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Chapter 5: Problem 86

Use the properties of logarithms to rewrite each expression as a single logarithm with coefficient 1. Assume that all variables represent positive real numbers. $$\frac{1}{2} \log x-\frac{1}{3} \log y-2 \log z$$

Short Answer

Expert verified
\( \log \left( \frac{\sqrt{x}}{\sqrt[3]{y} z^2} \right) \)

Step by step solution

01

Apply the Power Rule

The Power Rule states that \( a \log b = \log b^a \). We'll apply this to each term in the given expression:- \( \frac{1}{2} \log x \) becomes \( \log x^{1/2} = \log \sqrt{x} \).- \( \frac{1}{3} \log y \) becomes \( \log y^{1/3} = \log \sqrt[3]{y} \).- \( 2 \log z \) becomes \( \log z^2 \).
02

Apply the Quotient Rule

The Quotient Rule states that \( \log a - \log b = \log \left(\frac{a}{b}\right) \). Now we have the expression:\( \log \sqrt{x} - \log \sqrt[3]{y} - \log z^2 \).Apply the rule to the last two terms:- \( \log \sqrt{x} - \log \sqrt[3]{y} - \log z^2 \) becomes \( \log \left( \frac{\sqrt{x}}{\sqrt[3]{y} \cdot z^2} \right) \).
03

Combine into a Single Logarithm

Now the expression is in the form of a single logarithm:\[ \log \left( \frac{\sqrt{x}}{\sqrt[3]{y} \cdot z^2} \right) \]

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Key Concepts

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

Properties of Logarithms
Logarithms have several properties that make them incredibly useful for simplifying expressions involving exponents and division. These properties allow us to rewrite complex logarithmic expressions into simpler forms. There are three main properties that are commonly used:
  • Product Rule: This rule states that the logarithm of a product is the sum of the logarithms of its factors: \( \log(a \times b) = \log a + \log b \).
  • Quotient Rule: Similar to the product rule, the quotient rule states that the logarithm of a quotient is the difference of the logarithms: \( \log\left(\frac{a}{b}\right) = \log a - \log b \).
  • Power Rule: This rule allows us to bring an exponent outside the log as a factor: \( \log(a^b) = b \log a \).
By using these properties, we can transform logarithmic expressions into simpler, equivalent forms. This is often useful for solving equations or simplifying expressions.
Power Rule
The Power Rule is a crucial tool for manipulating logarithms when they involve exponents or powers. To apply this rule, you'll need to understand that it effectively lets you step outside the logarithmic operation and deal with the power directly.Here's how it works: If you have an expression involving a logarithm with a coefficient, the power rule allows you to convert it into a single exponent form. For example:- \( a \log b \) becomes \( \log b^a \).In practical terms, this means:
  • If you see \( \frac{1}{2} \log x \), using the power rule, it becomes \( \log x^{1/2} = \log \sqrt{x} \). This conversion makes it easier to work with the expression because the power rule "removes" the coefficient away from the logarithm.
  • Similarly, \( 2 \log z \) turns into \( \log z^2 \).
By applying this rule, you can start combining and reducing logarithmic terms, leading to a simpler overall expression.
Quotient Rule
The Quotient Rule is another fundamental property of logarithms that helps in simplifying expressions involving divisions within logarithms. This rule is particularly helpful when you are working with expressions that involve subtraction between different logarithmic terms.The rule states:
  • \( \log a - \log b = \log\left(\frac{a}{b}\right) \).
This transformation simplifies expressions since it allows you to express a difference of logs as a single log involving a fraction.For example, suppose you have the logarithmic expression \( \log \sqrt{x} - \log \sqrt[3]{y} - \log z^2 \). By applying the quotient rule, it can be rewritten as:
  • \( \log\left(\frac{\sqrt{x}}{\sqrt[3]{y} \cdot z^2}\right) \).
This final single logarithmic expression includes all the components from the original expression, but it is simplified to one manageable term. The Quotient Rule is invaluable for such transformations, as it allows the subtraction of logarithms to succinctly capture the relationship between different components as a division.

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Most popular questions from this chapter

Solve each problem. World Population Growth since 2000 , world population in millions closely fits the exponential function $$ y=6079 e^{0.0126 x} $$ where \(x\) is the number of years since 2000 . (Image can't copy) (a) The world population was about 6555 million in 2006 . How closely does the function approximate this value? (b) Use this model to estimate the population in 2010 . (c) Use this model to predict the population in 2025 . (d) Explain why this model may not be accurate for 2025 .

Use a graphing calculator to solve each equation. Give solutions to the nearest hundredth. $$2^{-x}=\log _{10} x$$

Use the table feature of your graphing calculator to work parts (a) and (b). (a) Find how long it will take \(\$ 1500\) invested at \(5.75 \%\) compounded daily, to triple in value. Locate the solution by systematically decreasing \(\Delta\) Tbl. Find the answer to the nearest day. (Find your answer to the nearest day by eventually letting \(\Delta \mathrm{Tbl}=\frac{1}{365} .\) The decimal part of the solution can be multiplied by 365 to determine the number of days greater than the nearest year. For example, if the solution is determined to be 16.2027 years, then multiply 0.2027 by 365 to get \(73.9855 .\) The solution is then, to the nearest day, 16 years and 74 days.) Confirm your answer analytically. (b) Find how long it will take \(\$ 2000\) invested at \(8 \%,\) compounded daily, to be worth \(\$ 5000\).

In general, it is not possible to find exact solutions analytically for equations that involve exponential or logarithmic functions together with polynomial, radical, and rational functions. Solve each equation= using a graphical method, and express solutions to the nearest thousandth if an approximation is appropriate. $$e^{x}=\frac{1}{x+2}$$

In the formula \(A=P\left(1+\frac{r}{n}\right)^{n t},\) we can interpret \(P\) as the present value of A dollars t years from now, earning annual interest \(r\) compounded \(n\) times per year. In this context, \(A\) is called the future value. If we solve the formula for \(P,\) we obtain $$P=A\left(1+\frac{r}{n}\right)^{-n t}$$ Use the future value formula. Find the present value of an account that will be worth \(\$ 25,000\) in 2.75 years, if interest is compounded quarterly at \(6 \%\).
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