3.2 Logarithmic Functions & Their Graphs. Inverses of Exponentials Remember from section 1.6 that if...
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Transcript of 3.2 Logarithmic Functions & Their Graphs. Inverses of Exponentials Remember from section 1.6 that if...
![Page 1: 3.2 Logarithmic Functions & Their Graphs. Inverses of Exponentials Remember from section 1.6 that if a function is one- to-one (meaning it passes the.](https://reader035.fdocuments.in/reader035/viewer/2022070413/5697bf901a28abf838c8e006/html5/thumbnails/1.jpg)
3.2
Logarithmic Functions & Their Graphs
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Inverses of Exponentials
Remember from section 1.6 that if a function is one-to-one (meaning it passes the Horizontal Line Test) it must have an inverse function. Looking at the graphs of exponential functions of the form f(x) = ax, they all pass the Horizontal Line Test and therefore have an inverse function. The inverse function is called the logarithmic function with base a.
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Definition of Logarithmic Functions
For x > 0, a > 0, and a ≠ 1
y = loga x
If and only if x = ay. The function given by f(x) = loga x is called the logarithmic function with base a. Read as log base a of x.
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When evaluating logarithms, remember that loga x is the exponent to which a must be raised to obtain x.
For example: log2 8 = 3 because 23 = 8.
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Example 1: Evaluating Logarithms
Use the definition of logarithmic functions to evaluate each logarithm at the indicated value of x.
A)f(x) = log2 x x = 32
B)F(x) = log3 x x = 1
C)F(x) = log4 x x = 2
D)F(x) = log10 x x = 1001
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Common Logarithm
The logarithmic function with base 10 is called the common logarithmic function.
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Example 2: Evaluating Common Logarithms on a Calculator
Use a calculator to evaluate the function f(x) = log10 x at each value of x.
A)x = 10
B)x = 2.5
C)x = -2
D)x = 41
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Error Message
In part c we obtain an error message because the domain of every logarithmic function is the set of positive real numbers.
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Properties of Logarithms
1. loga 1 = 0 because a0 = 1
2. loga a = 1 because a1 = a
3. loga ax = x and alogx = x INVERSES
4. If loga x = loga y then x = y
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Example 3: Using Properties of Logarithms
A) Solve for x: log2 x = log2 3
B) Solve for x: log4 4 = x
C) Simplify: log5 5x
D) Simplify: 7log7 14
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The Natural Logarithmic Function
The function f(x) = ex is one-to-one and has an inverse function. This inverse function is called the natural logarithmic function and is denoted by ln x (read as the natural log of x).
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For x > 0, y = ln x if and only if x = ey. The function given by f(x) = loge x = ln x is called the natural logarithmic function.
NOTE: the natural logarithm ln x is written without a base. The base is understood to be e.
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Example 4: Evaluating the Natural Logarithmic Function
Use a calculator to evaluate the function f(x) = ln x at each indicated value of x.
A)x = 2
B)x = .3
C)x = -1
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Properties of Natural Logarithms
1. ln 1 = 0 because e0 = 1
2. ln e = 1 because e1 = e
3. ln ex = x and elnx = x INVERSES
4. If ln x = ln y, then x = y
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Example 5: Using Properties of Natural Logarithms
Use the properties of natural logarithms to rewrite each expression.
A)ln
B)eln 5
C)ln e0
D)2 ln e
e
1
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Example 6: Finding the Domains of Logarithmic Functions
Find the domain of each function.
A)f(x) = ln (x – 2)
B)g(x) = ln (2 – x)
C)h(x) = ln x2