Author |
Topic: How Many Triangles (Read 742 times) |
|
william wu
wu::riddles Administrator
Gender:
Posts: 1291
|
|
How Many Triangles
« on: Feb 16th, 2003, 3:55pm » |
Quote Modify
|
Source: Macedonia Mathematics Olympiad, 1997 Given some integer n, how many non-congruent triangles are there whose sides are all of integral length and less than or equal to 2n?
|
|
IP Logged |
[ wu ] : http://wuriddles.com / http://forums.wuriddles.com
|
|
|
Eigenray
wu::riddles Moderator Uberpuzzler
Gender:
Posts: 1948
|
|
Re: How Many Triangles
« Reply #1 on: Apr 25th, 2003, 12:16am » |
Quote Modify
|
We count the number of ordered triples (x,y,z) such that: 1<= x <= y <= z <= 2n x + y > z <-> x > z-y <-> x >= z-y+1 This is "simply": sum_{z=1}^{2n} sum_{y=1}^{z} sum_{x=z-y+1}^{y} 1 Note that the last sum vanishes unless y >= z-y+1, i.e., y>=(z+1)/2. Thus we get: F(n) = sum_{z=1}^{2n} sum_{y=ceil[(z+1)/2]}^{z} (2y-z) = sum_{z=1}^{2n} G(z) If z=2k is even, G(z)=G(2k)=sum_{y=k+1}^{2k} (2y-2k) = sum_{m=1}^{k} 2m = k(k+1) If z=2k-1 is odd, G(z)=G(2k-1)=sum_{y=k}^{2k-1} (2y-2k+1) = sum_{y=k+1}^{2k} (2y-2k-1) = G(2k) - k Then F(n) = sum_{k=1}^{n} G(2k-1) + G(2k) = sum_{k=1}^{n} 2k(k+1) - k = sum_{k=1}^{n} 2/3*[(k+1)^3-k^3 - 1] - n(n+1)/2 = 2/3*[(n+1)^3-1 - n] - n(n+1)/2 = ( 4n^3 + 9n^2 + 5n ) /6 = n(4n^2+9n+5)/6 = n(4n+5)(n+1)/6
|
|
IP Logged |
|
|
|
|