C2D8

1. C2D8 Bellwork: Fill in the blanks on the worksheet Recall the formula for compound interest: Initial value (or amount) Number of compoundings Interest rate as a decimal Time To develop an equation to determine continuously compounded interest, let P= 1, r = 100% = 1, and t = 1. Let n  . Fill in the table

2. 2 1 4 2.44141 2.61304 12 365 2.71457 8760 2.71813 e 2.718281828 _________  ______________ Now we will use e in logs!!

3. e 2.718281828 _____  _____________ π This number is a constant (like ___), and is referred to as the _________ base. The logarithm with base e is called the _________ logarithm, ___. natural natural ln

4. 10 8 6 4 2 –10 –6 –4 –2 2 4 6 10 8 –8 –2 –4 –6 –8 –10 Sketch y = f(x) for f(x) = ex. y = x f(x) = ex y e-1 ≈ 0.37 y = f –1(x) e0 = 1 x ≈ 2.72 e1 ≈ 7.39 e2 Sketch y = f–1(x) and y = x. ln x f–1(x) =

5. Definition: Whenever you convert back and forth between exponential and logarithmic form using base e, follow the same definition of logs: Why do base e and natural logs exist? In the “real” world, you will see examples of both in situations involving growth and decay of natural organisms, population growth, continuous compounding, etc.

6. Practice #1: exponent a) b) c) argument x = 4 log 5 = 9x log base e e exponent 4 = x log e argument base Never write “e” in the base for the final answer!

7. Practice #1: d) e) f) 10 = x – 8 16 = 3x + 7 x5 = 2 log log log e e e

8. 2. Rewrite each equation in exponential form. a) ln x = 2 b) ln 3 = x c) ln x2 = 2 2 x 2 e = x e = 3 e = x2 d) ln (x – 4) = 3 e) x = ln 56 f) ln 9 = x4 x x4 3 e = 56 e = 9 e = x – 4 What’s the base?

9. Properties: Natural logs have the same properties as regular logarithms: Same thing as before except the base is e! Practice #2: a) b)

10. 4. Expand the expression. a) b) 5. Simplify each expression. a) ln e b) ln e2 c) ln e x + 4 d) eln 5 e) eln (x – 1) (x + 4) ln e logee 2 ln e x – 1 5 e to what power is e? 2 (1) x + 4 Remember it’s as if the bases “cancel” 2 1

11. Change Of Base: The change of base formula also works for natural logs. Find each to 2 decimal places. 30 30 1) 2.45 2.45 4 4 2) Sometimes there are rounding errors, so ALWAYS do the entire problem in the calculator, then approximate at the end.

12. Practice #3: Solve for the variable. Be careful! All types of logarithmic equations are included below, but you will work with natural logs. Check your solutions. Rewrite these with exponents  Definition of Logs: + 5 + 5 ln (2x + 3) = 3 3 2x + 3 = e Exact and approximate answers are both required! – 3 – 3 2x = e3 – 3 (exact) (approx.) x ≈ 8.54

13.  Property of Equality: ln ( ) = ln ( ) Set each argument equal Did you check? Only x = 6, Sucka! ln x2 = ln (2x + 24) x2 = 2x + 24 x2 – 2x – 24 = 0 (x – 6)(x + 4) = 0 x – 6 = 0 or x + 4 = 0 x = 6 x = –4

14.  Log Properties: Product, Quotient, and Power Simplify using the properties Did you check? Only x = 9 Sucka!

15. Combine, then rewrite.  ln( ) + ln( ) = # Did you check? 4 e (exact) x ≈ 36.95 (approx.)

16. Logging both sides a) If you see an “e”, use “ln” (exact) (approx.) x ≈ –2.91 Be careful here… “ln” before subtracting. Do not write ln(16).

17. Continuously Compounded Interest Formula: Value after continuous compounding A(t) = A(t) = _________ Principal Value P = Compounding rate (as a decimal) r = Time t = a) An investment of $100 is now valued at $300. The annual interest rate is 8% compounded continuously. About how long has the money been invested? A(t) = P = r = t = 300 100 0.08 100 100 0.08 0.08 (exact) What do we do now? t ≈ 13.73 years (approx.)

18. b) An initial deposit of $2000 is now worth $5000. The account earns 5% annual interest, compounded continuously. Determine how long the money has been in the account. A(t) = P = r = t = 2000 2000 0.05 0.05 18.33 years