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− | == Solution (Binary Interpretation, Computer Scientists' Playground) == | + | == Solution 3 (Binary Interpretation, Computer Scientists' Playground) == |
We first check that <math>\gcd(23, 2^n) = 1</math> hence we are always seeking a unique modular inverse of <math>23</math>, <math>b_n</math>, such that <math>a_n \equiv 23b_n \equiv 1 \mod{2^n}</math>. | We first check that <math>\gcd(23, 2^n) = 1</math> hence we are always seeking a unique modular inverse of <math>23</math>, <math>b_n</math>, such that <math>a_n \equiv 23b_n \equiv 1 \mod{2^n}</math>. |
Revision as of 18:57, 16 February 2023
For each positive integer let
be the least positive integer multiple of
such that
Find the number of positive integers
less than or equal to
that satisfy
Contents
[hide]Solution
Denote .
Thus, for each
, we need to find smallest positive integer
, such that
Thus, we need to find smallest , such that
Now, we find the smallest , such that
.
We must have
. That is,
.
We find
.
Therefore, for each , we need to find smallest
, such that
We have the following results:
\begin{enumerate}
\item If , then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\item If
, then
and
.
\end{enumerate}
Therefore, in each cycle, , we have
,
,
,
, such that
. That is,
.
At the boundary of two consecutive cycles,
.
We have .
Therefore, the number of feasible
is
.
~Steven Chen (Professor Chen Education Palace, www.professorchenedu.com)
Solution 2
Observe that if is divisible by
,
. If not,
.
This encourages us to let . Rewriting the above equations, we have
Now, we start listing. We know that
, so
,
,
,
,
,
,
,
,
,
,
. Hence the sequence is periodic with period 11.
Note that
if and only if
, i.e.
is even. This occurrs when
is congruent to 0, 3, 4 or 6 mod 11.
From 1 to , there are
values of
. Since
satisfies the criteria, we subtract 1 to get
, and we're done!
Solution 3 (Binary Interpretation, Computer Scientists' Playground)
We first check that hence we are always seeking a unique modular inverse of
,
, such that
.
Now that we know that is unique, we proceed to recast this problem in binary. This is convenient because
is simply the last
-bits of
in binary, and if
, it means that of the last
bits of
, only the rightmost bit (henceforth
th bit) is
.
Also, multiplication in binary can be thought of as adding shifted copies of the multiplicand. For example:
Now note , and recall that our objective is to progressively zero out the
leftmost bits of
except for the
th bit.
Write , we note that
uniquely defines the
th bit of
, and once we determine
,
uniquely determines the
st bit of
, so on and so forth.
For example, satisfies
Next, we note that the second bit of
is
, so we must also have
in order to zero it out, giving
happens precisely when
. In fact we can see this in action by working out
. Note that
has 1 on the
nd bit, so we must choose
. This gives
Note that since the rd and
th bit are
,
, and this gives
.
It may seem that this process will take forever, but note that has
bits behind the leading digit, and in the worst case, the leading digits of
will have a cycle length of at most
. In fact, we find that the cycle length is
, and in the process found that
,
, and
.
Since we have complete cycles of length
, and the last partial cycle yields
and
, we have a total of
values of
such that
~ cocoa @ https://www.corgillogical.com
See also
2023 AIME II (Problems • Answer Key • Resources) | ||
Preceded by Problem 14 |
Followed by Last Problem | |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 | ||
All AIME Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.