Seeing as how Christmas is around the corner, I thought you guys might enjoy a quick video on how to wrap a rather intangible gift: a random distribution of points.
This was actually an incredibly fun code to write / I love Chan's algorithm. It's one of the most beautifully simple yet clever ideas I have seen in a while. Of course, I say that about every algorithm, so who knows when I'm telling the truth!
Anyway, thanks again for popping in and watching / I'll see you next time!
The music came from Josh Woodward (sped up 1.5 times):
https://www.joshwoodward.com/
Please feel free to follow me on Twitter:
https://twitter.com/LeiosOS
Twitch (where I do all the simulations):
https://www.twitch.tv/simuleios
My second youtube channel (where I put the streams):
https://www.youtube.com/channel/UCFf6...
or Github:
https://github.com/leios
The code I used is available here:
https://github.com/leios/simuleios/tree/master/gift_wrapping
(sorry it's so messy)
Also, discord:
https://discord.gg/Pr2E9S6
...
https://www.youtube.com/watch?v=ZnTiWcIznEQ
Working on the Fractal Animation Engine! https://www.leioslabs.com/Fae.jl/dev/
Discord: https://discord.gg/QctJhUA
Github: https://github.com/leios
Music: https://www.joshwoodward.com/
...
https://www.youtube.com/watch?v=OniK0mzVzcY
Be sure to check out my twitch channel, simuleios (5 - 7AM JST):
http://www.twitch.tv/simuleios
And, of course, the github repo where this was coded up:
https://github.com/leios/simuleios
... And the site this is now hosted on:
http://leios.github.io/
Outside of that, there are a few things I would like to mention about these simulations:
1. Some of the simulations shown for diffusion were actually truncated simulations of other Maxwell demon simulations. If it seems like some of the particles were bouncing on the interior wall when they shouldn't have been... well, I am sorry about that! Also note that none of these simulations truly reached equilibrium. Sorry. I didn't let the simulations run long enough!
2. Let me know if you want to see me actually coding this up on simuleios. I will add a maxwell's demon playlist filled with unlisted videos of the process, if you want!
3. Let me know if you have any further questions. Seriously, I love hearing them!
Want more information and my answers are not good enough? Well, there's always wikipedia:
https://en.wikipedia.org/wiki/Maxwell%27s_demon
Wanna contact me in 140 characters or less?
https://twitter.com/leiosos
And... I think that's about it. Thanks for watching and I'll see you next time!
PS: All the background music can be found on this site: http://www.joshwoodward.com/
(Josh Woodward is a great guy!)
Also, discord:
https://discord.gg/Pr2E9S6
Some of the animations (previous work) can be found here: http://www.lanl.gov/projects/dense-plasma-theory/more/movies.php
...
https://www.youtube.com/watch?v=5niDIoptyIU
Here's a video describing a simple method to solve Newton's equations of motion. More info can be found here: https://www.algorithm-archive.org/chapters/physics_solvers/verlet/verlet.html
If you want to contribute, here's the github repo: https://github.com/algorithm-archivists/algorithm-archive
The music came from Josh Woodward (sped up 1.5 times):
https://www.joshwoodward.com/
Please feel free to follow me on Twitter:
https://twitter.com/LeiosOS
Twitch (where I do all the simulations):
https://www.twitch.tv/simuleios
or Github:
https://github.com/leios
Also, discord:
https://discord.gg/Pr2E9S6
Also: Special thanks to butt4cak3 for the thumbnail!
...
https://www.youtube.com/watch?v=g55QvpAev0I
Guys, this is amazing! Let me know if you agree in the comment section!
Seriously, though. Euclid's Orchard somehow snuck up on me while browsing wikipedia and I fell in love with the concept! I hope you can see why.
Anyway, thanks so much for watching and I'll see you next time!
The music came from Josh Woodward (sped up 1.5 times):
https://www.joshwoodward.com/
Please feel free to follow me on Twitter:
https://twitter.com/LeiosOS
Twitch (where I do all the simulations):
https://www.twitch.tv/simuleios
My second youtube channel (where I put the streams):
https://www.youtube.com/channel/UCFf6...
or Github:
https://github.com/leios
The code I used is available here:
https://github.com/leios/simuleios/blob/master/euclid/euclid.cpp
(sorry it's so messy)
Also, discord:
https://discord.gg/Pr2E9S6
...
https://www.youtube.com/watch?v=2dWxS8-HicQ
Algorithm Archive chapter: https://www.algorithm-archive.org/chapters/principles_of_code/building_blocks/bitlogic.html
If you want to contribute, here's the github repo: https://github.com/algorithm-archivists/algorithm-archive
I realize that this information might be a little basic, but it's a necessary stepping stone for the future!
The music came from Josh Woodward:
https://www.joshwoodward.com/
Please feel free to follow me on Twitter:
https://twitter.com/LeiosOS
Twitch (where I do all the simulations):
https://www.twitch.tv/simuleios
or Github:
https://github.com/leios
Also, discord:
https://discord.gg/Pr2E9S6
...
https://www.youtube.com/watch?v=zMuEk44Ufkw
Ever want to find the greatest common divisor of two numbers? Here's a way to do just that!
Chapter in Algorithm Archive: https://www.algorithm-archive.org/chapters/euclidean_algorithm/euclidean.html
If you want to contribute, here's the github repo: https://github.com/algorithm-archivists/algorithm-archive
The music came from Josh Woodward:
https://www.joshwoodward.com/
Please feel free to follow me on Twitter:
https://twitter.com/LeiosOS
Twitch (where I do all the simulations):
https://www.twitch.tv/simuleios
or Github:
https://github.com/leios
Also, discord:
https://discord.gg/Pr2E9S6
...
https://www.youtube.com/watch?v=h86RzlyHfUE