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Warm Up Simplify. x 1. log10 x 2. log b b 3w 3. 10 log z 3w z 4. b log b (x –1) x 1

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Warm Up Simplify. x. 1. log 10 x. 3 w. 2. log b b 3 w. z. 3. 10 log z. x – 1. 4. b log b ( x – 1 ). Objectives. Use the number e to write and graph exponential functions representing real-world situations. Solve equations and problems involving e or natural logarithms. - PowerPoint PPT Presentation

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Page 1: Warm Up Simplify

Warm UpSimplify.

x1. log10x

2. logbb3w

3. 10log z

3w

z

4. blogb(x –1) x – 1

Page 2: Warm Up Simplify

Use the number e to write and graph exponential functions representing real-world situations.

Solve equations and problems involving e or natural logarithms.

Objectives

Page 3: Warm Up Simplify

natural logarithmnatural logarithmic function

Vocabulary

Page 4: Warm Up Simplify

Recall the compound interest formula A = P(1 + )nt, where A is the amount, P is the principal, r is the annual interest, n is the number of times the interest is compounded per year and t is the time in years.

nr

Suppose that $1 is invested at 100% interest (r = 1) compounded n times for one year as represented by the function f(n) = P(1 + )n. n

1

Page 5: Warm Up Simplify

As n gets very large, interest is continuously compounded. Examine the graph of f(n)= (1 + )n. The function has a horizontal asymptote. As n becomes infinitely large, the value of the function approaches approximately 2.7182818…. This number is called e. Like , the constant e is an irrational number.

n1

Page 6: Warm Up Simplify
Page 7: Warm Up Simplify

Exponential functions with e as a base have the same properties as the functions you have studied. The graph of f(x) = ex is like other graphs of exponential functions, such as f(x) = 3x.

The domain of f(x) = ex is all real numbers. The range is {y|y > 0}.

Page 8: Warm Up Simplify

A logarithm with a base of e is called a natural logarithm and is abbreviated as “ln” (rather than as log

e). Natural logarithms have the same

properties as log base 10 and logarithms with other bases.

The natural logarithmic function f(x) = ln x is the inverse of the natural exponential function f(x) = ex.

Page 9: Warm Up Simplify

The domain of f(x) = ln x is {x|x > 0}.

The range of f(x) = ln x is all real numbers.

All of the properties of logarithms from Lesson 7-4 also apply to natural logarithms.

Page 10: Warm Up Simplify

Simplify.

A. ln e0.15t B. e3ln(x +1)

ln e0.15t = 0.15t e3ln(x +1) = (x + 1)3

ln e2x + ln ex = 2x + x = 3x

Example 2: Simplifying Expression with e or ln

C. ln e2x + ln ex

Page 11: Warm Up Simplify

Simplify.

a. ln e3.2 b. e2lnx

c. ln ex +4y

ln e3.2 = 3.2 e2lnx = x2

ln ex + 4y = x + 4y

Check It Out! Example 2

Page 12: Warm Up Simplify

The formula for continuously compounded interest is A = Pert, where A is the total amount, P is the principal, r is the annual interest rate, and t is the time in years.

Page 13: Warm Up Simplify

What is the total amount for an investment of $500 invested at 5.25% for 40 years and compounded continuously?

Example 3: Economics Application

The total amount is $4083.08.

A = Pert

Substitute 500 for P, 0.0525 for r, and 40 for t.

A = 500e0.0525(40)

Use the ex key on a calculator.

A ≈ 4083.08

Page 14: Warm Up Simplify

What is the total amount for an investment of $100 invested at 3.5% for 8 years and compounded continuously?

The total amount is $132.31.

A = Pert

Substitute 100 for P, 0.035 for r, and 8 for t.

A = 100e0.035(8)

Use the ex key on a calculator.

A ≈ 132.31

Check It Out! Example 3

Page 15: Warm Up Simplify

The half-life of a substance is the time it takes for half of the substance to breakdown or convert to another substance during the process of decay. Natural decay is modeled by the function below.

Page 16: Warm Up Simplify

Pluonium-239 (Pu-239) has a half-life of 24,110 years. How long does it take for a 1 g sample of Pu-239 to decay to 0.1 g?

Example 4: Science Application

Step 1 Find the decay constant for plutonium-239.

Use the natural decay function.N(t) = N0e–kt

Substitute 1 for N0 ,24,110 for t,

and for N(t) because half of the initial quantity will remain.

12

= 1e–k(24,110)12

Page 17: Warm Up Simplify

Example 4 Continued

Simplify and take ln of both sides.

ln 2–1 = –24,110k

ln = ln e–24,110k12

Write as 2 –1, and simplify the right side.

12

–ln 2 = –24,110k ln2–1 = –1ln 2 = –ln 2

ln224,110

k = ≈ 0.000029

Page 18: Warm Up Simplify

Example 4 Continued

Substitute 0.000029 for k.

Take ln of both sides.

Step 2 Write the decay function and solve for t.

Substitute 1 for N0 and 0.01 for N(t).

N(t) = N0e–0.000029t

0.1 = 1e–0.000029t

ln 0.1 = ln e–0.000029t

ln 0.1 = –0.000029t

ln 0.10.000029t = – ≈ 80,000

It takes approximately 80,000 years to decay.

Simplify.

Page 19: Warm Up Simplify

Determine how long it will take for 650 mg of a sample of chromium-51 which has a half-life of about 28 days to decay to 200 mg.

Use the natural decay function. t.N(t) = N0e–kt

Substitute 1 for N0 ,28 for t, and for

N(t) because half of the initial quantity will remain.

12 = 1e–k(28)1

2

Check It Out! Example 4

Step 1 Find the decay constant for Chromium-51.

Page 20: Warm Up Simplify

Simplify and take ln of both sides.

ln 2–1 = –28k

ln = ln e–28k12

Write as 2 –1 , and simplify the right side.

12

–ln 2 = –28k ln 2 –1 = –1ln 2 = –ln 2.

Check It Out! Example 4 Continued

k = ≈ 0.0247ln 2 28

Page 21: Warm Up Simplify

Substitute 0.0247 for k.

Take ln of both sides.

Step 2 Write the decay function and solve for t.

Substitute 650 for N0 and 200 for

N(t).

N(t) = N0e–0.0247t

200 = 650e–0.0247t

It takes approximately 47.7 days to decay.

Simplify.

Check It Out! Example 4 Continued

ln = ln e–0.0247t 650

200

ln = –0.0247t 650

200

t = ≈ 47.7

650200ln

–0.0247

Page 22: Warm Up Simplify

Lesson Quiz

Simplify.

1. ln e–10t t0.25–10t

–x 2x2

2. e0.25 lnt

3. –ln ex 4. 2ln ex2

5. What is the total amount for an investment of $1000 invested at 7.25% for 15 years and compounded continuously?

≈ 21,000 yr

6. The half-life of carbon-14 is 5730 years. What is the age of a fossil that only has 8% of its original carbon-14?

≈ $2966.85

Page 23: Warm Up Simplify

Homework!

Chapter 7 Section 6Page 534 #6-12, 17-22, 31-36

Page 24: Warm Up Simplify