Difference between revisions of "1990 AIME Problems/Problem 13"

Revision as of 14:53, 27 June 2019

Problem

Let $T = \{9^k : k ~ \mbox{is an integer}, 0 \le k \le 4000\}$ . Given that $9^{4000}_{}$ has 3817 digits and that its first (leftmost) digit is 9, how many elements of $T_{}^{}$ have 9 as their leftmost digit?

Solution 1

Since $9^{4000}$ has 3816 digits more than $9^1$ , $4000 - 3816 = \boxed{184}$ numbers have 9 as their leftmost digits.

Solution 2

Let's divide all elements of T into sections. Each section ranges from $10^{i}$ to $10^{i+1}$ And, each section must have 1 or 2 elements. So, let's consider both cases.

If a section has 1 element, we claim that the number doesn't have 9 as the leftmost digit. Let this element be $9^{k}$ and the section ranges from $10^{i}$ to $10^{i+1}$ . To the contrary, let's assume the number ( $9^{k}$ ) does have 9 as the leftmost digit. Thus, $9 \cdot 10^i \leq 9^k$ . But, if you divide both sides by 9, you get $10^i \leq 9^{k-1}$ , and because $9^{k-1} < 9^{k} < 10^{i+1}$ , so we have another number ( $9^{k-1}$ ) in the same section ( $10^i \leq 9^{k-1} < 10^{i+1}$ ). Which is a contradiction to our assumption that the section only has 1 element. So in this case, the number doesn't have 9 as the leftmost digit.

If a section has 2 elements, we claim one has to have a 9 as the leftmost digit, one doesn't. Let the elements be $9^{k}$ and $9^{k+1}$ , and the section ranges from $10^{i}$ to $10^{i+1}$ . So We know $10^{i} \leq 9^{k} < 9^{k+1} < 10^{i+1}$ . From $10^{i} \leq 9^{k}$ , we know $9 \cdot 10^{i} \leq 9^{k+1}$ , and since $9^{k+1} < 10^{i+1}$ . The number( $9^{k+1}$ )'s leftmost digit must be 9, and the other number( $9^{k}$ )'s leftmost digit is 1.

There are total 4001 elements in T and 3817 sections that have 1 or 2 elements. And, no matter how many elements a section has, each section contains exactly one element that doesn't begin with 9. We can take 4001 elements, subtract 3817 elements that don't have 9 as the leftmost digit, and get $\boxed{184}$ numbers that have 9 as the leftmost digit.

- AlexLikeMath

@@ Line 13: / Line 13: @@
 So We know <math>10^{i} \leq 9^{k} < 9^{k+1} < 10^{i+1}</math>. From <math>10^{i} \leq 9^{k} </math>, we know <math>9 \cdot 10^{i} \leq 9^{k+1} </math>, and since <math>9^{k+1} < 10^{i+1}</math>. The number(<math>9^{k+1}</math>)'s leftmost digit must be 9, and the other number(<math>9^{k}</math>)'s leftmost digit is 1.
-There are total 4001 elements in T and 3817 sections (each esction can only has one or two elements). The two elements section must have 9 as the left most digit. We can take 4001 elements, subtract 3817 elements that don't have 9 as the leftmost digit, and get <math>\boxed{184}</math> numbers that have 9 as the leftmost digit.
+There are total 4001 elements in T and 3817 sections that have 1 or 2 elements. And, no matter how many elements a section has, each section contains exactly one element that doesn't begin with 9. We can take 4001 elements, subtract 3817 elements that don't have 9 as the leftmost digit, and get <math>\boxed{184}</math> numbers that have 9 as the leftmost digit.
 - AlexLikeMath

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Difference between revisions of "1990 AIME Problems/Problem 13"

Revision as of 14:53, 27 June 2019

Contents

Problem

Solution 1

Solution 2

See also