To solve the equation \( 27^{x \frac{3}{4} - 1} = 26 \), we will first isolate \( x \).
-
Rewrite the equation:
\[ 27^{x \frac{3}{4} - 1} = 26 \] -
Take the logarithm of both sides:
\[ \log(27^{x \frac{3}{4} - 1}) = \log(26) \] -
Use the power rule of logarithms:
\[ (x \frac{3}{4} - 1) \log(27) = \log(26) \] -
Solve for \( x \):
\[ x \frac{3}{4} - 1 = \frac{\log(26)}{\log(27)} \] -
Add 1 to both sides:
\[ x \frac{3}{4} = \frac{\log(26)}{\log(27)} + 1 \] -
Multiply both sides by \( \frac{4}{3} \):
\[ x = \frac{4}{3} \left( \frac{\log(26)}{\log(27)} + 1 \right) \]
To find an approximate numerical value for \( x \), we can compute the values of \( \log(26) \) and \( \log(27) \) using a calculator:
- \( \log(26) \approx 1.41497 \)
- \( \log(27) \approx 1.43136 \)
Now, substitute these values into the equation:
\[ \frac{\log(26)}{\log(27)} \approx \frac{1.41497}{1.43136} \approx 0.987 \]
So,
\[ x \frac{3}{4} \approx 0.987 + 1 \approx 1.987 \]
Therefore:
\[ x \approx \frac{4}{3} \times 1.987 \approx 2.646 \]
Now we compare the approximate value \( x \approx 2.646 \) with the response choices:
- \( 1 \)
- \( 0 \)
- \( \frac{25}{27} \)
- \( 3 \)
The closest valid integer response appears to be:
3.
So, the answer to the equation is: 3