Lecture Outline:
1. MEASUREMENTS
1.1.
Measuring Things
1.2. The
International Systems of Units
1.3. Changing
Unit
1.4. Length
1.5. Time
1.6. Mass
2. MOTION ALONG A STRAIGHT LINE
2.1. Motion
2.2. Position
and Displacement
2.3. Average
Velocity and Average Speed
2.4.
Instantaneous Velocity and Speed
2.5.
Acceleration
2.6. Constant
Acceleration: A Special Case
2.7. Another
Look at Constant Acceleration
2.8. Free-Fall
Acceleration
2.9. The
Particles of Physics
3. VECTORS
3.1. Vectors
and Scalars
3.2. Adding
Vectors: Graphical Method
3.3. Vectors
and their Components
3.4. Unit
Vectors
3.5. Adding
Vectors and Components
3.6. Vectors
and the Laws of Physics
3.7.
Multiplying Vectors
4. MOTION IN TWO AND THREE
DIMENSIONS
4.1. Moving
Two or Three Dimensions
4.2. Position
and Displacement
4.3. Velocity
and Average Velocity
4.4.
Acceleration and Average Acceleration
4.5.
Projectile Motion
4.6.
Projectile Motion Analyzed
4.7. Uniformly
Circular Motion
4.8. Relative
Motion in One Dimension
4.9. Relative
Motion in Two Dimension
4.10.
Relative Motion at High Speeds
5. FORCE AND MOTION - I
5.1. What
Causes an Acceleration?
5.2. Newton’s
First Law
5.3. Force
5.4. Mass
5.5. Newton’s
Second Law
5.6. Some
Particular Forces
5.7. Newton’s
Third Law
5.8. Applying
Newton’s Laws
6. FORCE AND MOTION
- II
6.1. Friction
6.2.
Properties of Friction
6.3. The Drag
Force and Terminal Speed
6.4. Uniform
Circular Motion
6.5. The
Forces of Nature
7. KINETIC ENERGY AND WORK
7.1. Kinetic
Energy
7.2. Work
7.3. Work and
Kinetic Energy
7.4. Work Done
by Weight
7.5. Work Done
by a Variable Force
7.6. Work Done
by a Spring Force
7.7. Power
7.8. Kinetic
Energy at High Speed
7.9. Reference
Frames
8. POTENTIAL ENERGY AND
CONSERVATION OF ENERGY
8.1. Potential
Energy
8.2. Path
Independence of Conservative Forces
8.3.
Determining Potential Energy Values
8.4.
Conservation of Mechanical Energy
8.5. Reading a
Potential Energy Curve
8.6. Work Done
by Nonconservative Forces
8.7.
Conservation of Energy
8.8. Mass and
Energy
8.9. Quantized
Energy
9. SYSTEMS OF PARTICLES
9.1. A Special
Point
9.2. The
Center of Mass
9.3. Newton’s
Second Law for a Systems of Particles
9.4. Linear
Momentum
9.5. The
Linear Momentum of a System of Particles
9.6.
Conservation of Linear Momentum
9.7. Systems
with Varying Mass: A Rocket
9.8. External
Forces And Internal Energy Changes
10. COLLISIONS
10.1. What is
a Collision?
10.2. Impulse
and Linear Momentum
10.3. Elastic
Collisions in One Dimension
10.4.
Inelastic Collisions in One Dimension
10.5.
Collisions in Two Dimensions
10.6.
Reactions and Decay Processes
11. ROTATION
11.1.
Translation and Rotation
11.2. The
Rotational Variables
11.3. Are
Angular Quantities Vectors?
11.4.
Rotation With Constant Angular Acceleration
11.5.
Relating The Linear and Angular Variables
11.6. Kinetic
Energy of Rotation
11.7.
Calculating the Rotational Inertia
11.8. Torque
11.9.
Newton’s Second Law for Rotation
11.10. Work and
Rotational Kinetic Energy
12. ROLLING, TORQUE AND ANGULAR
MOMENTUM
12.1. Rolling
12.2. The Yo-Yo
12.3. Torque Revisited
12.4. Angular Momentum
12.5. Newton’s Second Law For
Rotation in Angular Form
12.6. The Angular Momentum of a
System of Particles
12.7. The Angular Momentum of a
Rigid Body Rotating About a Fixed Axis
12.8. Conservation of Angular
Momentum
12.9. Quantized Angular
Momentum
16. OSCILLATIONS
16.1.
Oscillations
16.2. Simple
Harmonic Motion
16.3. The
Force Law for Simple Harmonic Motion
16.4. Energy
in Simple Harmonic Motion
16.5. An
Angular Simple Harmonic Oscillator
16.6.
Pendulums
16.7. Simple
Harmonic Motion and Uniform Circular Motion
16.8. Damped
Simple Harmonic Motion
16.9. Forced
Oscillations and Resonance