Don't get hung up on "14 year old". Pay attention to "took up origami 6 years ago". That's 6 years of passionate learning, experimenting and improvement.
Also, ‘years’ tend to be a lot more hours for kids, and each hour yields more learning due to neuroplasticity. I learned so much faster at 15 than I do at 35. I know more now, which often more than makes up for slower learning, but I can’t learn difficult novel subjects in depth as fast as I once did.
I’m glad I learned OS in depth during high school via Gentoo linux. And engineering/physics/math in college. It’s very easy to assimilate any new knowledge which can be understood through those areas of first principles.
But learning more advanced math is quite a task now.
Can you really say that unless you switched fields multiple times? Of course you'll pick up on math and physics faster in high school than in college or postgrad, but that's because the problems get way, way harder as you progress. I've found that even in my late 30s I can still easily pick up new skills outside my field of expertise as long as I start with the basics that could also be picked up by a high-schooler. I started learning a new language last year and thanks to modern study apps, I actually find it easier today. Of course it will still take a long time to become an expert, but I'm not sure it would need more total hours than if I had started 20 years ago. It just gets more difficult to allocate the necessary hours for learning.
> Can you really say that unless you switched fields multiple times?
I have ;-) far too many times! Even going back and taking undergrad math coursework that my engineering curriculum didn't have like Discrete Math or Statistics got a lot harder than calculus / differential equations was when I was younger. I felt like I got less out of each hour, and also couldn't put in as many hours - not just because I have more responsibilities, but also because my brain just gets tired after fewer hours.
Gentoo is what really made Linux click for me, too. I'm still very, very glad for that and remain a loyal user to this day!
Although I've had to restrict it to the 2 desktop machines. Maybe I should give it a shot again on the laptops, now that binary packages are universally available...
I don't know - i'm 33 ~ now - recently with AI learning is much easier - don't get me wrong I definitely won't say that the brain does not slow down - but I'd definitely argue that we have advantages over kids - be it discipline, knowing how to learn ; and stuff like that - for example let's take coq which is I suppose one of the hardest thing we can learn - you can decompose it in ways myself as a kid or as a 20yo wouldn't even be able to. What I mean is that there is a lot of complexities or stuff i would get stuck upon that I just fly over today and know I'm alright - much better ability to focus in a sense
Also don't get hung up on "folded". He hasn't innovated a design (it was invented by a Japanese astrophysicist, Miura-Ori), merely measured sustainable load across different designs.
Don't get hug up on "invented". Ruth Asawa registered for (1956) and received US patent 185,504 on June 16, 1959 at the suggestion of her professor, Buckminster Fuller.
> isn't this more a trait of autism than anything else?
No. It’s a sign of drive and discipline.
The latter, specifically the focus element, overlaps with autism. But more broadly it does not. (There are a lot of impressive teenagers applying themselves diligently to impressive ends. Most of them are not on the spectrum, though I suspect mild autism is slightly over-represented in that set.)
You're assuming that autism is always going to be a disadvantage. In fact, the obsessive focus mirrors scientific practice. Good luck to him, I respect him.
The key here is scale. What works in inches often falls apart at feet. The structure is holding about 33 psi over the area (which is rigidly supported from below), much more along the contact edges. By comparison balsa wood can support significantly more pressure (varies, but well over 100psi) but doesn’t concentrate pressure on edges.
Is there anything useful about this? Maybe as an inexpensive(?) core for high strength skins?
Directly: no, the end of the article has a nice list of reasons why, somewhat hidden
(ex. "Actual shelters...need to respond to multidirectional loads" = these were tested with load in one direction)
Miles, if you're reading this, it's useful. You're already doing what .1% of people do. I call them journeys and emphasize they're a million steps without clear direction, and if you're lucky, maybe positive feedback along the way. You're just on step N < 1,000,000. This works out, in some way, you already know it's not literally "yes this is sooo useful that we should start autofolding it at 1000x scale". It will work out. maybe as exactly this, this with some tweaks, or the $25K helps you do $X, or the publicity helps you do $Y.
> The key here is scale. What works in inches often falls apart at feet
Does that mean we could increase the orders of magnitude if we made it smaller? Lots of tiny stuff needs mechanical support. And lots of folded small things agglomerated is another way to say biology.
Closer to "mineralogy", plenty of things are both smaller and tougher (on this "support its own weight" metric) than cells or proteins with their squishy folding rules.
Even if we include things like hydroxyapatite in teeth, or even lignin, those are more like byproducts of biology than active biology itself.
I remember cutting an IKEA desk top down one side and discovering the inside was just corrugated cardboard under a few layers of laminate. it was trivial to break by shearing it but in a typical construction where the weight is mostly up/down it was obviously sufficient - until you cut the rigid sides off that is...
While this probably does have incredible Z-axis strength, I can't imagine it being very strong with any kind of lateral loads.
Does this shape hold up good weight distribution properties when 3D-printed? Maybe this could be huge for 3D-printing mostly hollow, yet strong parts that require in fewer plastic and time spent.
I wish the parents could be given a bit of credit. Instead we pretend the kid was doing this all solo... Its way less impressive when the parents are guiding them.
But the parents are doing lots of unappreciated work here.
> It's ok to say this has no practical uses but is very cool.
Agreed. But it doesn't go viral as much. Every cool robotics research goes with a comment that says "it could be useful for disaster response in a post-apocalyptic world where the conditions have changed in such a way that only my robot can save us".
This is weight distribution on a flat plain. Think of Roman Arches.
On a curved plain, weight distribution of THIS origami falls apart as pressure is added horizontally (not just vertically).
It looks like the top 10% from 6th to 8th grade Society of Science fairs are invited to participate. They are then selected down to a top 300[1] and a top 30.[2] You can find a project name for the top 300 and a paragraph on each of the top 30.
These teen science fair winners almost never amount to anything exceptional, and are a product intense parental supervision. Most universities have wised up.
Sometimes, but I do find his story inspiring. He has taken an age old craft and demonstrated it may have practical applications. I hope he can patent some design based off this and then he can make some money off it. (Yes, I know he didn't invent this particular fold.)
> Yes, I know he didn't invent this particular fold
So how could he patent it?
I join the parent: it's a kid who empirically evaluated how much weight an existing fold can hold. It's not like he solved a hundred years old mathematical problem.