AP CALCULUS AB Chapter 6:

Slides:

Advertisements

Similar presentations

Ch 6.4 Exponential Growth & Decay Calculus Graphical, Numerical, Algebraic by Finney Demana, Waits, Kennedy.

Advertisements

DIFFERENTIAL EQUATIONS: GROWTH AND DECAY Section 6.2.

Differential Equations Definition A differential equation is an equation involving derivatives of an unknown function and possibly the function itself.

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,

Diff EQs 6.6. Common Problems: Exponential Growth and Decay Compound Interest Radiation and half-life Newton’s law of cooling Other fun topics.

6.4 Exponential Growth and Decay Greg Kelly, Hanford High School, Richland, Washington Glacier National Park, Montana Photo by Vickie Kelly, 2004.

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

Differential Equations

Clicker Question 1 The radius of a circle is growing at a constant rate of 2 inches/sec. How fast is the area of the circle growing when the radius is.

Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Prentice Hall Slide 6- 1.

Copyright © Cengage Learning. All rights reserved.

Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Prentice Hall Exponential Growth and Decay Section 6.4.

Exponential Growth and Decay CalculusLesson 7-2 Mr. Hall.

Find the exponential function whose graph passes through the two points. Initial value: Equation: Other point: Function:

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

Chapter 6 AP Calculus BC.

Applications of Linear Equations

Warmup 1) 2). 6.4: Exponential Growth and Decay The number of bighorn sheep in a population increases at a rate that is proportional to the number of.

CHAPTER 1: PREREQUISITES FOR CALCULUS SECTION 1.3: EXPONENTIAL FUNCTIONS AP CALCULUS AB.

Sullivan PreCalculus Section 4

1.3 Exponential Functions. Exponential Growth Exponential Decay Applications The Number e …and why Exponential functions model many growth patterns. What.

Copyright © 2013, 2009, 2005 Pearson Education, Inc. 1 4 Inverse, Exponential, and Logarithmic Functions Copyright © 2013, 2009, 2005 Pearson Education,

AP Calculus Ms. Battaglia. Solve the differential equation.

6.4 Exponential Growth and Decay. What you’ll learn about Separable Differential Equations Law of Exponential Change Continuously Compounded Interest.

Exponential Growth and Decay

Imagine this much bacteria in a Petri dish Now this amount of the same bacteria Assuming that each bacterium would reproduce at the same rate, which dish.

Chapter 1: First-Order Differential Equations 1. Sec 1.4: Separable Equations and Applications Definition A 1 st order De of the form is said to.

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

Section 7.4: Exponential Growth and Decay Practice HW from Stewart Textbook (not to hand in) p. 532 # 1-17 odd.

Chapter 3 – Differentiation Rules

Using calculus, it can be shown that when the rate of growth or decay of some quantity at a given instant is proportional to the amount present at that.

Differential Equations Copyright © Cengage Learning. All rights reserved.

6 Differential Equations

INTRODUCTORY MATHEMATICAL ANALYSIS For Business, Economics, and the Life and Social Sciences  2007 Pearson Education Asia Chapter 15 Methods and Applications.

EXPONENTIAL GROWTH & DECAY; Application In 2000, the population of Africa was 807 million and by 2011 it had grown to 1052 million. Use the exponential.

Differential Equations: Growth and Decay Calculus 5.6.

Differential Equations

INTRODUCTORY MATHEMATICAL ANALYSIS For Business, Economics, and the Life and Social Sciences  2011 Pearson Education, Inc. Chapter 15 Methods and Applications.

Differential Equations: Growth & Decay (6.2) March 16th, 2012.

7.4 B – Applying calculus to Exponentials. Big Idea This section does not actually require calculus. You will learn a couple of formulas to model exponential.

Chapter 4 Section 4.6 Applications and Models of Exponential Growth and Decay.

Exponential Growth and Decay 6.4. Slide 6- 2 Quick Review.

Background Knowledge Write the equation of the line with a slope of ½ that goes through the point (8, 17)

Any population of living creatures increases at a rate that is proportional to the number present (at least for a while). Other things that increase or.

6.7 Growth and Decay. Uninhibited Growth of Cells.

Chapter 2 Solutions of 1 st Order Differential Equations.

Warm Up Dec. 19 Write and solve the differential equation that models the verbal statement. Evaluate the solution at the specified value. The rate of change.

Aim: Growth & Decay Course: Calculus Do Now: Aim: How do we solve differential equations dealing with Growth and Decay Find.

Ch. 7 – Differential Equations and Mathematical Modeling 7.4 Solving Differential Equations.

Exponential Functions Chapter 10, Sections 1 and 6.

3.8 - Exponential Growth and Decay. Examples Population Growth Economics / Finance Radioactive Decay Chemical Reactions Temperature (Newton’s Law of Cooling)

6.4 Exponential Growth and Decay Objective: SWBAT solve problems involving exponential growth and decay in a variety of applications.

Chapter 6 Integration Section 3 Differential Equations; Growth and Decay.

6.4 Exponential Growth and Decay. The number of bighorn sheep in a population increases at a rate that is proportional to the number of sheep present.

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

6.4 Exponential Growth and Decay Law of Exponential Change Continuously Compounded Interest Radioactivity Newton’s Law of Cooling Resistance Proportional.

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

Oh Sheep! 11.5 Exponential Growth and Decay

Applications of 1st Order Differential Equations

6.4 Growth and Decay.

Chapter 3: Elementary Applications

Exponential Growth and Decay

6.4 Exponential Growth and Decay, p. 350

6.2 Exponential Growth and Decay

7.4 Exponential Growth and Decay

6.4 day 2 Exponential Growth and Decay

7-4 Exponential Growth and Decay

6.4 Applications of Differential Equations

7.4 Exponential Growth and Decay Glacier National Park, Montana

Exponential Growth and Decay

Presentation transcript:

AP CALCULUS AB Chapter 6: Differential Equations and Mathematical Modeling Section 6.4: Exponential Growth and Decay

What you’ll learn about Separable Differential Equations Law of Exponential Change Continuously Compounded Interest Modeling Growth with Other Bases Newton’s Law of Cooling … and why Understanding the differential equation gives us new insight into exponential growth and decay.

Separable Differential Equation

Example Solving by Separation of Variables

Section 6.4 – Exponential Growth and Decay Law of Exponential Change If y changes at a rate proportional to the amount present and y = y0 when t = 0, then where k>0 represents growth and k<0 represents decay. The number k is the rate constant of the equation.

Section 6.4 – Exponential Growth and Decay From Larson: Exponential Growth and Decay Model If y is a differentiable function of t such that y>0 and y’=kt, for some constant k, then where C = initial value of y, and k = constant of proportionality (see proof next slide)

Section 6.4 – Exponential Growth and Decay Derivation of this formula:

Section 6.4 – Exponential Growth and Decay This corresponds with the formula for Continuously Compounded Interest This also corresponds to the formula for radioactive decay

Continuously Compounded Interest

Example Compounding Interest Continuously

Example Finding Half-Life Hint: When will the quantity be half as much?

Section 6.4 – Exponential Growth and Decay The formula for Derivation: half-life of a radioactive substance is

Newton’s Law of Cooling

Section 6.4 – Exponential Growth and Decay Another version of Newton’s Law of Cooling (where H=temp of object & T=temp of outside medium)

Example Using Newton’s Law of Cooling A temperature probe is removed from a cup of coffee and placed in water that has a temperature of T = 4.5 C. Temperature readings T, as recorded in the table below, are taken after 2 sec, 5 sec, and every 5 sec thereafter. Estimate the coffee's temperature at the time the temperature probe was removed. the time when the temperature probe reading will be 8 C. o S

Example Using Newton’s Law of Cooling Use time for L1 and T-Ts for L2 to fit an exponential regression equation to the data. This formula is T-Ts.

Section 6.4 – Exponential Growth and Decay Resistance Proportional to Velocity It is reasonable to assume that, other forces being absent, the resistance encountered by a moving object, such as a car coasting to a stop, is proportional to the object’s velocity. The resisting force opposing the motion is We can express that the resisting force is proportional to velocity by writing This is a differential equation of exponential change,