- •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
462 |
15 Rotation of Rigid Bodies |
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Fig. 15.3 A rod is thrown across the room. The top figure shows the motion of the rod. The bottom left figure shows the motion of the center of mass of the rod, and the bottom right figure shows the motion of the rod relative to the center of mass
15.3 Calculating the Moment of Inertia
The moment of inertia around an axis O of a system of particles with masses mi at positions ri is:
The moment of inertia around an axis O: is defined as |
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where ρi is the distance from particle i to the axis O.
Notice that the moment of inertia is not only a property of the object, it also depends on the axis of rotation, and the moment of inertia of a given object around different axes may be different, as illustrated below. A common mistake is to forget that the moment of inertia depends both on the object and on the axis, and that the moment of inertia changes if we change the axis.
15.3 Calculating the Moment of Inertia |
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I /M L 2
O O O O O O O M P
M P
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Fig. 15.4 Illustration of a hammer where all the mass is located in the point P in the head of the hammer. The hammer rotates around the point O, and the moment of inertia of a hammer depends on the distance R from the rotation axis to the hammer head
The moment of inertia depends on both the mass and how it is distributed around the rotation axis. Figure 15.4 illustrates a hammer consisting of a heavy head of mass M attached to an effectively massless rod. (You can assume that all of the mass of the head is located in the marked point, P ). The moment of inertia of the hammer is
IO = M R2 , |
(15.14) |
where R is the distance from the head, P , to the rotation axis O. We can therefore change the moment of inertia by changing the mass of the head, or by changing the distance from the head to the rotation axis. If you rotate it as a pendulum from your hand this corresponds to changing your grip (point O), since this will change the position of the rotation axis. As you move your grip closer to the head, the moment of inertia becomes smaller, and it becomes easier (requires less energy) to give the hammer a certain angular velocity. Pulling mass in towards the axis of rotation reduces the moment of inertia, pushing it further out from the axis increases it.
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15 Rotation of Rigid Bodies |
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Fig. 15.5 Moments of inertia for various solid bodies
15.3 Calculating the Moment of Inertia |
465 |
The moment of inertia of a hammerhead of dimensions h × w × d (h is height, w is width, and d is depth) around its center O can be found from Fig. 15.5, where we see that the moment of inertia of a plate around its center is
Icm = |
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h2 + w2 . |
(15.16) |
12 M |
This is therefore the real moment of inertia of the hammer when R = 0 m in the example above.
Parallel-Axis Theorem
We have now found a way to calculate the moment of inertia for a continuous object such as the hammer. But what if we now want to know the moment of inertia of the hammerhead for a different rotation axis—what if we want to know it as a function of the distance, R, from the center of the hammerhead to the rotation axis as illustrated in Fig. 15.6?
We could of course calculate the moment of inertia using the integral formulation in (15.15) for each position of the rotation axis. But this is cumbersome. Fortunately, it turns out that it is sufficient to calculate the moment of inertia around an axis through the center of mass. From this moment of inertia, we can find the moment of inertia around any other parallel axis using the parallel-axis theorem:
Parallel-axis theorem: The moment of inertia, IO , of an object around an axis O is related to the moment of inertia, Icm , of the object around a parallel axis through the center of mass of the object by:
IO = Icm + M s2 , |
(15.17) |
where M is the mass of the object, and s is the distance between the axis O and the parallel axis through the center of mass.
Fig. 15.6 A hammer consisting of a hammerhead (blue) of mass M and a thin rod (either massless or of a mass m)
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466 |
15 Rotation of Rigid Bodies |
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Fig. 15.7 Illustration of the parallel-axis theorem. The moment of inertia around an axis C through the center of mass can be used to find the moment of inertia around an axis O—if the axis O is parallel to the axis C through the center of mass. The vector s is perpendicular to both axes, and points from the origin of axis C to the origin of axis O
(You can find a proof in Sect. A.5). The theorem is illustrated in Fig. 15.7. We can use the parallel-axis theorem to find the moment of inertia around any axis if we only know the moment of inertia around the center of mass. This is why you usually only find tabulated the moment of inertia of an object around its center of mass: Given this, you can use the parallel-axis theorem to find the moment of inertia for any other parallel axis.
We can use the parallel-axis theorem to find the moment of inertia of the hammer as a function of the distance R from the center of the hammerhead to the rotation axis—it is simply given by:
IO = Icm + M R2 , |
(15.18) |
as long as the two rotation axes are parallel. This allows us to calculate the moment of inertia for any R—as illustrated in Fig. 15.4.
Superposition Principle
Still we are not satisfied with our characterization of the hammer, because it consists of two pieces: hammerhead and shaft. So far we have assumed that the mass of the shaft is negligible and that we therefore can neglects its moment of inertia. What if cannot neglect it—what to do then? We are saved by a principle called the superposition principle: For an object that consists of several parts, such as the hammerhead and the shaft of a hammer, we can find the moment of inertia around an axis by summing the moments of inertia for each part around the same axis:
15.3 Calculating the Moment of Inertia |
467 |
The moment of inertia of two systems A and B round the axis O is the sum of the moments of inertia for each part of the systems:
IO, A B = IO, A + IO,B . |
(15.19) |
(You can find a proof in Sect. A.4). We can therefore find the moment of inertia of a compound object by summing the moments of inertia for each of the object. Just be careful to ensure that you sum moments of inertia around the same axis.
This allows us to find the moment of inertia of the hammer illustrated in Fig. 15.6 as the sum of the moment of inertia of the hammerhead and the shaft:
IT O T ,O = Ih,O + Is,O , |
(15.20) |
where we have already found that the moment of inertia of the hammer is:
Ih,O = |
12 M h2 |
+ w2 + M R2 . |
(15.21) |
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The moment of inertia of the shaft around the point O can be found just as for the hammerhead. The moment of inertia around the center of mass for the shaft is found from Fig. 15.5:
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12 m L2 , |
(15.22) |
and we use the parallel-axis theorem to find its moment of inertia around point O, which is at a distance L/2 from the center of mass:
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12 m L2 + m |
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3 m L2 . |
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The total moment of inertia of the hammer around the point O is therefore:
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where R = L + h/2 for this configuration.