Presentation is loading. Please wait.

Presentation is loading. Please wait.

Base e and Natural Logarithms

Published byConrad Gallagher Modified over 8 years ago

Similar presentations

Presentation on theme: "Base e and Natural Logarithms"— Presentation transcript:

1 Base e and Natural Logarithms
Evaluate using the following table n 10 100 1000 10000 100000 e

2 Base e and Natural Logarithms
10—2.5937 100—2.7048 1000—2.7169 10000—2.7181 100000—2.7183 —2.7183 e= …

3 Base e and Natural Logarithms
Natural Base e ln x = loge x The system of natural logarithms has the number called e as its base. (e is named after the 18th century Swiss mathematician, Leonhard Euler.)  e is the base used in calculus.  It is called the "natural" base because of certain technical considerations. It is used in continual growth/decay situations

4 Base e and Natural Logarithms
Inverse Property of Base e and Natural Logarithms e ln x = x and ln ex = x All rules for log’s apply for ln’s ln 732= 2.5958 ln =

5 Base e and Natural Logarithms
A=A0ekt A = end value, Ao=beginning value After 500 years, a sample of radium-226 has decayed to 80.4% of its original mass. Find the half-life of radium-226. 0.804 = 1e500k ln ( 0.804) = ln (e500k)

6 ln ( 0.804) = 500k ln e ln e=1 ln ( 0.804) = 500k k= (ln 0.804)/500. This is the exact solution; evaluate the natural log with a calculator to get the decimal approximation k =

7 Base e and Natural Logarithms
Since we now know k, we can write the formula (function) for the amount of radium present at time t as A=A0 e t

8 Base e and Natural Logarithms
Now, we can finally find the half-life. We set A=1/2 A0 and solve for t. (1/2)A0=A0 e t 1/2 = e t ln(1/2) = ln[e t]. ln (1/2) = t t= ln(1/2) /( ) t = 1590

9 Base e and Natural Logarithms
2x=64 solve using ln X ln 2= ln 64 X=ln 64/ln 2 X=6

10 Base e and Natural Logarithms
POPULATION The equation A = A0e rt describes the growth of the world’s population where A is the population at time t, A0 is the population at t =0, and r is the annual growth rate. How long will take a population of 6.5 billion to increase to 9 billion if the annual growth rate is 2%? 9=6.5e.02t t=16.3 years

11 Base e and Natural Logarithms
INTEREST Horatio opens a bank account that pays 2.3% annual interest compounded continuously. He makes an initial deposit of 10,000. What will be the balance of the account in 10 years? Assume that he makes no additional deposits and no withdrawals. Use A = A0e rt A=10000e .023(10) 12586

Download ppt "Base e and Natural Logarithms"

Similar presentations

Compound interest & exponential growth/decay. Compound Interest A=P(1 + r ) nt n P - Initial principal r – annual rate expressed as a decimal n – compounded.

Compound interest & exponential growth/decay. Compound Interest A=P(1 + r ) nt n P - Initial principal r – annual rate expressed as a decimal n – compounded.
Welcome to Interactive Chalkboard Algebra 2 Interactive Chalkboard Copyright © by The McGraw-Hill Companies, Inc. Send all inquiries to: GLENCOE DIVISION.

Welcome to Interactive Chalkboard Algebra 2 Interactive Chalkboard Copyright © by The McGraw-Hill Companies, Inc. Send all inquiries to: GLENCOE DIVISION.
6.2 Growth and Decay Law of Exponential Growth and Decay C = initial value k = constant of proportionality if k > 0, exponential growth occurs if k < 0,

6.2 Growth and Decay Law of Exponential Growth and Decay C = initial value k = constant of proportionality if k > 0, exponential growth occurs if k < 0,
Exponential Functions, Growth, and Decay (2 Questions) Tell whether each function represents growth or decay, then graph by using a table of values: 1.

Exponential Functions, Growth, and Decay (2 Questions) Tell whether each function represents growth or decay, then graph by using a table of values: 1.
Exponential functions Logarithmic functions

Exponential functions Logarithmic functions
Warm-Up Solve for x in each equation. a) 3 x = b) log 2 x = –4 c) 5 x = 30.

Warm-Up Solve for x in each equation. a) 3 x = b) log 2 x = –4 c) 5 x = 30.
200 300 400 500 100 200 300 400 500 100 200 300 400 500 100 200 300 400 500 100 200 300 400 500 100 Exponential Functions Intro. to Logarithms Properties.

Exponential Functions Intro. to Logarithms Properties.
The Natural Base, e 7-6 Warm Up Lesson Presentation Lesson Quiz

The Natural Base, e 7-6 Warm Up Lesson Presentation Lesson Quiz
Models of Exponential and Log Functions Properties of Logarithms Solving Exponential and Log Functions Exponential Growth and Decay 100 200 300 400 500.

Models of Exponential and Log Functions Properties of Logarithms Solving Exponential and Log Functions Exponential Growth and Decay
The natural number e and solving base e exponential equations

The natural number e and solving base e exponential equations
LOGARITHMS AND EXPONENTIAL MODELS

LOGARITHMS AND EXPONENTIAL MODELS
Homework

Homework
Exponential FunctionsLogarithms Properties of Logarithms Natural Logarithms Solving Exponential Equations 100 200 300 400 500.

Exponential FunctionsLogarithms Properties of Logarithms Natural Logarithms Solving Exponential Equations
Warm Up Simplify. x 1. log 10 x 2. log b b 3w 3. 10 log z 3w3w z 4. b log b (x – 1 ) x – 1.

Warm Up Simplify. x 1. log 10 x 2. log b b 3w log z 3w3w z 4. b log b (x – 1 ) x – 1.
Logarithms and Exponential Equations Ashley Berens Madison Vaughn Jesse Walker.

Logarithms and Exponential Equations Ashley Berens Madison Vaughn Jesse Walker.
5.4 Exponential and Logarithmic Equations Essential Questions: How do we solve exponential and logarithmic equations?

5.4 Exponential and Logarithmic Equations Essential Questions: How do we solve exponential and logarithmic equations?
7-6 & 7-7 Exponential Functions

7-6 & 7-7 Exponential Functions
Objective: To identify and solve exponential functions.

Objective: To identify and solve exponential functions.
Chapter 8 Review. Rewrite into logarithm form: 1. 2.

Chapter 8 Review. Rewrite into logarithm form: 1. 2.
1.) If there are initially 100 fruit flies in a sample, and the number of fruit flies decreases by one-half each hour, How many fruit flies will be present.

1.) If there are initially 100 fruit flies in a sample, and the number of fruit flies decreases by one-half each hour, How many fruit flies will be present.

Similar presentations

Ads by Google