but it's the other way around from how you were thinking. The film was not sensitive to red light. To this film, red is "black" and cyan or blue is "white".
Why this was useful:
- You could open the box of film (it came in sheets) in a room that was darkened except for a red bulb, without exposing it.
- You could use overlays of transparent red material (rubylith) to mask things precisely. Even though you could see through to the layer below, the camera would see it as all black.
- And, as the article mentioned you can add notes to the layout with blue pencil and it would be invisible to the transfer. We always called this "non-repro blue" though, as in, the camera wouldn't reproduce it.
-- Litho film was also very high contrast so everything pretty much came out black or white. (Photos weren't actually reproduced as greyscale but rather as a set of larger or smaller black dots using a halftone screen. This still applies when things are printed.)
-- Because litho film was sensitive to blue, the non-repro blue writing on the white paper would, like the white itself, be an exposed part of the image. This results in a black area of the negative where silver halide has been turned into metallic silver. This black area would then become white again when the negative was used to create a printing plate.
For instance, red would not activate the paper commonly used for black and white prints, hence the red lights in dark rooms.
It is also possible the cameras illuminated the artwork with a light to which the non photo blue ink was transparent.
I don't know how these pre-digital reproduction systems excluded the blue, nor to I know if this system is still in use in the digital era.
[Edit: As someone wrote, the article just seems confused. Yeah, you can adjust a digital B&W image so that a light blue goes away. You can also adjust it so a light yellow or a light anything goes away. Digital sensors do have different wavelength sensitivities but the use of non-repro blue and rubylith were a function of the specific sensitivities or lack thereof of litho film.]
The article seems confused - it's implying that there is some magic shade of blue that cameras can't see (even today), which is totally wrong. I think that's why someone found it interesting to post here.
I've stuck with blue as the only highlighter colour I'll ever use, more than 20 years since the original rationale.
Also, used to freak people out scribbling (non-repro) obscenities on a flat that was going to be sent to photo and turned into a newspaper the next day.