Taken on a small group of Islands in the Oslo fjord, called Hvasser. A 15 meter peice of fabric playing in the wind, scanned right to left in 21 seconds. Got really lucky with the clouds this time, allowing a single beam of sunlight in as a highlight.
Thank you!
The n650u looks very similar to the lide 30, so I’ll assume that it’s more or less the same inside.
The sensor assembly is fairly straightforward. A plastic housing that gets pulled by a cord. Once you liberate the assembly from its track/cord/whatever is holding it and moving it around, you get to the good part.
The sensor itself, and the RGB LED that supplies the light is on a PCB that’s mounted to the plastic carriage from the underside, it’s held together by plastic tabs (it’s a few years since I did this, so the details might be off, but it wasn’t a difficult task). Use a sharp utility knife to cut the tabs and remove the sensor PCB. I’ve used strips of gaffers tape to put it all together again. The LED looks like a small white rectangle stood perpendicuar to the PCB, I simply broke it off. This makes the canon drivers throw an error, but VueScan doesn’t care. If you’re squeamish about actively destroying your scanner, you can probably figure out a way to cover it up with some tape or foil.
The circular vignetting you’re seeing is due to the pinhole array, it’s a thin black plastic strip with a bunch of tiny holes set in front of a slit, just rip it off, its either glued or welded in place, but I’ve never had a problem getting it out with some pliers. While you’re messing about in that area, get rid of the prism that spreads the light from LED as well, it probably won’t do much of anything if left in, but it feels better to remove it.
Once you run the camera in this state, you will discover that you get uneven exposure from edge to edge, a linear vignette perpendicular to the axis which the sensor moves. This happens because the plastic housing of the sensor is throwing shade. So use any available abrasive machine, and cut that housing down to its essential functions of holding the sensor in its place, and as a pressure against the glass plate.
Unfortunately I don’t have any large format lenses around, so I’ve stuck a magnifying glass to the front of my camera (you know, gotta keep it punk rock), but the way I handle aperture is by cutting holes into black cardboard (very thin cardboard) at about the size I think will work, and taping the hole across the lens. One of my goals with this project is to try make photography into a tactile, direct and intuitive process so I try to avoid unnecessary machinery.
The reason you’re only getting grayscale is due to how a CIS scanner renders color. During a normal scan, the RGB LED only flashes one channel at a time, and the driver figures out if it’s looking at the red, green or blue signal all by itself, and at the end it interpolates the data to render a full color image file for you to enjoy. I’ve been playing around with the idea of tapping the signal path and use it to trigger an external RGB lighting rig in a studio, to get full color images of models. But so far it’s only a funny thought!
And lastly, the sensor is exceptionally sensitive to infrared light, to the point that the heat from the internal electronics of the scanner causes streaking. I’m using a few pieces of carefully placed aluminum foil to shield the sensor in select areas, and that reduces the issue to a tolerable amount.
Good luck on your build! This project has given me a boatload of insights into both photography, electronics and computing, and I hope you will have a similarly awesome journey.
Edit: im happy to answer any further questions you might have. it would be awesome to see some shots once you get the contraption up and running!
Wow, that is all very valuable information, thank you. I feel a lot more confident attempting the surgery on the electronics now.
I had a thought about going from bw to colour. If should be possible to capture the same scene 3 times, each time with a different colour filter in front of the lens. Then merge the 3 images together as colour channels in Photoshop or similar. The filters will reduce the amount of light picked up by the sensor, which will help a bit on bright sunny days, but will require more light in a studio. Also, in a low light situation, it could be possible to capture a fourth scan with no filter, and use it for brightness information. I’m not exactly sure how to do that, but I know some cellphones use that trick.
Edit: But I also like your idea of tapping the signal to trigger external lighting.
What you are describing is known as a harris shutter, which would be awesome to explore, especially considering the weird way motion is captured on one of these devices.
I don’t think a separate brightness channel is entirely necessary. But if you want to go down that path, I’d start trying out the blending modes in photoshop. There’s probably also some method for taking your RGB composite, and bring it into a colorspace that has a separate channel for brightness, and then replace that channel with your b/w pass. Lab color space should allow you to do this, although I’m not really sure what software to use, or if theres some way of doing This directly in Photoshop.
I have photos to share:
—=== About the rig ===—
I’m using the vertical slider from an old enlarging machine to mount the lens on, because it lets me set the focus. I put a sheet of paper on the glass to focus on, then I remove the paper to capture the image. There’s a small gap between the sensor and the glass, so it’s not perfect.
And since the lens points straight up, there’s a mirror on top which can point to any direction. It looks like a cheap nasty plastic mirror, but the glass is very good quality.
I’ve looked into modifying the scanner, but it’s very challenging. I got as far a lifting the scanner head off the monorail before just putting it all back together. I’ve since picked up another scanner which I intend to modify. It’s much older, so I won’t feel bad if I accidentally destroy it.
—=== About lenses ===—
I used two lenses for these photos.
The first one is a 178mm/1.9 Kaylee Bloomed Projection Lens. The front element is 94mm in diameter. I believe it was designed to project from 70mm movie film. Someone has written the label “Cinemascope #2” on the side. I assume whoever wrote that knew what they were doing. When I bid on the auction, I was hoping it would be an anamorphic lens. It isn’t, but it is still a very special lens that I’m trying to make use of. Originally I built an adapter to fit my 5d mark1, which works very well, but the full frame sensor crops out a lot of the original image circle… and most of the swirly bokeh.
So the scanner back idea lets me capture the entire image circle for the first time. Admittedly it’s in black and white and, if I crop to a 3:2 frame, 1924x1297px. I’m looking into using a diverging lens to magnify the image circle.
The other lens is some kind of industrial lens that I don’t know anything about. I call it Big Red. I measured the focal length at about 200mm, and the image circle is massive. It basically covers the entire A4 scanner. It has a built in green pass filter that reflects red light back out thru the front of the lens which makes me suspect that it’s an interference filter, not an absorption filter.
—=== About photos ===—
2024.06.15 My first actual photo that wasn’t of a ceiling light or a ruler, was taken using the 178mm. I didn’t put a lot of thought into it, I was pretty much just testing the waters to see what kind of result I could get. I hadn’t even cleaned the scanner glass yet.
I wasn’t deliberately trying to capture motion, it just happened to be that the tree was swaying, and the power line was bouncing up and down in the breeze. If you look closely at the left of the frame, you can also make out two power poles on the skyline.
It was a bright sunny day, and my vintage light meter read 13ev with the shutter closed, which is nearly off the scale, so I had to place a stack of things on the front of the lens to reduce the amount of light enough that I didn’t get a blown out image. After some experimentation, I ended up with: an ND400 filter, and an adapter with a manual aperture set to about 14mm diameter… I’m probably going to have to buy some more ND filters if I want capture swirly bokeh, or be very selective with lighting conditions.
I used a random black cloth as a light shield. It’s thin and light, so it doesn’t put a lot of stress on the equipment, it works in low light situations, but in the bright sunlight, I had to stack sheets of cardboard in front of it.
Finally I cropped the image, rotated it, and since it was backwards, corrected it by flipping. And added the text.
2024.07.03 I took the camera to garden with the intention of doing some portraits. But it took so long to set up and adjust that I only managed to get photos of the garden, and the tower on Mt Kaukau. It’s much harder to work outside in the cold with the wind blowing the cloth, and it took so much concentration to see the laptop screen that I took all the photos at 50dpi, and forgot to set it back to 600dpi.
I have a fresnel lens that has a focal length of about 400mm, which I placed on the glass behind the main lens. It wasn’t as successful as I’d hoped. It does dramatically increase the area of the image that I can scan, but it’s still heavily vignetted in the corners. Also, the centers of the two lenses aren’t aligned. I intend to move the main lens out over the center of the scanner.
Thats quite the contraption! What an epic rig, and awesome shots! Thank you so much for sharing! What do you think is the cause of the moiree-pattern in the edges of some of them?
That’s caused by the fresnel lens. Its a cheap plastic one that I picked up at a craft store.
Cathode ray dude on YouTube just dropped a feature length video on scanners, you might find it interesting!
That was worth watching, thank you.