- •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
16.2 NewtonÕs Second Law for Rotational Motion |
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Fig. 16.11 Plot of θ (t ) for a |
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where w1 is the maximum wind velocity and T is the period of the wind. This is now implemented by changing the wind(t) function:
def wind(t):
%WIND Returns the wind veocity w(t) at the time t w1 = 20.0 # m/s
T = 1.0 #s
w = 0.5*w1*(1.0 + cos(2*pi*t/T)) return w
Now, we start the pendulum from θ (t0) = 0 and ω(t0) = 0rad/s, corresponding to the case where it hang straight down at rest before you start blowing periodically at it. The resulting behavior for T = 0.5 s, 1.0 s, 2.0 s and 4.0 s is shown in Fig. 16.11. What happens here? Play around with the model yourself to Þnd out what happens.
16.3 Rotational Motion Around a Moving Center of Mass
Figure 16.12 shows a rod being thrown across the lecture hall. After it has been thrown it is just affected by gravity and air resistance. We know that the motion of the center of mass of the object only depends on the external forces acting on the objectÑits motion is determined from NewtonÕs second law of motion. But what about the rotational motion around the center of mass? The rotational motion around the center of mass for a ridig body (rotating around a Þxed axis) is determined from NewtonÕs second law for rotational motion around the center of mass. (A proof is found in Sect. A.11)
Newton’s Second Law of Translational Motion
The motion of the center of mass of a rigid body, such as the rotating rod in Fig. 16.12 is determined from NewtonÕs second law for translational motion:
Fextj = M A . |
(16.43) |
j
This is true irrespective of how the system moves relatively to the center of mass. This means that the motion of the center of mass of the rod in Fig. 16.12 would be the same if the rod rotated or if it moved with the same angle all the time. But only if
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16 Dynamics of Rigid Bodies
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Fig. 16.12 Left The motion of a rigid rod thrown through the air, showing the motion of the center of mass and the rotational motion around the center of the mass. Right Free-body diagram for the rod
the external forces are the same! If we include the effects air resistance, the external forces depend on whether the rod is rotating or not, and the motion would not be exactly the same in the two situation.
Newton’s Second Law for Rotational Motion Around the Center of Mass
For a system rotating around a Þxed axis through the center of mass, the rotational motion is determined by NewtonÕs second law for rotational motion around the center of mass, which is just like NewtonÕs second law for rotation around a Þxed axis, but now all the torques must be taken around the center of mass:
τ cm = rcm × F , |
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where rcm is a vector from the center of mass to the point where the force F acts. Using this notation, we get:
NewtonÕs second law for a rigid body rotating around a fixed axis through the center of mass (the z-axis) is:
τz,cm, j = τznet,cm = Iz,cm αz , |
(16.45) |
j
where τ cm, j is the torque of force j around the center of mass, and Iz,cm is the moment of inertia (the rotational inertia) of the object around the Þxed rotational axis through its center of mass.
It may be confusing to call the axis Þxed if it is moving along with the center of mass. What we mean is that the axis has a Þxed direction: The direction of the rotation axis
16.3 Rotational Motion Around a Moving Center of Mass |
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Fig. 16.13 Top The motion of a rigid rod thrown through the air, showing the motion of the center of mass and the rotational motion around the center of the mass. The rod hits the ßoor, and bounces back up. Bottom Free-body diagram for the rod at Þve different times. When the rod is not in contact with the ßoor (the Þrst and the last inset) only gravity acts. When the rod is in contact with the ßoor (middle three insets) both gravity and a contact force from the ßoor act
does not change during the motion, but the position of the axis follows the center of mass. The application of the law is illustrated in Fig. 16.13. Here, we follow a rod thrown across the lecture hall also during its collision with the ßoor. The small insets at the bottom shows the forces acting on the rod at Þve different time steps. When the rod is not in contact with the ßoor, the only external force acting is gravity (we ignore air resistance), and since gravity acts in the center of mass, the torque of gravity around the center of mass is zero, and the angular acceleration is therefore zero: The rod rotates with a constant angular velocity. However, when the rod is in contact with the ßoor, as illustrated in the middle three insets, the contact force F from the ßoor on the rod gives rise to a net torque around the center of mass, which leads to an angular acceleration during the contact. The force F acts at the point rcm relative to the center of mass of the rod, giving rise to a torque: τ = rcm × F around the center of mass. We address the motion of a bouncing rod in Sect. 16.3.3.
16.3.1 Example: Kicking a Ball
Problem: You are kicking a stationary football lying on the ground. The ball is spherical, with a mass M , radius R, and moment of inertia I around the center of mass. You kick the ball with a constant force F = Fx i for a short time interval t .
508 16 Dynamics of Rigid Bodies
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Fig. 16.14 |
You are kicking a ballÑexerting a constant force F = Fx i for a small time interval t . |
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hitting the ball at a distance y from its center, as illustrated in Fig. 16.14. Find the motion of the ball during and after the kick. You may neglect the effects of friction and air resistance.
Approach: We plan to use NewtonÕs second law of motion to Þnd the motion of the center of mass from the external forces acting, and NewtonÕs second law for rotational motion around the center of mass to Þnd the rotational motion around the center for the ball during and after the kick.
Identify: We assume that the ball behaves as a rigid body and describe its motion by the position, R(t ) of its center of mass and its angle θ (t ) around the z-axis. The ball starts from rest: R(0 s) = 0 and θ (0 s) = 0.
Model: The translational and rotational motion depends on the external forces acting. The ball is affected by gravity, G = −M g k, acting at the center of mass, hence rG,cm = 0; the normal force N = N k from the ground, acting at rN ,cm = −R k; and the force F = F i from the foot, acting at rF,cm = −x i + y j, where x and y are given. All the positions are relative to the center of mass, since the acting points of the forces will move with the center of mass as the ball starts moving. The forces are illustrated in Fig. 16.14.
We apply NewtonÕs second law to Þnd the motion of the center of mass: |
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(16.46) |
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Since the applied force F only acts in the x -direction, we assume that the ball does not move in the y or z-directions. Therefore, the acceleration in the z-direction is zero and N = M g. The motion in the x -direction is given by:
M Ax = Fx |
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(16.47) |
M |
16.3 Rotational Motion Around a Moving Center of Mass |
509 |
starting from Vx = 0 m/s and X = 0 m at t = 0 s. Notice that the motion of the center of mass does not depend on the rotational motion of the ball, since (16.47) and the time, t , the force is acting does not depend on either the angle θ or the angular velocity ω of the ball!
The rotational motion of the ball is found from NewtonÕs second law for rotational motion around a Þxed axis around the center of mass. (How do we know the ball rotates around a Þxed axis? We know, since the direction of the torque does not change during the motionÑthis is an advanced point we will return to later in the chapter. For now you should consider this an assumption):
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which inserted in (16.48) gives: |
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where θ (0 s) = 0 and ω(0 s) = 0 rad/s.
Solve: Both the translational and the rotational motion occur with constant accelerations. We can therefore solve by direct integration to Þnd the positions and velocities. First, we Þnd the velocities:
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510 |
16 Dynamics of Rigid Bodies |
We integrate once more to Þnd the positions:
X (t ) = X (0) + 0 |
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However, this solution is only valid as long as the ball is affected by the force F, which only is for a time interval t . After that, the ball is not affected by the force F, and the net force in the x -direction is zero and the net torque is zero. Therefore the translational and the rotational accelerations are zero, and the ball continue with the same translational and rotational velocities:
V (t ) = V (Δt ) = |
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t when t > |
t . |
(16.56) |
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I |
Since the motion for t > t occurs with constant translational and angular velocities, it is easy to Þnd the position at a time t > t by integration:
X (t ) = X (Δt ) + V (Δt )(t − |
t ) when t > |
t , |
(16.57) |
and |
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θ (t ) = θ (Δt ) + ω(Δt )(t − |
t ) when t > |
t . |
(16.58) |
Analyze: We notice that the motion of the center of mass does not depend on yÑthe position where the force is acting. For any choice of y, the effect on the motion of the center of mass is the same. But the rotational motion depends on y. In particular, we notice that when y = 0, that is when the force acts on an axis through the center of mass, the net torque is zero, and the ball does not start to rotate. We also notice that if we kick the ball on the left side, with y > 0, the ball rotates in the negative direction, whereas if we kick the ball on the right side, with y < 0, the ball rotates in the positive direction, which is consistent with our experience with kicking balls. This is how you give them spin.
Comment: Notice that the translational and rotational motions are independent in this case. Why? Because the force acts at a constant distance y from the center of mass throughout the motion. Therefore the torque of F does not depend on the