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

Slides:

Advertisements

Similar presentations

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.

Advertisements

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.

2019 Related Rates AB Calculus.

4.6 Related Rates.

Section 2.6 Related Rates.

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

Section 2.6: Related Rates

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

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.

Teresita S. Arlante Naga City Science High School.

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

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.

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.

Sec 2.6 – Marginals and Differentials 2012 Pearson Education, Inc. All rights reserved Let C(x), R(x), and P(x) represent, respectively, the total cost,

2.8 Related Rates.

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

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.

Related Rates M 144 Calculus I V. J. Motto. The Related Rate Idea A "related rates" problem is a problem which involves at least two changing quantities.

Section 4.1: Related Rates Practice HW from Stewart Textbook (not to hand in) p. 267 # 1-19 odd, 23, 25, 29.

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.

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.

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

Related Rates 3.7. Finding a rate of change that cannot be easily measured by using another rate that can be is called a Related Rate problem. Steps for.

In this section, we will investigate the question: When two variables are related, how are their rates of change related?

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.

Warm-Up If x 2 + y 2 = 25, what is the value of d 2 y at the point (4,3)? dx 2 a) -25/27 c) 7/27 e) 25/27 b) -7/27 d) 3/4.

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.

Differentiation: Related Rates – Day 1

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.

4.1 - Related Rates ex: Air is being pumped into a spherical balloon so that its volume increases at a rate of 100cm 3 /s. How fast is the radius of the.

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

Sec 4.1 Related Rates Strategies in solving problems: 1.Read the problem carefully. 2.Draw a diagram or pictures. 3.Introduce notation. Assign symbols.

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

RELATED RATES Example 1 Air is being pumped into a spherical balloon so that its volume increases at a rate of 100 cm3/s. How fast is the radius of the.

6.5: RELATED RATES OBJECTIVE: TO USE IMPLICIT DIFFERENTIATION TO RELATE THE RATES IN WHICH 2 THINGS ARE CHANGING, BOTH WITH RESPECT TO TIME.

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.

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

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.

Mr. Moore is pushing the bottom end of a meter stick horizontally away from the wall at 0.25m/sec. How fast is the upper end of the stick falling down.

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.

Section 3.9 Related Rates AP Calculus October 15, 2009 Berkley High School, D2B2

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.

Review Implicit Differentiation Take the following derivative.

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.

MATH 1910 Chapter 2 Section 6 Related Rates.

Section 2-6 Related Rates

Calculus I (MAT 145) Dr. Day Monday Oct 23, 2017

Calculus I (MAT 145) Dr. Day Friday Oct 20, 2017

Calculus I (MAT 145) Dr. Day Friday, October 5, 2018

Differentiate. g(x) = 4 sec x + tan x

RATES OF CHANGE: GEOMETRIC.

Differentiate. g(x) = 8 sec x + tan x

Related Rates 2.7.

Section 2.6 Calculus AP/Dual, Revised ©2017

Math 180 Packet #9 Related Rates.

Calculus I (MAT 145) Dr. Day Wednesday February 27, 2019

§3.9 Related rates Main idea:

Related Rates Section 3.9.

Related Rates ex: Air is being pumped into a spherical balloon so that its volume increases at a rate of 100cm3/s. How fast is the radius of the balloon.

Presentation transcript:

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

Air is pumped into a spherical balloon so that its volume increases at a rate of 100cm 3 /s. How fast is the radius increasing when the diameter is 50cm?

Related Rates Guidelines 1. Make a sketch. Label all sides in terms of variables, even if you are given the actual values of the sides. 2. Make a list of variables. Separate them into variables that are constant (never change) and variables that are changing (variables that are a given value only at a certain point in time). Rates (recognized by “increasing”, “decreasing”, etc.) are derivatives with respect to time. They can go into either category. Be aware if the rate is positive or negative (increasing vs. decreasing over time). 3. Find an equation which ties your variables together. If it is an area problem, you need an area equation. If it is a right triangle, the Pythagorean formula may work, etc. 4. Plug in any variable that is constant. NEVER plug in a variable that is changing. 5. Use implicit differentiation to differentiate you equation with respect to time, t. 6. Plug in all variables and known rates. Solve for the unknown rate. 7. Label your answers in terms of the correct units ( very important), and be sure you answered the question asked.

Things to remember……  Words such as “rate” and “speed” are code words for derivative, where the underlying variable is time, t.  Be aware of positive vs. negative rates of change. Is “something” increasing or decreasing over time?  If “something” is constant or does not change over time, the rate of change, or derivative, is 0.

Ex. 1: Air is pumped into a spherical balloon so that its volume increases at a rate of 100cm 3 /s. How fast is the radius increasing when the diameter is 50cm?

Ex. 2: A 10 ft ladder is resting against a vertical wall when suddenly it starts to slide, with the bottom moving away from the wall at a rate of 1 ft/s. How fast is the top sliding down when the base is 6 feet from the wall?

Ex. 3 An inverted circular cone that has a radius of 2m and a height of 4 m is being filled with Slime at a rate of 2 m 3 /min. How fast is the height of the Slime increasing when it is 3m deep?

Ex. 4: A trough of water is 8 meters long and its ends are in the shape of isosceles triangles whose width is 5m and height is 2 m. Water is being pumped in at a constant rate of 6 m 3 /sec. At what rate is the height of the water changing when the water has a height of 1.2 m?

Ex. 5: You’re meeting your friend for breakfast at Percy’s in Kingston. If you’re driving south at 60mph and your friend is driving east at 50mph, how fast will you be approaching them when you’re 0.4 miles away and they’re 0.3 miles away?