Presentation is loading. Please wait.

Presentation is loading. Please wait.

Work and Energy A calculus-based perspective AP Physics C.

Published byDayna McKenzie Modified over 8 years ago

Similar presentations

Presentation on theme: "Work and Energy A calculus-based perspective AP Physics C."— Presentation transcript:

1 Work and Energy A calculus-based perspective AP Physics C

2

3 The old “special case” W=F d is a special case W=F d is a special case F must be in the direction of motion F must be in the direction of motion F is a constant force F is a constant force What if F is not parallel to d? What if F is not parallel to d? The Dot or Scalar Product. The Dot or Scalar Product. One vector times another to “make” a scalar One vector times another to “make” a scalar W= Fcos θ d W= Fcos θ d

4 If the graph below shows the force exerted by the Death Star’s Tractor beam. How could you calculate the work done on a ship being pulled from position a to b? A. Find the slope of the line between a and b B. Find the Area under the curve from point a to b C. Multiply force x (b-a)

5 Area Under the Curve For Hooke’s Law, the force is linear. For Hooke’s Law, the force is linear. For a force vs. distance graph, the work is just the area under the curve. The shape is a triangle. For a force vs. distance graph, the work is just the area under the curve. The shape is a triangle. What if the area under the curve is not geometric? What if the area under the curve is not geometric?

6 Finding an integral is a way of accurately finding the area under a curve. My looking at smaller and smaller “pieces” of x, multiplying them by the force, and summing them we can find total area. Most Forces aren’t constant. Springs Magnetic fields Pushes/pulls Gravity over large distances The Reality

7 Integration Rules!!

8 Example: Work done to stretch a spring. F(x) = kx F(x) = kx Hooke’s Law Hooke’s Law

9 How much work do you do if you stretch a spring from an initial position of 0m to the 1m position if the spring constant is 49 N/m A. 49 Nm B. 25 Nm C. 98 Nm D. 10 Nm

10 Work for a varying force

11 A force F(x) acts on a particle. The force is related to the position of the particle by the formula F(x) = Cx 3, where C is a constant. Find the work done by this force on the particle when the particle moves from x = 1.5 m to x = 3 m. A. 1 J B. 34 J C. 0 J D. 19C J

12 Solution

13 Energy

14 Work-Energy Theorem The change in the kinetic energy of an object is equal to the net work done on the object. The change in the kinetic energy of an object is equal to the net work done on the object.

15 Types of Force Conservative Conservative Obeys conservation of energy Obeys conservation of energy Examples Examples Spring force Spring force Gravity Gravity Non-conservative Energy is transferred into non-mechanical forms Examples Friction Air drag

16 Equilibrium Occurs when net force = 0 Occurs when net force = 0 If force = F(x), then equilibrium exists at points where F(x) = 0. If force = F(x), then equilibrium exists at points where F(x) = 0. Equilibrium exists where dU/dx = 0 Equilibrium exists where dU/dx = 0

17 Power

18 Power takes many forms

Download ppt "Work and Energy A calculus-based perspective AP Physics C."

Similar presentations

AP C UNIT 3 WORK & ENERGY.

AP C UNIT 3 WORK & ENERGY.
Kinetic Energy and Work; Potential Energy;Conservation of Energy. Lecture 07 Thursday: 5 February 2004.

Kinetic Energy and Work; Potential Energy;Conservation of Energy. Lecture 07 Thursday: 5 February 2004.
Energy and Energy Transfer

Energy and Energy Transfer
Rotational Dynamics Chapter 9.

Rotational Dynamics Chapter 9.
Fall wk 7 – Thus.11.Nov.04 Welcome, roll, questions, announcements Energy, work, and forces Review derivatives Spring workshop Energy Systems, EJZ.

Fall wk 7 – Thus.11.Nov.04 Welcome, roll, questions, announcements Energy, work, and forces Review derivatives Spring workshop Energy Systems, EJZ.
Phy 211: General Physics I Chapter 7: Kinetic Energy & Work Lecture Notes.

Phy 211: General Physics I Chapter 7: Kinetic Energy & Work Lecture Notes.
Work and Kinetic Energy. Work Done by a Constant Force The definition of work, when the force is parallel to the displacement: (7-1) SI unit: newton-meter.

Work and Kinetic Energy. Work Done by a Constant Force The definition of work, when the force is parallel to the displacement: (7-1) SI unit: newton-meter.
Conservation of Energy

Conservation of Energy
PHYS 218 sec. 517-520 Review Chap. 6 Work and Kinetic Energy.

PHYS 218 sec Review Chap. 6 Work and Kinetic Energy.
Chapter 7 Work and Kinetic Energy. Units of Chapter 7 Work Done by a Constant Force Kinetic Energy and the Work-Energy Theorem Work Done by a Variable.

Chapter 7 Work and Kinetic Energy. Units of Chapter 7 Work Done by a Constant Force Kinetic Energy and the Work-Energy Theorem Work Done by a Variable.
Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.

Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.
Chapter 6 Work & Energy.

Chapter 6 Work & Energy.
Notes - Energy A. Work and Energy. What is Energy?  Energy is the ability to produce change in an object or its environment.  Examples of forms of energy:

Notes - Energy A. Work and Energy. What is Energy?  Energy is the ability to produce change in an object or its environment.  Examples of forms of energy:
Work and Energy. Outcomes Upon completion of this unit you will be able to: Analyze force problems in terms of energy. Define the term work as it relates.

Work and Energy. Outcomes Upon completion of this unit you will be able to: Analyze force problems in terms of energy. Define the term "work" as it relates.
Physics C Energy 4/21/2017 Introduction to Work Bertrand.

Physics C Energy 4/21/2017 Introduction to Work Bertrand.
CONSERVATION LAWS PHY1012F WORK Gregor Leigh

CONSERVATION LAWS PHY1012F WORK Gregor Leigh
Work AP Physics C Mrs. Coyle.

Work AP Physics C Mrs. Coyle.
Test TODAY at 9:30 am in CNH-104 !!!

Test TODAY at 9:30 am in CNH-104 !!!
Work. Work is the product of the magnitude of the __________________ moved times the component of a ________________ in the direction of the ________________.

Work. Work is the product of the magnitude of the __________________ moved times the component of a ________________ in the direction of the ________________.
Chapter 7 Work and Energy Transfer. Section 7.1- Systems and Environments System- small portion of the universe being studied – Can be a single object.

Chapter 7 Work and Energy Transfer. Section 7.1- Systems and Environments System- small portion of the universe being studied – Can be a single object.

Similar presentations

Ads by Google