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Compactness #5
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Does anyone know if laser cut acrylic/PMMA would work to make a prism for a spectrometer? If so I can easily design an incredibly trivial-to-manufacture proof of concept for my "stacked" idea... Or would the PMMA only let through a certain spectrum in a way that would make this useless? |
Uuuuuuh... I just looked up what diffraction grating is on Wikipedia, and I think my rambling about was just re-inventing warm water. Sorry for the noise people. |
PySimpleGUI may compact the code if code length shortening is what's being suggested. |
Oh no, I mean ideas for more compact mechanisms/hardware. Like, the optics. LIke, you have this very long/bulky diffraction grating thing, and I was brainstorming ideas for things that would take less space/volume. |
There are shorter diffraction spectroscopes. I just ordered one that is 55mm long. i believe the one in the project is about 3x that long. You might be able to get away with running on a Pi Zero if you can accept a low framerate. Those are tiny. I have not tried this, it's just an idea. |
Cool! Let me know how you get on!
If you wanted to run on a Pi zero, you could always strip back the
interface, and just have an OpenCV Imshow frame.
Les
…On Tue, Apr 27, 2021 at 7:41 AM Jarrod Smith ***@***.***> wrote:
There are shorter diffraction spectroscopes. I just ordered one that is
55mm long. i believe the one in the project is about 3x that long.
You might be able to get away with running on a Pi Zero if you can accept
a low framerate. Those are tiny. I have not tried this, it's just an idea.
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I've got my eyes on this project. I would love to use it as a design pattern for "scope" projects using PySimpleGUI. There is at least 1 I know of now. I just don't have the ability to DO anything with it at the moment. Someday I'll be back to take a look at some of the features you've made. |
Schematic
Why do these have to be a (long) tube like this? Is there any way they could be made much shorter of a tube? Anyone has a schematic of how these work/function/are designed, so we can rack our brains for anything that could help shorten/make them more compact/take less volume or space in any way? Is this an accurate schematic of the kind of tube you have been using? ( image link ) If we can't reduce the length, can we reduce the diameter? Or can we reduce both diameter and length at the same time ("shrinking" the entire assembly altogether ?) Looking for any ideas that could make this more compact/transportable, become a tiny attachment/add-on for a smartphone or a pi zero's camera module. AngleMost schematics I can find for a diffraction grating spectroscope tube, have some kind of angle required in the design (see the image/schematic just above). Your tube is straight, no angle/change of direction from the light source being analyzed, to the actual sensor doing the measurement (CCD/CMOS etc). How is this? Why is this a thing? Existing designsI looked for "existing" designs that try to accomplish compactness, and did not find much. One is this product aimed at smartphones, with the end goal of use for gem analysis in the field: https://www.amazon.fr/GoSpectro-smartphone-Spectroscope/dp/B07KFJZW1Q// Also: Product page at the actual company rather than their Amazon shop And it's beefier cousin And an interesting write-up on those tools. Any opinions on the product, and in particular ideas of how the compactness is achieved / what the schematic for it would be? LearningI found this is also a pretty interresting ressource about diffraction grating, with a few very neat schematics. |
Beautiful.
I got a smaller one also, they are so tiny.
If I can source a smaller zoom lens for the picam, this would be sweet!
…On Sat, 1 May 2021, 19:05 Jarrod Smith, ***@***.***> wrote:
My tiny $30 diffraction spectroscope came today. A quick look through it
inspires some level of confidence that this little guy can work.
[image: IMG_3958]
<https://user-images.githubusercontent.com/52144433/116791108-bd63cb80-aa7d-11eb-8166-c79e7bab7077.JPEG>
[image: IMG_3959]
<https://user-images.githubusercontent.com/52144433/116791109-bdfc6200-aa7d-11eb-8155-fa986dc0a29a.JPEG>
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The diagram is more or less there.
After the slit, there is a collimating lens before the grating.
In the model I am using, there is also a prism of some description, so the
the output is in-line with the device. Hence the length.
Paton Hawksley do a miniaturised version as well, that I am looking into.
…On Sat, 1 May 2021, 19:18 Arthur Wolf, ***@***.***> wrote:
Why do these have to be a (long) tube like this?
Is there any way they could be made much shorter of a tube?
Anyone has a schematic of how these work/function/are designed, so we can
rack our brains for anything that could help shorten/make them more
compact/shorter?
Is this an accurate schematic of the kind of tube you have been using? image
link
<https://outsidescience.files.wordpress.com/2012/02/spectroscopediagram.png>
If we can't reduce the length, can we reduce the diameter? Or can we
reduce both diameter and length at the same time ("shrinking" the entire
assembly altogether ?)
Looking for any ideas that could make this more compact/transportable,
become a tiny attachment/add-on for a smartphone or a pi zero's camera
module.
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I think there are at least two things going on with the length. First, the light needs to be collimated. That is what's being depicted in your diagram where the white light travels for quite a ways before it hits the grating. It can occur via a lens with some focal length, or by a thin slit and a length of tubing, such that rays that are not perpendicular to the grating will eventually hit the sides of the tube and be absorbed. Second, there has to be adequate space for the differentially diffracted rays to resolve into a pattern that's wide enough to produce a spectrum you can resolve into its individual components. See the triangle produced by the diffracted rays in your diagram. The base of that triangle determines the resolution, and is related to the distance from the grating. |
@MakerMatrix Thanks for the great explanation! My naive understanding is that I can just miniaturize this (make everything 4x smaller), and with the correct lens at the entry, and the correct lens at the exit, have something functionally identical, but (nearly) 4x smaller (not exactly 4x smaller since the entry/exit lenses take room too). Is that wrong? I found an optics simulation thing the other day, I'll try to test my hypothesis in there. |
If you can find a collimating lens with a very short focal length, perhaps. I'm not an optics expert but this person is: Edit: what we are discussing here is running her experiment in the other direction: a non-collimated light source on the opposite side of the lens, producing collimated light on the other side, at |
Side comment: In my way of thinking, the tube needs not be shorter than the longest dimension of the Pi itself. At least if you are talking about making a standalone version (which is what I plan to try). I'm thinking of putting it together in such a way that the camera is on one end of the pi, lined up with the tube, which is over or under the Pi. If you can manage that, the entire thing need not have a footprint any larger than the Pi. This little spectroscope I showed is just over 1/2 the length of the Pi 3/4 boards. |
@MakerMatrix My goal is mostly that I'm curious about what the ultimate/maximum compactness that can be achieved here is. Maybe it'd be useful if this could be made into a very compact attachment to a smartphone too (not necessarily using the smartphone's camera either) I think there is value in discovering ways to make this more compact, if we can discover any. Maybe value we don't currently know what to do with/about, but that others reading this later will have ideas about / uses for. Making things smaller tends to be a good idea, in general, technologically speaking. |
i would trade size for better accuracy. Size is not something i particularlly am worried about. |
Really awesome project!
This is huge (in terms of volume).
I think this would be much more useful as a tool, if it was much more compact (say if you could have this easily added to a trichorder etc).
Does anyone reading this have any idea how it could be made more compact?
The internet has some designs for compact spectrometers, but I would be interrested in something even more compact if possible. You can see one such design here for example: https://img.laserfocusworld.com/files/base/ebm/lfw/image/2016/01/1305lfw01f1.png?auto=format&w=720
Could a prism be used instead of the diffraction grating? That sounds like it could be made more compact then.
A very small motor could be used to move (rotate) the prism about if needed, there are minuscule stepper motors around, and I can help with finding and interfacing those if required.
The design of this project (PySpectrometer) looks a lot like this one, am I correct in my understanding there? https://www.hamamatsu.com/sp/ssd/product/Spectrometers/img06_en.png
Stacking mirrors also might have potential by increasing the number of reflections (still using only two mirrors) and therefore widening the prism/spectrum effect: https://media.springernature.com/m685/springer-static/image/art%3A10.1038%2Fs41467-018-06495-5/MediaObjects/41467_2018_6495_Fig1_HTML.png
Something like this has a similar concept to what I'm describing here : https://www.researchgate.net/profile/Manuel-Cano-Garcia/publication/338279737/figure/fig1/AS:845739789938690@1578651487502/Schematic-draw-of-the-proposed-spectrophotometer-An-Arduino-stage-drives-all-the.png but I would think it might be possible to make this even much more compact somehow ... just racking my brain for an engineering solution and have not found one yet. Curious if somebody else reading this would have an idea.
Maybe it could be possible to take advantage of the fact that we have a 2D sensor (instead of the strictly 1D sensor we actually need for spectra), by having several different prisms stacked on top of each other, creating different lines hitting the sensor on top of one another. This should be relatively easy to manufacture: it is simply a pile of flat panes of glass, on top of one another, with their entries and exists at different/varying angles (and presumably an opaque sheet of something between each layer). I can create a schematic of this if somebody is interrested and/or my description is not clear enough. It would also be very easy to make this very precise, by having two (or more) holes in each pane/plate/prism, and have a "pin" go through all of the holes in the stack for each series/stack of holes, thus ensuring perfect alignment of the prisms.
This way, you would get on your sensor, a series of spectrum lines on top of one another, giving you a 2D array of spectral points instead of a line/1D array of such.
I hope I'm not saying anything too stupid...
Maybe it's not stupid: I found an image that looks like that idea: https://www.osapublishing.org/getImage.cfm?img=dTcqLmxhcmdlLG9lLTI2LTE1LTE5NDU2LWcwMDE
The interresting thing/goal of what I describe here, would be that it would be very compact, which is the objective/what I created the issue for. But if anyone else has any idea of how to make things more compact, I would be very interested to hear about it (I need very compact spectrometers to identify materials on an automated recycling/sorting CNC machine)
Sorry for rambling about this, I hope I'm not disturbing anything, I'm just trying to get a conversation going.
Cheers!
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