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Difference between revisions of "1996 OIM Problems/Problem 1"
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<math>V=\sum_{i}^{}2^ik_i=13^3</math> where <math>k_i</math> is the quantity of cubes of edge <math>i</math>, Hence, we want to find solve this equation for <math>k_i</math> with <math>\sum_{i}^{}k_i=1996</math>
 
<math>V=\sum_{i}^{}2^ik_i=13^3</math> where <math>k_i</math> is the quantity of cubes of edge <math>i</math>, Hence, we want to find solve this equation for <math>k_i</math> with <math>\sum_{i}^{}k_i=1996</math>
 +
 +
Starting with <math>k_1=13^3=2197</math> with 201 cubes left we find that <math>201=(25)(8^3)+1.  So, we can make 25 cubes of edge 2.  If we set </math>k_2<math>=25 we need to subtract 200 from </math>k_1<math> and our numbers are now at: 
 +
 +
</math>k_1=1997<math>, </math>k_2=25<math>, </math>\sum_{i}^{}k_i=2022<math>.  So we still have 26 cubes more than we need.
 +
 +
So we can take 27 cubes of edge 1 and combine them into one cube of edge three and our new numbers are:
 +
 +
</math>k_1=1970<math>, </math>k_2=25<math>, </math>k_3=1<math>, </math>\sum_{i}^{}k_i=1970+25+1=1996<math>.  And this proves that we can divide a cube of edge 13 into 1970 cubes of edge 1, plus 25 cubes of edge 2, plus one cube of edge 3.
 +
 +
Since smallest </math>n>12<math> and </math>n=13<math> is possible then smallest possible </math>n$ is 13.
  
 
~Tomas Diaz. ~orders@tomasdiaz.com
 
~Tomas Diaz. ~orders@tomasdiaz.com

Revision as of 10:27, 23 December 2023

Problem

Let $n$ be a natural number. A cube with edge $n$ can be divided into 1996 cubes whose edges are also natural numbers. Determine the smallest possible value of $n$.

~translated into English by Tomas Diaz. ~orders@tomasdiaz.com

Solution

A cube with edge $n$ can be divided at the most into $n^3$ cubes with side 1. Since $12^3 < 1996 < 13^3$ then smallest $n$ cannot be less or equal to 12. Now we need to find out if it is possible to divide a cube of edge 13 into 1996 cubes.

Since $13^3-1996=201$, this means that I have 201 extra cubes of side 1. Now we need to find out if we can if I can combine groups of these into other cubes of larger edge sides until my total of cubes is 1996. That is, I can combine 8 cubes into a cube of edge 2, 27 cubes into a cube of edge 3, $k^3$ cubes into a cube of edge $k$ and so on...

We can express the volume of the cube as:

$V=\sum_{i}^{}2^ik_i=13^3$ where $k_i$ is the quantity of cubes of edge $i$, Hence, we want to find solve this equation for $k_i$ with $\sum_{i}^{}k_i=1996$

Starting with $k_1=13^3=2197$ with 201 cubes left we find that $201=(25)(8^3)+1. So, we can make 25 cubes of edge 2. If we set$k_2$=25 we need to subtract 200 from$k_1$and our numbers are now at:$k_1=1997$,$k_2=25$,$\sum_{i}^{}k_i=2022$. So we still have 26 cubes more than we need.

So we can take 27 cubes of edge 1 and combine them into one cube of edge three and our new numbers are:$ (Error compiling LaTeX. Unknown error_msg)k_1=1970$,$k_2=25$,$k_3=1$,$\sum_{i}^{}k_i=1970+25+1=1996$. And this proves that we can divide a cube of edge 13 into 1970 cubes of edge 1, plus 25 cubes of edge 2, plus one cube of edge 3.

Since smallest$ (Error compiling LaTeX. Unknown error_msg)n>12$and$n=13$is possible then smallest possible$n$ is 13.

~Tomas Diaz. ~orders@tomasdiaz.com

Alternate solutions are always welcome. If you have a different, elegant solution to this problem, please add it to this page.

See also

https://www.oma.org.ar/enunciados/ibe11.htm

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