To determine which pairs of fractions are equivalent to \( \frac{29}{1} \), we need to check if the fractions can be simplified to \( \frac{29}{1} \) or if they are mathematically equal to it.
Let's analyze each pair of fractions given in your options:
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\( \frac{20}{27} \) and \( \frac{12}{19} \):
- Neither of these fractions simplify to \( \frac{29}{1} \).
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\( \frac{5}{27} \) and \( \frac{12}{54} \):
- The fraction \( \frac{12}{54} \) simplifies to \( \frac{2}{9} \), which does not equal \( \frac{29}{1} \).
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\( \frac{6}{27} \) and \( \frac{12}{45} \):
- The fraction \( \frac{6}{27} \) simplifies to \( \frac{2}{9} \) and \( \frac{12}{45} \) simplifies to \( \frac{4}{15} \), neither of which equals \( \frac{29}{1} \).
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\( \frac{6}{27} \) and \( \frac{12}{54} \):
- The fraction \( \frac{12}{54} \) simplifies to \( \frac{2}{9} \).
None of the pairs of fractions provided are equivalent to \( \frac{29}{1} \).
If the question was to find equivalent fractions for a specific fraction and you provided context for \( \frac{29}{n} \) (where \( n \) can be some positive integer), we would have to know that fraction to evaluate properly. However, as presented, none of the options equal \( \frac{29}{1} \).