Difference between revisions of "1969 AHSME Problems/Problem 17"
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== Solution == | == Solution == | ||
− | Let <math>2^x=a</math>. Because <math>2^{2x}=(2^x)^2</math>, the given expression can be rewritten as <math>a^2-8a+12=0</math>. This can be factored as <math>(a-6)(a-2)=0</math>, which has solutions <math>a=2^x=6</math> and <math>a=2^x=2</math>. Looking at the answer choices, we see that <math>x=1</math> is absent. Rewriting <math>2^x=6</math> as <math>x= | + | Let <math>2^x=a</math>. Because <math>2^{2x}=(2^x)^2</math>, the given expression can be rewritten as <math>a^2-8a+12=0</math>. This can be factored as <math>(a-6)(a-2)=0</math>, which has solutions <math>a=2^x=6</math> and <math>a=2^x=2</math>. Looking at the answer choices, we see that <math>x=1</math> is absent. Rewriting <math>2^x=6</math> as <math>x=log_26</math> and then applying the logarithm addition identity in reverse gives <math>x=log_2(2)+log_2(3)=1+log_2(3)</math>. Applying the logarithm division identity shows that the answer is <math>\fbox{D}</math>. |
== See also == | == See also == |
Latest revision as of 15:30, 10 July 2015
Problem
The equation is satisfied by:
Solution
Let . Because , the given expression can be rewritten as . This can be factored as , which has solutions and . Looking at the answer choices, we see that is absent. Rewriting as and then applying the logarithm addition identity in reverse gives . Applying the logarithm division identity shows that the answer is .
See also
1969 AHSC (Problems • Answer Key • Resources) | ||
Preceded by Problem 16 |
Followed by Problem 18 | |
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All AHSME Problems and Solutions |
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