CHAPTER 2 2.4 Continuity Exponential Growth and Decay Law of Natural Growth(k>0) & (Law of natural decay (k<0)): dy/dt = ky The solution of the initial-value.

Slides:

Advertisements

Similar presentations

Exponential Growth and Decay

Advertisements

Exponential Functions Functions that have the exponent as the variable.

Copyright © Cengage Learning. All rights reserved.

ACTIVITY 40 Modeling with Exponential (Section 5.5, pp ) and Logarithmic Functions.

7 INVERSE FUNCTIONS. 7.5 Exponential Growth and Decay In this section, we will: Use differentiation to solve real-life problems involving exponentially.

Chapter 3 Linear and Exponential Changes 3.2 Exponential growth and decay: Constant percentage rates 1 Learning Objectives: Understand exponential functions.

Differential Equations

Exponential Growth and Decay

Exponential Growth and Decay

4.5 Modeling with Exponential and Logarithmic Functions.

Copyright © Cengage Learning. All rights reserved.

Some Applications Involving Separable Differential Equations.

Warm Up Simplify each expression. 1. ( )2 3.

Precalc. 2. Simplify 3. Simplify 4. Simplify.

INTRODUCTORY MATHEMATICAL ANALYSIS For Business, Economics, and the Life and Social Sciences  2011 Pearson Education, Inc. Chapter 4 Exponential and Logarithmic.

Exponential Growth and Decay

© 2008 Pearson Addison-Wesley. All rights reserved Chapter 1 Section 8-6 Exponential and Logarithmic Functions, Applications, and Models.

Exponential & Logarithmic Models MATH Precalculus S. Rook.

Exponential and Logarithmic Functions

College Algebra Sixth Edition James Stewart Lothar Redlin Saleem Watson.

Sullivan PreCalculus Section 4

Exponential Growth and Decay; Modeling Data

Exponential Functions. Exponential Function f(x) = a x for any positive number a other than one.

Exponential Growth & Decay, Half-life, Compound Interest

Homework Lesson Handout #5-27 (ODD) Exam ( ): 12/4.

Exponential Growth and Decay 6.4. Exponential Decay Exponential Decay is very similar to Exponential Growth. The only difference in the model is that.

4.8 Exponential and Logarithmic Models

Exponentials and Logarithms

10.7 Exponential Growth and Decay

1 SS Solving Exponential Equations MCR3U - Santowski.

Section 6.4 Solving Logarithmic and Exponential Equations

Rates of Growth & Decay. Example (1) - a The size of a colony of bacteria was 100 million at 12 am and 200 million at 3am. Assuming that the relative.

Exponential Functions Section 1.3. Exponential Functions f(x) = a x Example: y 1 = 2 x y 2 = 3 x y 3 = 5 x For what values of x is 2 x

Chapter 3 – Differentiation Rules

 If you deposit $10,000 into an account earning 3.5% interest compounded quarterly;  How much will you have in the account after 15 years?  How much.

Applications of Logs and Exponentials Section 3-4.

Section 4.2 Logarithms and Exponential Models. The half-life of a substance is the amount of time it takes for a decreasing exponential function to decay.

Rates of Growth & Decay. Example (1) - a The size of a colony of bacteria was 100 million at 12 am and 200 million at 3am. Assuming that the relative.

Section 4.5 Modeling with Exponential & Logarithmic Functions.

12/7/2015 Math SL1 - Santowski 1 Lesson 16 – Modeling with Exponential Functions Math SL - Santowski.

Exponential Modeling Section 3.2a.

Exponential Growth and Decay. Objectives Solve applications problems involving exponential growth and decay.

Growth and Decay Exponential Models.

Advanced Precalculus Notes 4.8 Exponential Growth and Decay k > 0 growthk < 0 decay.

Compound Interest Amount invested = £1000 Interest Rate = 5% Interest at end of Year 1= 5% of £1000 = 0.05 x  £1000 = £50 Amount at end of Year 1= £1050.

Exponential Growth and Decay; Newton’s Law; Logistic Models

Lesson 16- Solving Exponential Equations IB Math HL - Santowski 1/28/20161 IB Math HL - Santowski.

Integers as Exponents Simplify:.

7.3B Applications of Solving Exponential Equations

6.7 Growth and Decay. Uninhibited Growth of Cells.

5.8 Exponential Growth and Decay Mon Dec 7 Do Now In the laboratory, the number of Escherichia coli bacteria grows exponentially with growth constant k.

Lesson 36 - Solving Exponential Equations Math 2 Honors - Santowski 2/1/20161 Math Honors 2 - Santowski.

A quantity that decreases exponentially is said to have exponential decay. The constant k has units of “inverse time”; if t is measured in days, then k.

Various Forms of Exponential Functions

Lesson 19 - Solving Exponential Equations IB Math SL1 - Santowski 2/17/20161 SL1 Math - Santowski.

1.3 Exponential Functions. Slide 1- 2 Exponential Function.

Chapter 5 Applications of Exponential and Natural Logarithm Functions.

6.4 Applications of Differential Equations. I. Exponential Growth and Decay A.) Law of Exponential Change - Any situation where a quantity (y) whose rate.

Constant Rate Exponential Population Model Date: 3.2 Exponential and Logistic Modeling (3.2) Find the growth or decay rates: r = (1 + r) 1.35% growth If.

Exponential and Logarithmic Functions 4 Copyright © Cengage Learning. All rights reserved.

Bellwork Evaluate each expression Solve. for x = bacteria that double 1. every 30 minutes. Find the 2. number of bacteriaafter 3 hours

E XPONENTIAL W ORD P ROBLEMS Unit 3 Day 5. D O -N OW.

Table of Contents 5. Section 5.8 Exponential Growth and Decay.

MAHATMA GANDHI INSTITUTE OF TECHNICAL EDUCATION AND RESEARCH CENTRE, NAVSARI YEAR :

Honors Precalculus: Do Now Solve for x. 4 2x – 1 = 3 x – 3 You deposit $7550 in an account that pays 7.25% interest compounded continuously. How long will.

4.4 Laws Of Logarithms.

Exponential Growth and Decay

Section 4.8: Exponential Growth & Decay

Section 4.8: Exponential Growth & Decay

Presentation transcript:

CHAPTER Continuity Exponential Growth and Decay Law of Natural Growth(k>0) & (Law of natural decay (k<0)): dy/dt = ky The solution of the initial-value problem dy/dt = ky, y(0) = y o is y(t) = y o e kt. Population Growth: In the context of population growth, we can write dP/dt = kP or (1/p)(dP/dt) = k, where (1/p)(dP/dt) is the growth rate divided by the population size,and it is called the relative growth rate.

CHAPTER Continuity Example: A common inhabitant of human intestines is the bacterium Escherichia coli. A cell of this bacterium in a nutrient-broth medium divides into two cells every 20 minutes. The initial population of a culture is 100 cells. a) Find the relative growth rate. b) Find an expression for the number of cells after t hours. c) Find the number of cells after 10 hours. d) When will the population reach 10,000 cells?

CHAPTER Continuity Example: A bacteria culture grows with constant relative growth rate. The count was 400 after 2 hours and 25,600 after 6 hours. a) What was the initial population of the culture? b) Find an expression for the population after t hours. c) In what period of time does the population double? d) When will the population reach 100,000?

Radioactive Decay: Radioactive substances decay by spontaneously emitting radiation. If m(t) is the mass remaining from an initial mass m o of the substance after time t, then the relative decay rate –(1/m)(dm/dt) has been found experimentally to be constant. It follows that dm/dt = k m where k is a negative constant. The mass decays exponentially: m(t) = m o e k t. Physicists express the rate of decay in terms of half-life, the time required for half of any given quantity to decay.

CHAPTER Continuity Example: Polonium-210 has a half-life of 140 days. a) If a sample has a mass of 200 mg, find a formula for the mass that remains after t days. b) Find the mass after 100 days. c) When will the mass be reduced to 10 mg? d) Sketch the graph of the mass function.

CHAPTER Continuity Example: After 3 days a sample of radon-222 decayed to 58% of its original amount. a) What is the half-life of radon-222? b) How long would it take the sample to decay to 10% of its original amount?

CHAPTER Continuity Continuously Compound Interest: Example: How long will it take an investment to double in value if the interest rate is 6% compounded continuously? Example: If $500 is borrowed at 14% interest, find the amounts due at the end of 2 years if the interest is compounded: i) annually, ii) quarterly, iii) monthly, iv) daily, v) hourly, vi) continuously.