Textbook Question
In Exercises 105–108, evaluate each expression without using a calculator. log5 (log2 32)
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Ch. 4 - Exponential and Logarithmic Functions
Blitzer8th EditionCollege AlgebraISBN: 9780136970514
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Table of contents
- Ch. P - Fundamental Concepts of Algebra311
- Ch. 1 - Equations and Inequalities398
- Ch. 2 - Functions and Graphs407
- Ch. 3 - Polynomial and Rational Functions306
- Ch. 4 - Exponential and Logarithmic Functions247
- Ch. 5 - Systems of Equations and Inequalities173
- Ch. 6 - Matrices and Determinants143
- Ch. 7 - Conic Sections124
- Ch. 8 - Sequences, Induction, and Probability251
Chapter 5, Problem 107
In Exercises 105–108, evaluate each expression without using a calculator. log2 (log3 81)
Verified step by step guidance1
Identify the expression to evaluate: \( \log_2 \left( \log_3 81 \right) \). This means you first need to evaluate the inner logarithm \( \log_3 81 \), then use that result as the argument for the outer logarithm with base 2.
Evaluate the inner logarithm \( \log_3 81 \). Recall that \( \log_b a = c \) means \( b^c = a \). So, find the exponent \( c \) such that \( 3^c = 81 \).
Express 81 as a power of 3. Since \( 81 = 3^4 \), it follows that \( \log_3 81 = 4 \).
Substitute the inner logarithm result back into the original expression: \( \log_2 4 \). Now, evaluate \( \log_2 4 \) by finding the exponent \( d \) such that \( 2^d = 4 \).
Recognize that \( 4 = 2^2 \), so \( \log_2 4 = 2 \). This completes the evaluation of the original expression.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Logarithmic Functions
A logarithmic function is the inverse of an exponential function. It answers the question: to what exponent must the base be raised to produce a given number? For example, log_b(a) = c means b^c = a. Understanding this relationship is essential for evaluating nested logarithms.
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Graphs of Logarithmic Functions
Change of Base and Simplification
Simplifying logarithmic expressions often involves rewriting numbers as powers of the base. For instance, recognizing that 81 = 3^4 allows you to simplify log3(81) to 4. This step is crucial before evaluating the outer logarithm.
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5:36Change of Base Property
Evaluating Nested Logarithms
Nested logarithms require evaluating the inner logarithm first, then using that result as the input for the outer logarithm. In this problem, you first find log3(81), then use that value to compute log2 of the result, applying the properties of logarithms sequentially.
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Related Practice
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In Exercises 105–108, evaluate each expression without using a calculator. log (ln e)
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Textbook Question
In Exercises 101–104, write each equation in its equivalent exponential form. Then solve for x. log4x=-3
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