- •Preface
- •Contents
- •1 Introduction
- •1.1 Physics
- •1.2 Mechanics
- •1.3 Integrating Numerical Methods
- •1.4 Problems and Exercises
- •1.5 How to Learn Physics
- •1.5.1 Advice for How to Succeed
- •1.6 How to Use This Book
- •2 Getting Started with Programming
- •2.1 A Python Calculator
- •2.2 Scripts and Functions
- •2.3 Plotting Data-Sets
- •2.4 Plotting a Function
- •2.5 Random Numbers
- •2.6 Conditions
- •2.7 Reading Real Data
- •2.7.1 Example: Plot of Function and Derivative
- •3 Units and Measurement
- •3.1 Standardized Units
- •3.2 Changing Units
- •3.4 Numerical Representation
- •4 Motion in One Dimension
- •4.1 Description of Motion
- •4.1.1 Example: Motion of a Falling Tennis Ball
- •4.2 Calculation of Motion
- •4.2.1 Example: Modeling the Motion of a Falling Tennis Ball
- •5 Forces in One Dimension
- •5.1 What Is a Force?
- •5.2 Identifying Forces
- •5.3.1 Example: Acceleration and Forces on a Lunar Lander
- •5.4 Force Models
- •5.5 Force Model: Gravitational Force
- •5.6 Force Model: Viscous Force
- •5.6.1 Example: Falling Raindrops
- •5.7 Force Model: Spring Force
- •5.7.1 Example: Motion of a Hanging Block
- •5.9.1 Example: Weight in an Elevator
- •6 Motion in Two and Three Dimensions
- •6.1 Vectors
- •6.2 Description of Motion
- •6.2.1 Example: Mars Express
- •6.3 Calculation of Motion
- •6.3.1 Example: Feather in the Wind
- •6.4 Frames of Reference
- •6.4.1 Example: Motion of a Boat on a Flowing River
- •7 Forces in Two and Three Dimensions
- •7.1 Identifying Forces
- •7.3.1 Example: Motion of a Ball with Gravity
- •7.4.1 Example: Path Through a Tornado
- •7.5.1 Example: Motion of a Bouncing Ball with Air Resistance
- •7.6.1 Example: Comet Trajectory
- •8 Constrained Motion
- •8.1 Linear Motion
- •8.2 Curved Motion
- •8.2.1 Example: Acceleration of a Matchbox Car
- •8.2.2 Example: Acceleration of a Rotating Rod
- •8.2.3 Example: Normal Acceleration in Circular Motion
- •9 Forces and Constrained Motion
- •9.1 Linear Constraints
- •9.1.1 Example: A Bead in the Wind
- •9.2.1 Example: Static Friction Forces
- •9.2.2 Example: Dynamic Friction of a Block Sliding up a Hill
- •9.2.3 Example: Oscillations During an Earthquake
- •9.3 Circular Motion
- •9.3.1 Example: A Car Driving Through a Curve
- •9.3.2 Example: Pendulum with Air Resistance
- •10 Work
- •10.1 Integration Methods
- •10.2 Work-Energy Theorem
- •10.3 Work Done by One-Dimensional Force Models
- •10.3.1 Example: Jumping from the Roof
- •10.3.2 Example: Stopping in a Cushion
- •10.4.1 Example: Work of Gravity
- •10.4.2 Example: Roller-Coaster Motion
- •10.4.3 Example: Work on a Block Sliding Down a Plane
- •10.5 Power
- •10.5.1 Example: Power Exerted When Climbing the Stairs
- •10.5.2 Example: Power of Small Bacterium
- •11 Energy
- •11.1 Motivating Examples
- •11.2 Potential Energy in One Dimension
- •11.2.1 Example: Falling Faster
- •11.2.2 Example: Roller-Coaster Motion
- •11.2.3 Example: Pendulum
- •11.2.4 Example: Spring Cannon
- •11.3 Energy Diagrams
- •11.3.1 Example: Energy Diagram for the Vertical Bow-Shot
- •11.3.2 Example: Atomic Motion Along a Surface
- •11.4 The Energy Principle
- •11.4.1 Example: Lift and Release
- •11.4.2 Example: Sliding Block
- •11.5 Potential Energy in Three Dimensions
- •11.5.1 Example: Constant Gravity in Three Dimensions
- •11.5.2 Example: Gravity in Three Dimensions
- •11.5.3 Example: Non-conservative Force Field
- •11.6 Energy Conservation as a Test of Numerical Solutions
- •12 Momentum, Impulse, and Collisions
- •12.2 Translational Momentum
- •12.3 Impulse and Change in Momentum
- •12.3.1 Example: Ball Colliding with Wall
- •12.3.2 Example: Hitting a Tennis Ball
- •12.4 Isolated Systems and Conservation of Momentum
- •12.5 Collisions
- •12.5.1 Example: Ballistic Pendulum
- •12.5.2 Example: Super-Ball
- •12.6 Modeling and Visualization of Collisions
- •12.7 Rocket Equation
- •12.7.1 Example: Adding Mass to a Railway Car
- •12.7.2 Example: Rocket with Diminishing Mass
- •13 Multiparticle Systems
- •13.1 Motion of a Multiparticle System
- •13.2 The Center of Mass
- •13.2.1 Example: Points on a Line
- •13.2.2 Example: Center of Mass of Object with Hole
- •13.2.3 Example: Center of Mass by Integration
- •13.2.4 Example: Center of Mass from Image Analysis
- •13.3.1 Example: Ballistic Motion with an Explosion
- •13.4 Motion in the Center of Mass System
- •13.5 Energy Partitioning
- •13.5.1 Example: Bouncing Dumbbell
- •13.6 Energy Principle for Multi-particle Systems
- •14 Rotational Motion
- •14.2 Angular Velocity
- •14.3 Angular Acceleration
- •14.3.1 Example: Oscillating Antenna
- •14.4 Comparing Linear and Rotational Motion
- •14.5 Solving for the Rotational Motion
- •14.5.1 Example: Revolutions of an Accelerating Disc
- •14.5.2 Example: Angular Velocities of Two Objects in Contact
- •14.6 Rotational Motion in Three Dimensions
- •14.6.1 Example: Velocity and Acceleration of a Conical Pendulum
- •15 Rotation of Rigid Bodies
- •15.1 Rigid Bodies
- •15.2 Kinetic Energy of a Rotating Rigid Body
- •15.3 Calculating the Moment of Inertia
- •15.3.1 Example: Moment of Inertia of Two-Particle System
- •15.3.2 Example: Moment of Inertia of a Plate
- •15.4 Conservation of Energy for Rigid Bodies
- •15.4.1 Example: Rotating Rod
- •15.5 Relating Rotational and Translational Motion
- •15.5.1 Example: Weight and Spinning Wheel
- •15.5.2 Example: Rolling Down a Hill
- •16 Dynamics of Rigid Bodies
- •16.2.1 Example: Torque and Vector Decomposition
- •16.2.2 Example: Pulling at a Wheel
- •16.2.3 Example: Blowing at a Pendulum
- •16.3 Rotational Motion Around a Moving Center of Mass
- •16.3.1 Example: Kicking a Ball
- •16.3.2 Example: Rolling down an Inclined Plane
- •16.3.3 Example: Bouncing Rod
- •16.4 Collisions and Conservation Laws
- •16.4.1 Example: Block on a Frictionless Table
- •16.4.2 Example: Changing Your Angular Velocity
- •16.4.3 Example: Conservation of Rotational Momentum
- •16.4.4 Example: Ballistic Pendulum
- •16.4.5 Example: Rotating Rod
- •16.5 General Rotational Motion
- •Index
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11 Energy |
Potential Energy of Many Individual Forces
In generatl, objects are affected by several forces simultaneously. For example, a person jumping on a trampoline is affected both by gravity and by the contact force from the trampoline. How can we extend our energy conservation approach to such cases?
The net force on an object affected by several forces F j , where j = 1, 2, . . . , is
F net = |
F j (x ) . |
(11.34) |
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Let us assume that each of the forces F j (x ) are conservative, that is, they depend on the position x only (and not on velocity or time). The potential energy for force F j (x ) is U j (x ). The work-energy theorem for a motion from x0 to x1 gives:
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F netd x = x0 j |
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U j (x0) − U j (x1) |
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(11.35) |
We move all the terms relating to position 0 to the right-hand side of the equation:
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(11.36) |
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where the potential energy U (x ) is the sum of the potential energies for each of the forces F j (x ). This gives a general law for energy conservation:
U (x1) + K1 = U (x0) + K0 . |
(11.37) |
We can therefore generalize the energy conservation methods introduced above by introducing a potential energy for each of the forces affecting the object. Energy conservation still holds, as long as we include the sum of all the potential energies for all the forces affecting the object.
11.2.1 Example: Falling Faster
Problem: You throw an apple directly downward from a high cliff, giving it an initial velocity v0. How far does the apple need to fall before it doubles its velocity? You can neglect the effects of air resistance.
11.2 Potential Energy in One Dimension |
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Identify: The position of the apple is given by y(t ). At t0, the apple is at y = y0 with velocity v = −v0. At t1, the apple is at y = y1 with velocity v1 = −2v0.
Model: The only force acting on the apple is gravity. We know that for motion under gravity, the total mechanical energy of the object is conserved throughout the motion:
E = U + K = constant |
(11.38) |
We use this to find the relation between the position and velocity of the apple.
Solve: The mechanical energy of the apple when at y0 is:
E0 = U0 + K0 = mgy0 + 1 mv2 ,
2 0
and at y1 it is:
E1 = U1 + K1 = mgy1 + 1 mv2 .
2 1
Since energy is conserved, we know that:
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(11.39)
(11.40)
(11.41)
We want to find y1 when we know that v1 = −2v0. We insert v1 = −2v0, and find:
mgy0 + |
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mv02 = mgy1 + |
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m (−2v0)2 . |
(11.42) |
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We solve for y1, finding the position where the velocity is doubled:
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11.2.2 Example: Roller-Coaster Motion
Problem: Let us revisit the roller-coaster problem using an energy conservation approach: A roller-coaster cart is rolling from the height h to the height 0 along a curving roller-coaster track. It starts with the speed v0 at the top of the track. Find the speed of the roller-coaster cart at the bottom of the track. You can ignore air resistance and friction.
Identify: The cart moves from the position 0, x (t0) = x0, y(t0) = y0, to position 1, x (t1) = x1, y(t1) = y1 as illustrated in Fig. 11.6.
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Fig. 11.6 A roller-coaster cart moving along a roller-coaster track
11 Energy
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Model: The cart is affected by the normal force, N, the friction force, f , and gravity, G = −mg j. We assume that friction is negligible, f = 0 throughout the motion. Solve: Since the normal force, N, does no work on the cart during the motion, we can use the conservation of energy to determine the relation between position and velocity of the cart. The conservation of mechanical energy of the cart gives:
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E = K0 + U0 = K1 + U1 , |
(11.44) |
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where we use that U (y) = mgy: |
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mv02 + mgy0 = |
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(11.45) |
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From this equation, we find the velocity v1 as a function of the height difference, h = y0 − y1 and the initial velocity v0 of
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mv02 + mg (y0 − y1) v12 = v02 + 2gh . |
(11.46) |
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Analyze: This is, of course, exactly the same result as we found above when we used the net work-energy theorem. However, the use of energy considerations is much simpler and allows us to use more of our intuition about the process than the application of the net work-energy theorem.
11.2.3 Example: Pendulum
Problem: A classical problem is that of the motion of a pendulum. A pendulum consists of sphere of mass m hanging in a massless rope of the length L . The pendulum moves in a vertical plane with a maximum angle θ0 with the vertical. Find the velocity v of the sphere as a function of the angle θ . We neglect air resistance.
Identify: We describe the motion of the pendulum with the angle θ between the rope and the vertical. We assume that the sphere follows a circular path. The system is illustrated in Fig. 11.7.
11.2 Potential Energy in One Dimension
Fig. 11.7 Left Illustration of a pendulum. Right Free-body diagram for the sphere
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Model: The sphere is affected by the tension, T, from the rope and gravity, G. We already know that for motion under gravity we can use energy considerations to relate position and velocity. What about the tension T? It is always normal to the direction of motion of the sphere. The rope tension T is a normal force, which does no work during the motion. We can therefore use energy conservation to solve the problem.
We examine two positions, as illustrated in Fig. 11.8, and use energy conservation to relate the two positions. In position 0 the sphere is at the top of its path. This is where the motion changes direction. The velocity is zero at this position. In position 1 the sphere is at an angle θ and the velocity of the sphere is v.
Energy conservation gives:
E = U0 |
+ K0 |
= U + K , |
(11.47) |
E = mgy0 |
+ K0 |
= mgy + K , |
(11.48) |
In order to find the velocities as a function of θ , we need to relate the vertical positions y0 and y to the angle θ . From Fig. 11.8 we see that the vertical position of the sphere is
y0 = −L cos θ0 and y = −L cos θ , |
(11.49) |
where we have chosen the origin of the coordinate system to at the attachment point of the pendulum. We insert this into (11.48):
− mg L cos θ0 + |
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mv02 = −mg L cos θ + |
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mv2 , |
(11.50) |
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Fig. 11.8 Illustration of the positions. In postion 0 (left) the sphere is at the top of its path. In position 1 (right) the sphere is at the angle θ
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