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Chapter 4: Problem 70

Use the properties of logarithms to expand the expression as a sum, difference, and/or multiple of logarithms. (Assume all variables are positive.)\(\log _{10} \frac{y}{2}\)

Short Answer

Expert verified
\(\log_{10}y - \log_{10}2\)

Step by step solution

01

Apply the logarithm quotient rule

The log of a quotient can be written as a difference of the referenced logs. Using the mentioned property, \(\log _{10} \frac{y}{2}\) can be rewritten as \(\log_{10}y - \log_{10}2\).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Logarithm Quotient Rule
Understanding the logarithm quotient rule is essential when working with logarithmic expressions involving division. This rule states that the logarithm of a quotient is the difference between the logarithm of the numerator and the logarithm of the denominator. In mathematical terms, for any positive real numbers a, b, and base c, where c is not equal to 1, we can express this as:
\[\begin{equation}\log_c\left(\frac{a}{b}\right) = \log_c(a) - \log_c(b)\end{equation}\]
Let's apply this rule to an example: If given the expression \(\log_{10} \frac{y}{2}\), we recognize that y is the numerator and 2 is the denominator. According to the quotient rule, this can be simplified to \(\log_{10}y - \log_{10}2\). This rule is particularly powerful because it breaks down a single logarithmic expression into a difference of two simpler logarithmic terms, making it easier to work with and understand.
Expanding Logarithmic Expressions
Expanding logarithmic expressions is a technique used to rewrite complex logs into a combination of simpler ones. This often involves applying a series of logarithm rules, not just the quotient rule.
  • Product Rule: States that the log of a product is equal to the sum of the logs of the factors; \(\log_c(ab) = \log_c(a) + \log_c(b).\)
  • Power Rule: Shows that the log of a power can be expressed as the exponent times the log of the base; \(\log_c(a^k) = k \cdot \log_c(a).\)
Employing these rules can significantly simplify the process of solving equations involving logarithms. In particular, the power rule often complements the quotient rule when dealing with logarithmic expressions that involve powers. This is why understanding each property is vital: they serve as building blocks that, when combined, allow for the expanding and simplifying of any logarithmic expression.
Logarithm Rules
In addition to the quotient rule, there are other fundamental logarithm rules that are crucial when manipulating logarithmic equations. These rules form the backbone of understanding logarithms and their properties. Here are the basics summarized:
  • Product Rule: As mentioned, this expresses the log of a product as the sum of the logs (\(\log_b(mn) = \log_b(m) + \log_b(n)\)).
  • Quotient Rule: We've already seen how this can express the log of a quotient as the difference of logs.
  • Power Rule: This allows rewriting the log of an exponent as the exponent multiplied by the log of the base (\(\log_b(m^n) = n\cdot\log_b(m)\)).
In all cases, it's assumed that the bases are the same and are neither 0 nor 1. By mastering these rules, one can expand, condense, and transform logarithmic expressions to proceed with solving more advanced mathematics problems. It’s important when using these rules to always ensure the variables are within the domain where the logarithms are defined, typically this means making sure the log arguments are positive numbers.

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Most popular questions from this chapter

Solve the exponential equation algebraically. Approximate the result to three decimal places.\(\left(1+\frac{0.075}{4}\right)^{4 t}=5\)

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Population The populations \(P\) of the United States (in thousands) from 1990 to 2005 are shown in the table. (Source: U.S. Census Bureau)$$ \begin{array}{|c|c|} \hline \text { Year } & \text { Population } \\ \hline 1990 & 250,132 \\ \hline 1991 & 253,493 \\ \hline 1992 & 256,894 \\ \hline 1993 & 260,255 \\ \hline 1994 & 263,436 \\ \hline 1995 & 266,557 \\ \hline 1996 & 269,667 \\ \hline 1997 & 272,912 \\ \hline \end{array} $$$$ \begin{array}{|c|c|} \hline \text { Year } & \text { Population } \\ \hline 1998 & 276,115 \\ \hline 1999 & 279,295 \\ \hline 2000 & 282,403 \\ \hline 2001 & 285,335 \\ \hline 2002 & 288,216 \\ \hline 2003 & 291,089 \\ \hline 2004 & 293,908 \\ \hline 2005 & 296,639 \\ \hline \end{array} $$(a) Use a graphing utility to create a scatter plot of the data. Let \(t\) represent the year, with \(t=0\) corresponding to 1990 . (b) Use the regression feature of a graphing utility to find an exponential model for the data. Use the Inverse Property \(b=e^{\ln b}\) to rewrite the model as an exponential model in base \(e\). (c) Use the regression feature of a graphing utility to find a linear model and a quadratic model for the data. (d) Use a graphing utility to graph the exponential model in base \(e\) and the models in part (c) with the scatter plot. (e) Use each model to predict the populations in 2008 , 2009 , and 2010 . Do all models give reasonable predictions? Explain.
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