Presentation is loading. Please wait.

Presentation is loading. Please wait.

Introduction Previously, you learned how to graph logarithmic equations with bases other than 10. It may be necessary to convert other bases to common.

Published bySamson Briggs Modified over 8 years ago

Similar presentations

Presentation on theme: "Introduction Previously, you learned how to graph logarithmic equations with bases other than 10. It may be necessary to convert other bases to common."— Presentation transcript:

1 Introduction Previously, you learned how to graph logarithmic equations with bases other than 10. It may be necessary to convert other bases to common logarithms if you are using a calculator that does not automatically do this. This process involves applying a property of logarithms in order to convert logarithms with different bases to common logarithms. Properties of logarithms allow you to solve problems containing logarithms by making the logarithms easier to work with. Applying logarithmic properties often allows for simpler and fewer calculations in a problem. 1 4.2.3: Properties of Logarithms

2 Key Concepts Recall that a logarithm is a quantity that represents the power to which a base b must be raised in order to equal a quantity x. It is typically written in the form log b x. Recall that when logarithms have bases other than 10, you can rewrite them as common logarithms by using the change of base formula,. 2 4.2.3: Properties of Logarithms

3 Key Concepts, continued Since logarithms are the inverses of exponents, they have similar properties. Like exponents, logarithms can be added, subtracted, multiplied, and divided. Performing operations with logarithms is the same as performing operations on exponents. For example, log (ab) = log a + log b is the same as multiplying two numbers raised to powers, as in x a x b = x a + b. 3 4.2.3: Properties of Logarithms

4 Key Concepts, continued The following table includes properties of logarithms and corresponding properties of exponents. 4 4.2.3: Properties of Logarithms Exponent propertyLogarithm property Logarithm property name a x a y = a x + y log a (x y) = log a x + log a y Product Property of Logarithms Quotient Property of Logarithms (a x ) y = a x y log a x y = y log a x Power Property of Logarithms

5 Common Errors/Misconceptions misunderstanding the parts of a logarithmic equation misunderstanding how to convert a logarithmic equation to an exponential equation or vice versa making calculator input errors 5 4.2.3: Properties of Logarithms

6 Guided Practice Example 2 Use the Product Property of Logarithms to show that log a (xy) = log a x + log a y. Verify this property mathematically. 6 4.2.3: Properties of Logarithms

7 Guided Practice: Example 2, continued 1.Write the equivalent exponential equation for log a x. To write the equivalent exponential equation, let M = log a x. By the definition of logarithms, M = log a x is equivalent to a x = M. 7 4.2.3: Properties of Logarithms

8 Guided Practice: Example 2, continued 2.Write the equivalent exponential equation for log a y. To write the equivalent exponential equation, let N = log a y. By the definition of logarithms, N = log a y is equivalent to a y = N. 8 4.2.3: Properties of Logarithms

9 Guided Practice: Example 2, continued 3.Write the exponential form of the Product Property. According to the Product Property, log a (xy) = M + N. Therefore, the exponential form of the Product Property is a (M + N) = xy. By the Product Property of Exponents, a (M + N) = (a M )(a N ). 9 4.2.3: Properties of Logarithms

10 Guided Practice: Example 2, continued 4.Substitute specific values for a, x, and y into the original equation to verify that the Product Property of Logarithms holds true for this problem. The original equation was log a (xy) = log a x + log a y. Start by substituting values into the left-hand side of the equation, log a (xy), and evaluating. Then, substitute the same values into log a x + log a y and solve to see if the result matches that for log a (xy). 10 4.2.3: Properties of Logarithms

11 Guided Practice: Example 2, continued For example, let a = 10, x = 3, and y = 5. log a (xy)Original expression = log (10) [(3)(5)]Substitute 10 for a, 3 for x, and 5 for y. = log 10 15Multiply the numbers. ≈ 1.18Use a calculator to compute log 10 15. 11 4.2.3: Properties of Logarithms

12 Guided Practice: Example 2, continued Now evaluate the terms in the right-hand side of the equation, log a x + log a y, for the same values of a, x, and y. log a x + log a yOriginal expression = log (10) (3) + log (10) (5)Substitute 10 for a, 3 for x, and 5 for y. ≈ 0.48 + 0.70Use a calculator to compute log 10 3 and log 10 5. ≈ 1.18Add. 12 4.2.3: Properties of Logarithms

13 Guided Practice: Example 2, continued The results match: log 10 15 ≈ 1.18 and log 10 3 + log 10 5 ≈ 1.18. Therefore, the Product Property of Logarithms holds true. 13 4.2.3: Properties of Logarithms ✔

14 Guided Practice: Example 2, continued 14 4.2.3: Properties of Logarithms

15 Guided Practice Example 3 Use the properties of logarithms to simplify the logarithmic function f(x) = 2 log x – log (x – 3). 15 4.2.3: Properties of Logarithms

16 Guided Practice: Example 3, continued 1.Identify which logarithmic properties can be used to simplify the logarithmic function. The given function contains the term 2 log x. This is the same as 2 log x. This form is also seen in the Power Property of Logarithms, where log a x y = y log a x. 16 4.2.3: Properties of Logarithms

17 Guided Practice: Example 3, continued Additionally, this function includes the subtraction of two logarithmic terms. This form is also seen in the Quotient Property of Logarithms, where Both the Power Property of Logarithms and the Quotient Property of Logarithms can be used to simplify the given function. 17 4.2.3: Properties of Logarithms

18 Guided Practice: Example 3, continued 2.Simplify the logarithmic function by applying the identified properties. Apply the Power Property of Logarithms to the term 2 log x from the original function. The base, a, is understood to be 10 and is omitted. y log x = log x y Power Property of Logarithms (2) log x = log x (2) Substitute 2 for y. Thus, 2 log x = log x 2. 18 4.2.3: Properties of Logarithms

19 Guided Practice: Example 3, continued Now apply the Quotient Property, to the original function. Use log x 2 in place of 2 log x. f(x) = 2 log x – log (x – 3)Original function f(x) = (log x 2 ) – log (x – 3) Substitute log x 2 for 2 log x. Simplify using the Quotient Property of Logarithms. 19 4.2.3: Properties of Logarithms

20 Guided Practice: Example 3, continued The logarithmic function f(x) = 2 log x – log (x – 3) simplifies to. 20 4.2.3: Properties of Logarithms ✔

21 Guided Practice: Example 3, continued 21 4.2.3: Properties of Logarithms

Download ppt "Introduction Previously, you learned how to graph logarithmic equations with bases other than 10. It may be necessary to convert other bases to common."

Similar presentations

4.3 - 1 10 TH EDITION LIAL HORNSBY SCHNEIDER COLLEGE ALGEBRA.

TH EDITION LIAL HORNSBY SCHNEIDER COLLEGE ALGEBRA.
Essential Question: What are some of the similarities and differences between natural and common logarithms.

Essential Question: What are some of the similarities and differences between natural and common logarithms.
Introduction Exponential functions are ideal for modeling growth and decay phenomena. Equations derived from given information, such as observations, can.

Introduction Exponential functions are ideal for modeling growth and decay phenomena. Equations derived from given information, such as observations, can.
Table of Contents Solving Logarithmic Equations A logarithmic equation is an equation with an expression that contains the log of a variable expression.

Table of Contents Solving Logarithmic Equations A logarithmic equation is an equation with an expression that contains the log of a variable expression.
Introduction Previously, we learned how to solve quadratic-linear systems by graphing and identifying points of intersection. In this lesson, we will focus.

Introduction Previously, we learned how to solve quadratic-linear systems by graphing and identifying points of intersection. In this lesson, we will focus.
In this section we will introduce a new concept which is the logarithm

In this section we will introduce a new concept which is the logarithm
Logarithmic Functions  In this section, another type of function will be studied called the logarithmic function. There is a close connection between.

Logarithmic Functions  In this section, another type of function will be studied called the logarithmic function. There is a close connection between.
Exponential and Logarithmic Functions. Exponential Functions Vocabulary – Exponential Function – Logarithmic Function – Base – Inverse Function – Asymptote.

Exponential and Logarithmic Functions. Exponential Functions Vocabulary – Exponential Function – Logarithmic Function – Base – Inverse Function – Asymptote.
5.2 Logarithmic Functions & Their Graphs

5.2 Logarithmic Functions & Their Graphs
Logarithmic Functions

Logarithmic Functions
Introduction Two equations that are solved together are called systems of equations. The solution to a system of equations is the point or points that.

Introduction Two equations that are solved together are called systems of equations. The solution to a system of equations is the point or points that.
Standardized Test Practice

Standardized Test Practice
Properties of Logarithms

Properties of Logarithms
Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.
LOGS EQUAL THE The inverse of an exponential function is a logarithmic function. Logarithmic Function x = log a y read: “x equals log base a of y”

LOGS EQUAL THE The inverse of an exponential function is a logarithmic function. Logarithmic Function x = log a y read: “x equals log base a of y”
Exponential and Logarithmic Equations

Exponential and Logarithmic Equations
7-5 Logarithmic & Exponential Equations

7-5 Logarithmic & Exponential Equations
Logarithmic Functions y = log a x, is read “the logarithm, base a, of x,” or “log, base a, of x,” means “the exponent to which we raise a to get x.”

Logarithmic Functions y = log a x, is read “the logarithm, base a, of x,” or “log, base a, of x,” means “the exponent to which we raise a to get x.”
Log Properties. Because logs are REALLY exponents they have similar properties to exponents. Recall that when we MULTIPLY like bases we ADD the exponents.

Log Properties. Because logs are REALLY exponents they have similar properties to exponents. Recall that when we MULTIPLY like bases we ADD the exponents.
Section 6.4 Exponential and Logarithmic Equations

Section 6.4 Exponential and Logarithmic Equations

Similar presentations

Ads by Google