Difference between revisions of "2008 iTest Problems/Problem 39"
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Using the formula <math>\phi(n) = n \cdot (1 - \tfrac{1}{p_1})(1 - \tfrac{1}{p_2}) \cdots (1 - \tfrac{1}{p_n})</math> (or by manually counting the numbers relatively prime to each number), <math>1</math> number is relatively prime to <math>1</math>, <math>1</math> number is relatively prime to <math>2</math>, <math>2</math> numbers are relatively prime to <math>4</math>, <math>4</math> numbers are relatively prime to <math>8</math>, <math>250</math> numbers are relatively prime to <math>251</math>, <math>250</math> numbers are relatively prime to <math>502</math>, <math>500</math> numbers are relatively prime to <math>1004</math>, and <math>1000</math> numbers are relatively prime to <math>2008</math>. That means <math>S = 2008</math>, and the remainder when <math>S</math> is divided by <math>1000</math> is <math>\boxed{8}</math>. | Using the formula <math>\phi(n) = n \cdot (1 - \tfrac{1}{p_1})(1 - \tfrac{1}{p_2}) \cdots (1 - \tfrac{1}{p_n})</math> (or by manually counting the numbers relatively prime to each number), <math>1</math> number is relatively prime to <math>1</math>, <math>1</math> number is relatively prime to <math>2</math>, <math>2</math> numbers are relatively prime to <math>4</math>, <math>4</math> numbers are relatively prime to <math>8</math>, <math>250</math> numbers are relatively prime to <math>251</math>, <math>250</math> numbers are relatively prime to <math>502</math>, <math>500</math> numbers are relatively prime to <math>1004</math>, and <math>1000</math> numbers are relatively prime to <math>2008</math>. That means <math>S = 2008</math>, and the remainder when <math>S</math> is divided by <math>1000</math> is <math>\boxed{8}</math>. | ||
− | ==Extra Note | + | ==Extra Note== |
If all the divisors of an integer n are {<math>{d_1}</math>, <math>{d_2}</math>, <math>{d_3}</math>, ... <math>{d_k}</math>}, then n = <math>\phi({d_1})</math> + <math>\phi({d_2})</math> + .... + <math>\phi({d_k})</math>. | If all the divisors of an integer n are {<math>{d_1}</math>, <math>{d_2}</math>, <math>{d_3}</math>, ... <math>{d_k}</math>}, then n = <math>\phi({d_1})</math> + <math>\phi({d_2})</math> + .... + <math>\phi({d_k})</math>. | ||
This provides a shorter approach in this problem because it asks about the sum of the number of numbers co prime to 2008's divisors, as mentioned earlier. This is the same as 2008 itself, drastically simplifying the problem. | This provides a shorter approach in this problem because it asks about the sum of the number of numbers co prime to 2008's divisors, as mentioned earlier. This is the same as 2008 itself, drastically simplifying the problem. | ||
− | Proof | + | ==Proof== |
Given that: <math>n</math> = <math>{p_1}^{\alpha_1}</math><math>{p_2}^{\alpha_2}</math>....<math>{p_k}^{\alpha_k}</math> | Given that: <math>n</math> = <math>{p_1}^{\alpha_1}</math><math>{p_2}^{\alpha_2}</math>....<math>{p_k}^{\alpha_k}</math> |
Revision as of 22:11, 20 August 2023
Contents
Problem
Let denote , the number of integers that are relatively prime to . (For example, and .) Let , in which ranges through all positive divisors of , including and . Find the remainder when is divided by .
Solution
The divisors of are ,,,,,,, and , so the problem requires the sum of the number of numbers relatively prime to each of the eight numbers.
Using the formula (or by manually counting the numbers relatively prime to each number), number is relatively prime to , number is relatively prime to , numbers are relatively prime to , numbers are relatively prime to , numbers are relatively prime to , numbers are relatively prime to , numbers are relatively prime to , and numbers are relatively prime to . That means , and the remainder when is divided by is .
Extra Note
If all the divisors of an integer n are {, , , ... }, then n = + + .... + . This provides a shorter approach in this problem because it asks about the sum of the number of numbers co prime to 2008's divisors, as mentioned earlier. This is the same as 2008 itself, drastically simplifying the problem.
Proof
Given that: = ....
and
, , .... are all of 's divisors
+ + ... +
= + + ...
The above term represents the sum of the totient functions of all of n's divisors.
= + ....
= )) ...
=
...
= ...
=
See Also
2008 iTest (Problems) | ||
Preceded by: Problem 38 |
Followed by: Problem 40 | |
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