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The rad(n) is a function with some very nice properties. It also behaves well with respect to the function gcd(A,B). | The rad(n) is a function with some very nice properties. It also behaves well with respect to the function gcd(A,B). | ||
− | '''Exercise 1:''' Show that: | + | '''Exercise 1:''' Suppose that A and B are positive integers. Show that: |
− | + | gcd(rad(A),rad(B)) = rad(gcd(A,B)) | |
− | + | and | |
+ | |||
+ | rad(AB) = rad(A)rad(B)/rad(gcd(A,B)) | ||
== The Evil Wizard == | == The Evil Wizard == |
Revision as of 08:24, 22 July 2010
The Erdos-Woods Problem
This page introduces a problem considered by Erdos and Woods.
Defintion (Radical): The radical of a positive integer n is simply the product of all those prime numbers p which divide n.
Remark: There are no prime numbers which divide 1, so rad(1) is the product of all the elements in the empty set. The only reasonable value to choose for this number is 1.
To compute rad(n) in sage, define the following simple function.
sage: def rad(n):
....: return prod(n.prime_divisors())
....:
sage: rad(256)
2
sage: rad(210)
210
The rad(n) is a function with some very nice properties. It also behaves well with respect to the function gcd(A,B).
Exercise 1: Suppose that A and B are positive integers. Show that:
gcd(rad(A),rad(B)) = rad(gcd(A,B))
and
rad(AB) = rad(A)rad(B)/rad(gcd(A,B))
The Evil Wizard
Suppose you are confronted by an evil wizard who presents you with the following challenge:
"I'm going to pick a positive integer $n > 1$ and then I shall tell you the radical of each integer from $n$ to $n+k$. Then you must tell me what $n$ is."
For which $k$ should you accept this challenge? Discuss...