… am I the only one who learned 1+100, 2+99… to make 101 times 50 pairs? Lmao feels like it’s much easier. 101 × 50 = 5050
poggers
Submitted 11 months ago by fossilesque@mander.xyz to science_memes@mander.xyz
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Comments
LordGimp@lemm.ee 11 months ago
boeman@lemmy.world 11 months ago
I’d say it’s fifty-fifty.
0ops@lemm.ee 11 months ago
The math is the same, you just wrote it more “casually”. For me it was 0+100, 1+99, 2+98 … 49+51 -> 100 x 50 = 5000, then add the 50 that was missed from the middle for 5050. But yeah I remember coming up with that when I was really young.
nova_ad_vitum@lemmy.ca 11 months ago
Sorry if this is stupid but how to deal with sums to odd numbers ? Won’t you have a number left over after pairing all the others?
LordGimp@lemm.ee 11 months ago
Add the last number onto the end. So the sum of all numbers between 1 and 101 is 50 pairs of 101 plus one extra 101 and the end. It’d end up being 5050 + 101 or 51x101 or 5151
0x0@lemmy.dbzer0.com 11 months ago
Nope, because what you’re doing is copying the entire sequence, reversing it, and pairing up each element left to right. There’s no way to have any leftovers because the original sequence and the new reversed sequence have the same number of elements.
A perhaps less intuitive way of thinking of it is you start with a sequence of 1 up to N, which contains exactly N elements. The sequence from 1 to N and its reverse together contain 2N elements, which is by definition an even number, regardless of whether N is even or odd. Because it’s even we can break it into pairs without leftovers.
KISSmyOS@lemmy.world 11 months ago
Ah yes, because the goal of teachers is to make their students waste a lot of time.
Bashnagdul@lemmy.world 11 months ago
Well, it does happen
Johanno@feddit.de 11 months ago
In this case it probably was
computerscientistI@lemm.ee 11 months ago
I always thought like that:
Hmmm: 1 + 2 + 3 + … + 99 + 100
Kommutativgesetz be like: This equals:
100 +1 + 99 + 2 +98 + 3 . . . And this equals: 101+ 101+ 101+ . . .How often do I need to do this? I use up 2 numbers for each 101. I have 100 numbers total. So that’s 50x101.
Now you can think about: What if it’s 1000 instead of 100? But it#s easy from here…
Asafum@feddit.nl 11 months ago
This is why I never succeeded at math. Like why does this shit work?? How can people just take a problem and be like, nah I’m going to just throw numbers all over the place and reassemble them in all sorts of ways and get an answer somehow…
I can’t just memorize arbitrary nonsense that “just is” I need to know how it works or it never sticks and all the math I’ve ever been taught was just “memorize this arbitrary nonsense and regurgitate a specific formula for a specific application that we’ve spent 0 time explaining other than telling you to memorize it. You want proofs and you can’t get proofs until advanced college courses” well guess I’ll just never understand mathematical manipulation then…
I feel like 50/50 school failed me and I failed at math.
nova_ad_vitum@lemmy.ca 11 months ago
The rules underpinning math are axioms in the end, but they’re not completely arbitrary, because if you change them in most cases it just fucks everything up.
The axioms that were chosen were chosen for good reason, and the rules they result in (such as summation and multiplication being commutative so 3x4=4x3 and 3+4=4+3) allow more complex rules to be created.
There’s a lot of philosophy of math at the core of all this , but it’s not really true that this is all arbitrary.
Rediphile@lemmy.ca 11 months ago
It’s not arbitrary. Really try to think about the problem at hand. The ‘why’ is quite apparent. Ask yourself why did they go with 99+1+98+2… in the first place? And why is that the same as 101+101…? What was the benefit of simplifying it to that? How did it save the student time?
You can deduce this yourself and literally no memorization is involved to figure this out. No formulas needed either.
rasensprenger@feddit.de 11 months ago
Once you have the idea, seeing that it works if often easy. But coming up with ideas like that can be really hard, which is why gauss was the only one in his class who got it. There is no general method, you just have to think about stuff for a while, but you can get better with practice. And it feels really good when you prove something for yourself, even if it’s relatively straightforward. You can just try to prove some simple things yourself, if you want, the advanced college courses are just for proving really advanced stuff.
TserriednichThe4th@lemmy.world 11 months ago
Look up how to solve it by george polya
sj_zero 11 months ago
It's just a matter of breaking the problem down Into an easier problem or set of problems.
All the additions are interchangable, so you could choose to add 1+2+3+4 or 4+1+2+3 and then 4+1=5 and 2+3=5 and then youve got 5+5 which is easy its 10. So you go ok you can do the conversion with 1 and 50 except it's still tough mental math so you say 1 and 100 to get 101 100 times, but that's twice too big so you slap it in half and you get the answer. It's solving a tough problem by splitting it into problems that aren't as tough.
The first step is knowing what tools you have in your belt. The second is knowing how they work in detail. The third part is the inspiration of using them in a way that solves a difficult problem.
I'm not a mathematician, but I've found interesting solutions to problems like this before, and it's fun when you understand your tools and understand the problem and it all comes together to find a solution nobody else would have.
troyunrau@lemmy.ca 11 months ago
I’m a spatial-visual person, so when presented with this problem as a teenager, I instead solved it spatially. If you stack squares like.
█ ██ ███ … To the hundredth row, you get a shape that is a half filled square that is 100x100. Except the diagonal is fully filled in, so you need to add another 50.
So the answer was 0.5x100x100 + 0.5x100. Easy to visualize, easy to solve. 5050.
There’s a similar problem in sports – I was a teaching assistant for our rural school’s gym class so this one also popped up for me as a teenager. If you have 100 teams and each team needs to play each other team once… You fill in a similar grid, with the teams on both the x and y axis. The diagonal gets removed in this scenario because a team cannot play itself. So the answer is 0.5x100x100 - 0.5x100. 4950. Anyone who has ever tried to plan any sort of tournament can probably solve this intuitively, but 25 years ago I though I was the smartest gym class teaching assistant ever ;)
nova_ad_vitum@lemmy.ca 11 months ago
The algorithm gets a little weird if you’re summing the numbers to an odd number, though since there will be a left over number you have to deal with . By calculating 2S it works exactly the same in either case.
Ibex0@lemmy.world 11 months ago
Ohhhhh
SnipingNinja@slrpnk.net 11 months ago
Can also be called a programmer move
Chakravanti@sh.itjust.works 11 months ago
Not a good one.
idiomaddict@feddit.de 11 months ago
Bettter than a regular grammer move
jtk@lemmy.sdf.org 11 months ago
[deleted]mycus@kbin.social 11 months ago
picture a square that is n times n, grid size 1. cut it diagonaly, you have n²/2, but that leaves out the bunch of triangles that are 1/2 each. how many of these triangles are there? n.
so we are left with n²/2 + n/2.
which is (n² + n)/2.
which is n(n + 1)/2.
Blue_Morpho@lemmy.world 11 months ago
Is it required to wear a silly hat to be a genius mathematician? I’ve seen Euler and his hat. But I didn’t realize Gauss was in it too.
doctorcrimson@lemmy.today 11 months ago
Legends say Sir Isaac Newton never found a hat to fit over the glorious wig.
Kanda@reddthat.com 11 months ago
A Wig is actually just a terribly silly hat
wrath_of_grunge@kbin.social 11 months ago
I never made it far enough in math to understand this.
stevar@lemmy.world 11 months ago
I’ve always seen it explained as (100+0) + (99+1) + (98+2) + (97+3) + …
So you basically have 50 pairs of numbers that all equal 100. So 5000 right? But there is one number that doesnt have a pair to make 100. Which is 50. Obviously there arent two 50s to make 100. So its added by itself. 5050.
Its the same as the summation of 1 to 10. (0+10) + (1+9) + (2+8) + (3+7) + (4+6) + 5. Its 55.
0ops@lemm.ee 11 months ago
This is how I used to think about it too, back when I didn’t even know what a natural number was
Fal@yiffit.net 11 months ago
Addition?
veganpizza69@lemmy.world 11 months ago
There’s a nice book about this: www.goodreads.com/…/57007645-thinking-better so you can learn.
I… haven’t read it yet, but it’s on my list. I’ve only listened to some interviews with the author about it.
mvilain@kbin.social 11 months ago
I thought it was Euler that did this. But I can imagine Gauss doing it too.
KISSmyOS@lemmy.world 11 months ago
Granted, it’s usually a good bet that Euler did it.
mexicancartel@lemmy.dbzer0.com 11 months ago
Ahh because Euler did everything
criitz@reddthat.com 11 months ago
Mathologer has a good video on this topic youtu.be/fw1kRz83Fj0?si=_j46BoZHHfcatYnu
jxk@sh.itjust.works 11 months ago
Seeing this meme gives me flashbacks to the 10 Deutschmark bill (I think that was the one)
chitak166@lemmy.world 11 months ago
Just put it in the calculator.
someguy3@lemmy.world 11 months ago
That seems complicated.
Average is (100+1)÷2= 50.5
50.5 average x 100 numbers = 5050.
agamemnonymous@sh.itjust.works 11 months ago
You did essentially the exact same thing in a different order.
(100+1)÷2 × 100
(100+1)x100 ÷ 2
0ops@lemm.ee 11 months ago
Clever though
Vent@lemm.ee 11 months ago
I think you’d need to prove that the average is (100+1)/2 because that’s not an axiom.