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Logarithmic Functions and Their Graphs

Logarithmic Functions and Their Graphs. Review: Changing Between Logarithmic and Exponential Form. If x > 0 and 0 < b ≠ 1, then if and only if .

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Logarithmic Functions and Their Graphs

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  1. Logarithmic Functions and Their Graphs

  2. Review: Changing Between Logarithmic and Exponential Form • If x > 0 and 0 < b ≠ 1, then if and only if . • This statement says that a logarithm is an exponent. Because logarithms are exponents, we can evaluate simple logarithmic expressions using our understanding of exponents.

  3. Evaluating Logarithms a.) because . b.) because . c.) because d.) because e.) because

  4. Basic Properties of Logarithms • For 0 < b ≠ 1 , x > 0, and any real number y, • logb1 = 0 because b0 = 1. • logbb = 1 because b1 = b. • logbby = y because by = by. • because

  5. Evaluating Logarithmic and Exponential Expressions (a) (b) (c)

  6. Common Logarithms – Base 10 • Logarithms with base 10 are called common logarithms. • Often drop the subscript of 10 for the base when using common logarithms. • The common logarithmic function: y = log x if and only if 10y = x.

  7. Basic Properties of Common Logarithms • Let x and y be real numbers with x > 0. log 1 = 0 because 100 = 1. log 10 = 1 because 101 = 10. log 10y = y because 10y = 10y . because log x = log x. • Using the definition of common logarithm or these basic properties, we can evaluate expressions involving a base of 10.

  8. Evaluating Logarithmic and Exponential Expressions – Base 10 (a) (b) (c) (d)

  9. Solving Simple Logarithmic Equations • Solve each equation by changing it to exponential form: a.) log x = 3 b.) a.) Changing to exponential form, x = 10³ = 1000. b.) Changing to exponential form, x = 25 = 32.

  10. Natural Logarithms – Base e • Logarithms with base e are natural logarithms. • We use the abbreviation “ln” (without a subscript) to denote a natural logarithm.

  11. Basic Properties of Natural Logarithms • Let x and y be real numbers with x > 0. ln 1 = 0 because e0 = 1. ln e = 1 because e1 = e. lney = y because ey = ey. eln x = x because ln x = ln x.

  12. Transforming Logarithmic Graphs • Describe how to transform the graph of y = ln x or y = log x into the graph of the given function. a.) g(x) = ln (x + 2) The graph is obtained by translating the graph of y = ln (x) two units to the LEFT.

  13. Transforming Logarithmic Graphs • Describe how to transform the graph of y = ln x or y = log x into the graph of the given function. c.) g(x) = 3 log x The graph is obtained by vertically stretching the graph of f(x) = log x by a factor of 3.

  14. Transforming Logarithmic Graphs • Describe how to transform the graph of y = ln x or y = log x into the graph of the given function. d.) h(x) = 1+ log x The graph is obtained by a translation 1 unit up.

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