3.4 Velocity, Speed, and Rates of Change

Slides:

Advertisements

Similar presentations

3.4 Velocity, Speed, and Rates of Change Created by Greg Kelly, Hanford High School, Richland, Washington Revised by Terry Luskin, Dover-Sherborn HS, Dover,

Advertisements

Motion and Force A. Motion 1. Motion is a change in position

 Example 1:  Find the rate of change of the Area of a circle with respect to its radius.  Evaluate the rate of change of A at r = 5 and r = 10.  If.

2.1 Derivatives and Rates of Change. The slope of a line is given by: The slope of the tangent to f(x)=x 2 at (1,1) can be approximated by the slope of.

3.4 Velocity, Speed, and Rates of Change

3.4 Velocity, Speed, and Rates of Change Consider a graph of displacement (distance traveled) vs. time. time (hours) distance (miles) Average velocity.

3.4 Velocity and Other Rates of Change

Kinematics Demo – Ultrasonic locator Graph representation.

Denver & Rio Grande Railroad Gunnison River, Colorado

3.1 Derivative of a Function

1 Instantaneous Rate of Change  What is Instantaneous Rate of Change?  We need to shift our thinking from “average rate of change” to “instantaneous.

3.3 –Differentiation Rules REVIEW: Use the Limit Definition to find the derivative of the given function.

3.4 Velocity, Speed, and Rates of ChangeVelocitySpeedRates of Change.

3.4 Velocity and Rates of Change

The derivative as the slope of the tangent line

Motion ISCI Speed Speed: change in distance over time Speed =  d /  t Constant vs. Average Speed Speed is a ‘scalar’ quantity – No directional.

Motion in One Dimension Average Versus Instantaneous.

3.4 Velocity, Speed, and Rates of Change. downward , 8.

Lesson 3-4: Velocity, Speed, and Rates of Change AP Calculus Mrs. Mongold.

Physics Chapter 5. Position-Time Graph  Time is always on the x axis  The slope is speed or velocity Time (s) Position (m) Slope = Δ y Δ x.

3.4 Velocity, Speed, and Rates of Change

3.4 Velocity, Speed, and Rates of ChangeVelocitySpeedRates of Change.

Physics 203 – College Physics I Department of Physics – The Citadel Physics 203 College Physics I Fall 2012 S. A. Yost Chapter 2 Motion in 1 Dimension.

Chapter 2 One-Dimensional Kinematics. Units of Chapter 2 Position, Distance, and Displacement Average Speed and Velocity Instantaneous Velocity Acceleration.

Warm-Up: (let h be measured in feet) h(t) = -5t2 + 20t + 15

Motion ISCI Speed: change in distance over time Speed =  d /  t Constant vs. Average Speed Speed is a ‘scalar’ quantity No directional properties.

2.1 Position, Velocity, and Speed 2.1 Displacement  x  x f - x i 2.2 Average velocity 2.3 Average speed  

2.2 Differentiation Techniques: The Power and Sum-Difference Rules 1.5.

Unit 2- Force and Motion Vocabulary- Part I. Frame of Reference  A system of objects that are not moving with respect to each other.

l The study of HOW objects move: è Graphs è Equations è Motion maps è Verbal descriptions Kinematics-1.

Force and Motion Unit Vocabulary Week 1. S8P3a Determine the relationship between velocity and acceleration.

Speed: Average Velocity: Instantaneous Velocity:

Instantaneous Rate of Change The instantaneous rate of change of f with respect to x is.

Copyright © 2010 Pearson Education, Inc. Chapter 2 One-Dimensional Kinematics.

Motion graphs Position (displacement) vs. time Distance vs. time

Chapter 4 Linear Motion. Position, Distance, and Displacement Position: being able to describe an object’s location is important when things start to.

Chapter 3.4 Velocity and Other Rates of Change. Objectives Use derivatives to analyze straight line motion. Solve problems involving rates of change.

Motion Chapter 2 Part 1 1. What kind of motion will this car undergo? 2.

Sect. 3-A Position, Velocity, and Acceleration

Tippecanoe HS AP PHYSICS

Speed vs. Velocity.

LINEAR MOTION CHAPTER 2.

2.7 Derivatives and Rates of Change

Position vs. time graphs Review (x vs. t)

Non-Constant Velocity

Describing Motion.

3.4 Velocity and Other Rates of Change, p. 127

Derivative of a Function

Speed How fast does it go?.

Denver & Rio Grande Railroad Gunnison River, Colorado

Period 2 Question 1.

Motion and Force A. Motion 1. Motion is a change in position

Speed and Velocity What is Speed and Velocity?.

Denver & Rio Grande Railroad Gunnison River, Colorado

Contents: 2-1E, 2-5E, 2-9P, 2-13P, 2-33P, 2-36P*

Unit 2- Force and Motion Vocabulary- Part I.

Unit One The Newtonian Revolution

Velocity, Speed, and Rates of Change

Speed, velocity and acceleration

3.4 Velocity and Other Rates of Change

Denver & Rio Grande Railroad Gunnison River, Colorado

3.3 Velocity, Speed, and Rates of Change

Chapter 4 Linear Motion.

Velocity-Time Graphs for Acceleration

2.4 The Derivative.

Presentation transcript:

3.4 Velocity, Speed, and Rates of Change

Bell Ringer Solve even #’s

Consider a graph of displacement (distance traveled) vs. time. Average velocity can be found by taking: time (hours) distance (miles) B A The speedometer in your car does not measure average velocity, but instantaneous velocity. (The velocity at one moment in time.)

Velocity is the first derivative of position.

Speed is the absolute value of velocity. Example: Free Fall Equation Gravitational Constants: Speed is the absolute value of velocity.

Acceleration is the derivative of velocity. example: If distance is in: Velocity would be in: Acceleration would be in:

It is important to understand the relationship between a position graph, velocity and acceleration: time distance acc neg vel pos & decreasing acc neg vel neg & decreasing acc zero vel neg & constant acc zero vel pos & constant acc pos vel neg & increasing velocity zero acc pos vel pos & increasing acc zero, velocity zero

Rates of Change: Average rate of change = Instantaneous rate of change = These definitions are true for any function. ( x does not have to represent time. )

Instantaneous rate of change of the area with respect to the radius. Example 1: For a circle: Instantaneous rate of change of the area with respect to the radius. For tree ring growth, if the change in area is constant then dr must get smaller as r gets larger.

from Economics: Marginal cost is the first derivative of the cost function, and represents an approximation of the cost of producing one more unit.

Suppose it costs: to produce x stoves. Example 13: Suppose it costs: to produce x stoves. If you are currently producing 10 stoves, the 11th stove will cost approximately: Note that this is not a great approximation – Don’t let that bother you. The actual cost is: marginal cost actual cost

Note that this is not a great approximation – Don’t let that bother you. Marginal cost is a linear approximation of a curved function. For large values it gives a good approximation of the cost of producing the next item. p

Homework: 3.4a 3.4 p135 1,14 3.3 p124 40 p126 1,2,3,4 1.4 p34 17,23 3.4b 3.4 p135 9,18,21,27,35 1.5 p44 9,18,27,36,43 (practice test – extra credit)