Difference between revisions of "2004 AMC 10B Problems/Problem 21"

Revision as of 21:12, 30 April 2020

Problem

Let $1$ ; $4$ ; $\ldots$ and $9$ ; $16$ ; $\ldots$ be two arithmetic progressions. The set $S$ is the union of the first $2004$ terms of each sequence. How many distinct numbers are in $S$ ?

$\mathrm{(A) \ } 3722 \qquad \mathrm{(B) \ } 3732 \qquad \mathrm{(C) \ } 3914 \qquad \mathrm{(D) \ } 3924 \qquad \mathrm{(E) \ } 4007$

Solution 1

The two sets of terms are $A=\{ 3k+1 : 0\leq k < 2004 \}$ and $B=\{ 7l+9 : 0\leq l<2004\}$ .

Now $S=A\cup B$ . We can compute $|S|=|A\cup B|=|A|+|B|-|A\cap B|=4008-|A\cap B|$ . We will now find $|A\cap B|$ .

Consider the numbers in $B$ . We want to find out how many of them lie in $A$ . In other words, we need to find out the number of valid values of $l$ for which $7l+9\in A$ .

The fact " $7l+9\in A$ " can be rewritten as " $1\leq 7l+9 \leq 3\cdot 2003 + 1$ , and $7l+9\equiv 1\pmod 3$ ".

The first condition gives $0\leq l\leq 857$ , the second one gives $l\equiv 1\pmod 3$ .

Thus the good values of $l$ are $\{1,4,7,\dots,856\}$ , and their count is $858/3 = 286$ .

Therefore $|A\cap B|=286$ , and thus $|S|=4008-|A\cap B|=\boxed{(A) 3722}$ .

Solution 2

We can start by finding the first non-distinct term from both sequences. We find that that number is $16$ . Now, to find every

other non-distinct terms, we can just keep adding $21$ . We know that the last terms of both sequences are $1+3\cdot 2003$ and

$9+7\cdot 2003$ . Clearly, $1+3\cdot 2003$ is smaller and that is the last possible common term of both sequences. Now, we can

create the inequality $16+21k \leq 1+3\cdot 2003$ . Using the inequality, we find that there are $286$ common terms. There are 4008

terms in total. $4008-286=\boxed{(A) 3722}$

~Hithere22702

@@ Line 20: / Line 20: @@
 ==Solution 2==
-We can start by finding the first non-distinct term from both sequences. We find that that number is <math>16</math>. Now, to find every other
+We can start by finding the first non-distinct term from both sequences. We find that that number is <math>16</math>. Now, to find every
-non-distinct terms, we can just keep adding 21. We know that the last terms of both sequences are <math>1+3\cdot 2003</math> and <math>9+7\cdot
+other non-distinct terms, we can just keep adding <math>21</math>. We know that the last terms of both sequences are <math>1+3\cdot 2003</math> and
-</math>. Clearly, <math>1+3\cdot 2003</math> is smaller and that is the last possible common term of both sequences. Now, we can create the
+<math>9+7\cdot 2003</math>. Clearly, <math>1+3\cdot 2003</math> is smaller and that is the last possible common term of both sequences. Now, we can
-inequality <math>16+21k \leq 1+3\cdot 2003</math>. Using the inequality, we find that there are <math>286</math> common terms. There are 4008 terms in
+create the inequality <math>16+21k \leq 1+3\cdot 2003</math>. Using the inequality, we find that there are <math>286</math> common terms. There are 4008
-total. <math>4008-286=\boxed{(A) 3722}</math>
+terms in total. <math>4008-286=\boxed{(A) 3722}</math>
 ~Hithere22702

2004 AMC 10B (Problems • Answer Key • Resources)
Preceded by Problem 20	Followed by Problem 22
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Difference between revisions of "2004 AMC 10B Problems/Problem 21"

Revision as of 21:12, 30 April 2020

Contents

Problem

Solution 1

Solution 2

See also