Looking Ahead (12/5/08) Today – HW#4 handed out. Monday – Regular class Tuesday – HW#4 due at 4:45 pm Wednesday – Last class (evaluations etc.) Thursday.

Slides:

Advertisements

Similar presentations

Lesson 9-5 Logistic Equations. Logistic Equation We assume P(t) is constrained by limited resources so : Logistic differential equation for population.

Advertisements

1) Consider the differential equation

9/22 thru 9/26 Monday – Distributive Property – Slides 2 AND 3 Tuesday – Factor Linear Expressions – Slides 4 AND 5 Wednesday – Solutions of Equations.

Section 6.5: Partial Fractions and Logistic Growth.

Separation of Variables (11/24/08) Most differential equations are hard to solve exactly, i.e., it is hard to find an explicit description of a function.

Look Ahead Today – HW#4 out Monday – Regular class (not lab) Tuesday – HW#4 due at 4:45 Wednesday – Last class - return clickers Thursday – Regular office.

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.

Look Ahead (4/27/08) Tuesday – HW#4 due at 4:45 Wednesday – Last class – return clickers, review and overview, and do evaluations. Thursday – Regular office.

Saturday May 02 PST 4 PM. Saturday May 02 PST 10:00 PM.

Pre-Calc Monday Warm ups: Discuss/Review 11.5 WS from Friday Discussion/Notes/Guided Practice Section 11.6 Natural Logarithms Assignment: A#11.6.

Differential Equations 7. The Logistic Equation 7.5.

POPULATION DENSITY, DISTRIBUTION & GROWTH.  Density is a measure of how closely packed organisms are in a population  Calculated by … DENSITY # of individuals.

CHAPTER 2 The Logistic Equation 2.4 Continuity The Logistic Model:

CHAPTER Continuity Modeling with Differential Equations Models of Population Growth: One model for the growth of population is based on the assumption.

Warm up 3/19 Draw and label the graph for the Logistic model.

9 DIFFERENTIAL EQUATIONS.

(Tentative) Plan for Last Days of School. Friday 5/8 / Monday 5/11 Work on empathy final project Tuesday 5/12 / Wednesday 5/13 (MIN.) Work on empathy.

HW: p. 369 #23 – 26 (all) #31, 38, 41, 42 Pick up one.

6.5 Logistic Growth Model Years Bears Greg Kelly, Hanford High School, Richland, Washington.

BC Calculus – Quiz Review

C Applications of DE Calculus - Santowski 10/17/2015 Calculus - Santowski 1.

Clicker Question 1 The position of an object (in feet) is given by s (t ) = 4 + ln(t 2 ) where t is in seconds. What is the object’s velocity at time t.

One model for the growth of a population is based on the assumption that the population grows at a rate proportional to the size of the population. That.

Determine whether the function y = x³ is a solution of the differential equation x²y´ + 3y = 6x³.

6 Differential Equations

Thursday, May 31, 2007PHYS , Summer 2007 Dr. Jaehoon Yu 1 PHYS 1443 – Section 001 Lecture #3 Thursday, May 31, 2007 Dr. Jaehoon Yu One Dimensional.

Modeling with a Differential Equation

Section 7.5: The Logistic Equation Practice HW from Stewart Textbook (not to hand in) p. 542 # 1-13 odd.

The simplest model of population growth is dy/dt = ky, according to which populations grow exponentially. This may be true over short periods of time,

Test Corrections You may correct your test. You will get back 1/3 of the points you lost if you submit correct answers. This work is to be done on your.

The number of bighorn sheep in a population increases at a rate that is proportional to the number of sheep present (at least for awhile.) So does any.

We have used the exponential growth equation

Population Growth Biology Ch 5-1& 5-2. Exponential Growth  Under ideal conditions with unlimited resources and protection from predators/disease, a population.

Q2.W3 Math 8Monday 11/9/15 Today: o Welcome o Good things! o Essential Questions o Correct Lesson 4.2 Quiz Corrections due by Monday 11/16 Must show all.

LOGISTIC GROWTH.

Clicker Question 1 Consider the DE y ' = 4x. Using Euler’s method with  x = 0.5 and starting at (0, 0), what is the estimate for y when x = 2 ? – A. y.

9.4 The Logistic Equation Wed Jan 06 Do Now Solve the differential equation Y’ = 2y, y(0) = 1.

Chapter 5 Applications of Exponential and Natural Logarithm Functions.

2002 BC Question 5NO CalculatorWarm Up Consider the differential equation (a)The slope field for the given differential equation is provided. Sketch the.

Clicker Question 1 Suppose a population of gerbils starts with 20 individuals and grows at an initial rate of 6% per month. If the maximum capacity is.

Copyright © Cengage Learning. All rights reserved. 9 Differential Equations.

Welcome to Math 8 with Mrs. New! Monday, September 21 To-Do Before Class Starts: #1 Get a new Daily Warm-Up sheet and complete Monday’s. #2Have notes on.

1 6.1 Slope Fields and Euler's Method Objective: Solve differential equations graphically and numerically.

Problem of the Day - Calculator Let f be the function given by f(x) = 2e4x. For what value of x is the slope of the line tangent to the graph of f at (x,

Differential Equations 6 Copyright © Cengage Learning. All rights reserved.

Clicker Question 1 What is the degree 2 (i.e., quadratic) Taylor polynomial for f (x) = 1 / (x + 1) centered at 0? – A. 1 + x – x 2 / 2 – B. 1  x – C.

Daily Math Review September 2-6, Monday Solve the following problems with strategies and/or algorithms 5, = 9, = 3, =

Copyright © Cengage Learning. All rights reserved. 9.4 Models for Population Growth.

Final Exam Information These slides and more detailed information will be posted on the webpage later…

Solving Differential Equations Slope Fields. Solving DE: Slope Fields Slope Fields allow you to approximate the solutions to differential equations graphically.

Announcements Topics: -Introduction to (review of) Differential Equations (Chapter 6) -Euler’s Method for Solving DEs (introduced in 6.1) -Analysis of.

9/27/2016Calculus - Santowski1 Lesson 56 – Separable Differential Equations Calculus - Santowski.

Table of Contents 1. Section 5.8 Exponential Growth and Decay.

6-3 More Difficult Separation of Variables Rizzi – Calc BC.

Logistic Equations Sect. 8-6.

Differential Equations

Separation of Variables

Logistic Growth Columbian Ground Squirrel

Population Growth, Limiting Factors & Carrying Capacity

Unit 7 Test Tuesday Feb 11th

Calculus II (MAT 146) Dr. Day Monday, Oct 23, 2017

6.5 Logistic Growth.

AP Calculus AB/BC 6.5 Logistic Growth, p. 362.

Euler’s Method, Logistic, and Exponential Growth

Clicker Question 1 What is the general solution to the DE dy / dx = x(1+ y2)? A. y = arctan(x2 / 2) + C B. y = arctan(x2 / 2 + C) C. y = tan(x2 / 2)

Population Ecology Population Growth.

Clicker Question 1 Suppose a population of gerbils starts with 20 individuals and grows at an initial rate of 6% per month. If the maximum capacity is.

Logistic Growth 6.5 day 2 Columbian Ground Squirrel

Logistic Growth 6.5 day 2 Columbian Ground Squirrel

Presentation transcript:

Looking Ahead (12/5/08) Today – HW#4 handed out. Monday – Regular class Tuesday – HW#4 due at 4:45 pm Wednesday – Last class (evaluations etc.) Thursday – Regular office hours 3:15-4:45 Friday – Extra Help 11-noon (HW#4 returned) Tuesday (12/16) – Regular office hours Wednesday (12/17) – Exam 9-noon

Application of DE’s: Population Growth Let P be the size of a population and let t be time. We have seen already that if the population grows at a rate proportional to its size, this say that it satisfies the DE: dP / dt = k P, k being the relative growth rate. This is separable, and we know the general solution is P = A e kt where A is the starting population. This is, naturally, called exponential growth.

The Logistic Model of Growth Many populations may grow exponentially at first, but eventually that growth rate slows as capacity (space, food, etc.) is reached. That is, as time passes, k will approach 0. If the maximum capacity of the population is denoted M, a simple expression which approaches 0 as P approaches M is 1 – P / M.

The Logistic DE Thus a DE which would model this “exponential growth at first but slowing of the growth rate as P approaches its maximum capacity” would be

Example Suppose a population growing by the logistic model has a maximum capacity of 1000 and displays an initial growth rate of 8%. Look at the slope field. Look at an Euler’s Method approximate solution assuming an initial population of 2. Can we explicitly solve this DE? Is it separable?

Assignment Regular class on Monday. Work on HW#4. Test #2 corrections will be returned Monday.