Related Rates Objective: To find the rate of change of one quantity knowing the rate of change of another quantity.

Slides:

Advertisements

Similar presentations

Related Rates Finding the rates of change of two or more related variables that are changing with respect to time.

Advertisements

4.6 Related Rates Any equation involving two or more variables that are differentiable functions of time t can be used to find an equation that relates.

1 Related Rates Section Related Rates (Preliminary Notes) If y depends on time t, then its derivative, dy/dt, is called a time rate of change.

2.6 Related Rates.

2019 Related Rates AB Calculus.

Related Rates TS: Explicitly assessing information and drawing conclusions.

Section 2.6 Related Rates.

Related Rates Kirsten Maund Dahlia Sweeney Background Calculus was invented to predict phenomena of change: planetary motion, objects in freefall, varying.

3.11 Related Rates Mon Dec 1 Do Now Differentiate implicitly in terms of t 1) 2)

Section 2.6: Related Rates

1. Read the problem, pull out essential information and identify a formula to be used. 2. Sketch a diagram if possible. 3. Write down any known rate of.

Section 2.8 Related Rates Math 1231: Single-Variable Calculus.

Objectives: 1.Be able to find the derivative of an equation with respect to various variables. 2.Be able to solve various rates of change applications.

Sec 2.6 Related Rates In related rates problems, one tries to find the rate at which some quantity is changing by relating it to other quantities whose.

8. Related Rates.

DERIVATIVES Related Rates In this section, we will learn: How to compute the rate of change of one quantity in terms of that of another quantity.

D1 - Related Rates IB Math HL, MCB4U - Santowski.

3.11 Related Rates Mon Nov 10 Do Now

Definition: When two or more related variables are changing with respect to time they are called related rates Section 2-6 Related Rates.

Section 2.6 Related Rates Read Guidelines For Solving Related Rates Problems on p. 150.

2.8 Related Rates.

Miss Battaglia AP Calculus Related rate problems involve finding the ________ at which some variable changes. rate.

1 Related Rates Finding Related Rates ● Problem Solving with Related Rates.

Related Rates Test Review

Aim: How do we find related rates when we have more than two variables? Do Now: Find the points on the curve x2 + y2 = 2x +2y where.

R ELATED R ATES. The Hoover Dam Oil spills from a ruptured tanker and spreads in a circular pattern. If the radius of the oil spill increases at a constant.

Related Rates Section 4.6a.

3.9 Related Rates 1. Example Assume that oil spilled from a ruptured tanker in a circular pattern whose radius increases at a constant rate of 2 ft/s.

Lesson 3-10a Related Rates. Objectives Use knowledge of derivatives to solve related rate problems.

RELATED RATES Section 2.6.

Ch 4.6 Related Rates Graphical, Numerical, Algebraic by Finney Demana, Waits, Kennedy.

RELATED RATES. P2P22.7 RELATED RATES  If we are pumping air into a balloon, both the volume and the radius of the balloon are increasing and their rates.

Section 4.6 Related Rates.

Related Rates. The chain rule and implicit differentiation can be used to find the rates of change of two or more related variables that are changing.

Related Rates. I. Procedure A.) State what is given and what is to be found! Draw a diagram; introduce variables with quantities that can change and constants.

6.5: Related Rates Objective: To use implicit differentiation to relate the rates in which 2 things are changing, both with respect to time.

Copyright © Cengage Learning. All rights reserved. 12 Further Applications of the Derivative.

Miss Battaglia AP Calculus Related rate problems involve finding the ________ at which some variable changes. rate.

Lesson 3-10b Related Rates. Objectives Use knowledge of derivatives to solve related rate problems.

Calculus and Analytical Geometry Lecture # 9 MTH 104.

Differentiation: Related Rates – Day 1

1 §3.4 Related Rates. The student will learn about related rates.

Related Rates Section 4.6. First, a review problem: Consider a sphere of radius 10cm. If the radius changes 0.1cm (a very small amount) how much does.

3.11 Related Rates Tues Nov 10 Do Now Differentiate implicitly in terms of t 1) 2)

Related Rates Objective: To find the rate of change of one quantity knowing the rate of change of another quantity.

Bonaventura Francesco Cavalieri 1598 – 1647 Bonaventura Francesco Cavalieri 1598 – 1647 Bonaventura Cavalieri was an Italian mathematician who developed.

DO NOW Approximate 3 √26 by using an appropriate linearization. Show the computation that leads to your conclusion. The radius of a circle increased from.

4.1 Related Rates Greg Kelly, Hanford High School, Richland, Washington.

5.8: Intermediate Related Rates. Sand is poured on a beach creating a cone whose radius is always equal to twice its height. If the sand is poured at.

Drill: find the derivative of the following 2xy + y 2 = x + y 2xy’ +2y + 2yy’ = 1 + y’ 2xy’ + 2yy’ – y’ = 1 – 2y y’(2x + 2y – 1) = 1 – 2y y’ = (1-2y)/(2x.

Implicit Differentiation & Related Rates Review. Given: y = xtany, determine dy/dx.

4.6 RELATED RATES. STRATEGIES FOR SOLVING RELATED RATES PROBLEMS 1.READ AND UNDERSTAND THE PROBLEM. 2.DRAW AND LABEL A PICTURE. DISTINGUISH BETWEEN CONSTANT.

Calculus - Santowski 3/6/2016Calculus - Santowski1.

Related Rates ES: Explicitly assessing information and drawing conclusions.

Section 4.6 Related Rates. Consider the following problem: –A spherical balloon of radius r centimeters has a volume given by Find dV/dr when r = 1 and.

Related Rates 3.6.

3.9 Related Rates In this section, we will learn: How to compute the rate of change of one quantity in terms of that of another quantity. DIFFERENTIATION.

Examples of Questions thus far…. Related Rates Objective: To find the rate of change of one quantity knowing the rate of change of another quantity.

Logarithmic Differentiation 对数求导. Example 16 Example 17.

Warm-up A spherical balloon is being blown up at a rate of 10 cubic in per minute. What rate is radius changing when the surface area is 20 in squared.

3.10 – Related Rates 4) An oil tanker strikes an iceberg and a hole is ripped open on its side. Oil is leaking out in a near circular shape. The radius.

Warm up 1. Calculate the area of a circle with diameter 24 ft. 2. If a right triangle has sides 6 and 9, how long is the hypotenuse? 3. Take the derivative.

Section 2-6 Related Rates

4.6 Related Rates.

Related Rates AP Calculus AB.

Background Calculus was invented to predict phenomena of change: planetary motion, objects in freefall, varying populations, etc. In many practical applications,

Related Rates and Applications

Applications of Differentiation

Presentation transcript:

Related Rates Objective: To find the rate of change of one quantity knowing the rate of change of another quantity.

Related Rates When looking at water draining from a cone, we notice that the radius and height of the water changes as the volume changes. If we are interested in the rate of change of the volume with respect to time, we need to take the derivative of the volume function.

Related Rates This is called a related rates problem because the goal is to find an unknown rate of change by relating it to other variables whose values and whose rates of change at time t are known or can be found.

Example 1 Suppose that x and y are differentiable functions of t and are related by the equation . Find at time t = 1 if x = 2 and at time t = 1.

Strategies for Solving Related Rates Assign letters to all quantities that vary with time Identify the rates of change that are known and the rate of change that is to be found Find an equation (Area, Volume, Pythagorean Theorem, Trig Ratio) that relates variables Differentiate both sides with respect to time AFTER differentiating both sides, substitute all known values and solve

Example 2 Assume that oil spilled from a ruptured tanker spreads in a circular pattern whose radius increases at a constant rate of 2ft/s. How fast is the area of the spill increasing when the radius of the spill is 60ft?

Example 2 Assume that oil spilled from a ruptured tanker spreads in a circular pattern whose radius increases at a constant rate of 2ft/s. How fast is the area of the spill increasing when the radius of the spill is 60ft? We are looking for dA/dt. We know dR/dt = 2 ft/s. We know that r = 60 ft.

Example 2 Assume that oil spilled from a ruptured tanker spreads in a circular pattern whose radius increases at a constant rate of 2ft/s. How fast is the area of the spill increasing when the radius of the spill is 60ft? We are looking for dA/dt. We know dR/dt = 2 ft/s. We know that r = 60 ft.

Example 2 Assume that oil spilled from a ruptured tanker spreads in a circular pattern whose radius increases at a constant rate of 2ft/s. How fast is the area of the spill increasing when the radius of the spill is 60ft? We are looking for dA/dt. We know dR/dt = 2 ft/s. We know that r = 60 ft.

Example 3 A 25-foot ladder is leaning against a wall. If the top of the ladder slips down the wall at a rate of 2ft/s, how fast will the foot be moving away from the wall when the top of the ladder is 7 feet above the ground?

Example 4 A camera is mounted at a point 3000 ft from the base of a rocket launching pad. If the rocket is rising vertically at 880 ft/s when it is 4000 ft above the launching pad, how fast must the camera elevation angle change at that instant to keep the camera aimed at the rocket?

Example 4 A camera is mounted at a point 3000 ft from the base of a rocket launching pad. If the rocket is rising vertically at 880 ft/s when it is 4000 ft above the launching pad, how fast must the camera elevation angle change at that instant to keep the camera aimed at the rocket? t = time in seconds = angel of elevation h = height of rocket

Example 4 A camera is mounted at a point 3000 ft from the base of a rocket launching pad. If the rocket is rising vertically at 880 ft/s when it is 4000 ft above the launching pad, how fast must the camera elevation angle change at that instant to keep the camera aimed at the rocket? t = time in seconds = angel of elevation h = height of rocket

Example 4 We need to take the derivative to find the answer.

Homework Pages 221-223 1 – 9 odd 13 – 17 odd #21 Let’s do 9 and 13 NOW together