Lesson 14: Properties of Exponential and Logarithmic Functions

Hi everyone! This is the third of our distance-learning lessons. Read through the material below, watch the videos, and send me your questions. Don’t forget to complete the Daily Quiz (below this post) before midnight to be marked present for the day

Lesson 14: Properties of Exponential and Logarithmic Functions

Lesson Date: Thursday, March 26th.

Topic: This lesson covers Chapter 14 in the book, Exponential and Logarithmic Functions.

WeBWorK: There are three WeBWorK assignments on today’s material, due next Thursday 4/2: Logarithmic Functions - Properties, Logarithmic Functions - Equations, and Exponential Functions - Equations

Today’s goal is to review the properties/rules of exponents and logs, and then see how we can use them to solve equations.

Lesson NOtes (Notability – pdf):

This .pdf file contains most of the work from the videos in this lesson. It is provided for your reference.

Properties of Exponential and Logarithmic Functions

You should already be familiar with the rules of exponents and rules of logarithms. I realize you may not remember them, so read through the material below and take a look at the examples in the first video.

Review: Properties of Exponential Functions

The following rules apply to exponential functions (where $b>0$ and $x,y$ are any real numbers):

$b^{x+y}=b^{x} \cdot b^{y}$
$b^{x-y}=\frac{b^{x}}{b^{y}}$
$\left(b^{x}\right)^{n}=b^{n x}$

Review: Properties of Logarithmic Functions

The following rules apply to logarithmic functions (where $b>0, b\neq 1$ and $x,y > 0$, and $n$ is an integer).

$\log_{b}(x \cdot y)=\log_{b}(x)+\log_{b}(y)$
$\log_{b}\left(\frac{x}{y}\right)=\log_{b}(x)-\log_{b}(y)$
$\log_{b}\left(x^{n}\right)=n \cdot \log_{b}(x)$ 

Change of base formula (if $a>0, a\neq 1)$:  
$\log_{b}(x)=\frac{\log_{a}(x)}{\log_{a}(b)}$

Since the logarithm is the inverse of the exponential function, each rule of exponents has a corresponding rule of logarithms.

Example 14.1: Combine the terms using the properties of logarithms so as to write as one logarithm.

a) $\frac{1}{2} \ln (x)+\ln (y)$
b) $\frac{2}{3}\left(\log \left(x^{2} y\right)-\log \left(x y^{2}\right)\right)$
c) $2 \ln (x)-\frac{1}{3} \ln (y)-\frac{7}{5} \ln (z)$ 
d) $5+\log_{2}\left(a^{2}-b^{2}\right)-\log_{2}(a+b)$
Example 14.2:  Write the expressions in terms of elementary logarithms $u=$ $\log_{b}(x), v=\log_{b}(y),$ and, in part $(\mathrm{c}),$ also $w=\log_{b}(z) .$ Assume that $x, y, z>0$

a) $\ln \left(\sqrt{x^{5}} \cdot y^{2}\right)$
b) $\log (\sqrt{\sqrt{x} \cdot y^{3}}) \quad$ 
c) $\log _{2}(\sqrt[3]{\frac{x^{2}}{y \sqrt{z}}})$

Warning: The videos in this lesson are LONG – about 30 minutes each – but they consist almost entirely of EXAMPLES. Feel free to skip around.

Prof. Reitz

Solving Exponential and Log Equations

Now we’re going to use these properties to solve equations.

Example 14.5: Solve for $x$.

a) $2^{x+7}=32$
b) $10^{2 x-8}=0.01$
c) $7^{2 x-3}=7^{5 x+4}$
d) $5^{3 x+1}=25^{4 x-7}$
e) $\ln (3 x-5)=\ln (x-1)$
f) $\log_{2}(x+5)=\log_{2}(x+3)+4$
g) $\log_{6}(x)+\log_{6}(x+4)=\log_{6}(5)$ 
h) $\log_{3}(x-2)+\log_{3}(x+6)=2$
Example 14.6: Solving Log Equations

a) $3^{x+5}=8$
b) $13^{2 x-4}=6$
c) $5^{x-7}=2^{x}$
d) $5.1^{x}=2.7^{2 x+6}$
e) $17^{x-2}=3^{x+4}$
f) $7^{2x+3}=11^{3x-6}$

That’s it for today, everybody! Give the WeBWorK a try, and let me know if you have questions.

-Prof. Reitz

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