The second stage examination of INMO, the Regional Mathematical Olympiad (RMO) is a three hour examination with six problems. The problems under each topic involve high level of difficulty and sophistication. West Bengal RMO 2015 Problem 6 Solution has been written for RMO preparation series. The book, Challenge and Thrill of Pre-College Mathematics is very useful for preparation of RMO.
Also visit: Math Olympiad program of Cheenta
We can write $latex a=[a]+\{a\},$ where $latex [a]$ denotes the integral part of $latex a.$
Now, we can say that $latex 0<\{a\}<1,$ as $latex a\not\in\mathbb{Z}.$
Let $latex a=[a]+\dfrac{1}{2},$ where $latex [a]$ is odd. Then $latex {a}=\dfrac{1}{2}.$
All such integers, must satisfy the property $latex 2k+1<a<2k+2,$ where $latex k$ is a non-negative integer.
Then $latex a\left(3-{a}\right)=\dfrac{\left(2[a]+1\right)}{2}~\cdot~\left([a]+\dfrac{1}{2}-\dfrac{3}{2}\right)=\dfrac{(2[a]+1)([a]-1)}{2}~.$
Now, $latex [a]=2k+1.$ Means, $latex [a]-1$ is even.
So $latex 2|[a]-1.$
Or, $latex =a(3-{a})=\dfrac{(2[a]+1)([a]-1)}{2}$ is an integer.
Hence, $latex a(3-{a})$ is an integer for all positive reals $latex a$ satisfying $latex -$
$latex (I)~2k+1<a<2k+2,$ for some non-negative integer $latex k.$
$latex (II)~{a}=\dfrac{1}{2}~.$
As $latex k$ takes infinitely many values, number of such positive real numbers $latex a$ is also infinite.
This completes the proof.
Key Idea: Greatest Integer Function
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