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Shawn Zhong

钟万祥

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AP Physics C Mechanics

Home / AP / Notes / AP Physics C Mechanics / Page 6

7.5 - Angular Momentum

Dec 08, 2017
Shawn
AP Physics C Mechanics
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Linear Momentum • Momentum is a vector describing how difficult it is to stop a moving object • Total momentum is the sum of individual momenta • p ⃗=mv ⃗ • Units are kg·m/s or N·s Angular Momentum • Angular momentum (L ⃗) is a vector describing how difficult it is to stop a rotating object • Total angular momentum is the sum of individual angular momenta • A mass with velocity v ⃗ moving at some position r ⃗ about point Q has angular momentum L ⃗_Q • Units are kg·m2/s Calculating Angular Momentum • L ⃗_Q=r ⃗×p ⃗=r ⃗×mv ⃗=(r ⃗×v ⃗ )m Spin Angular Momentum • For an object rotating about its center of mass • L ⃗=Iω ⃗ • This is known as an object's spin angular momentum • Spin angular momentum is constant regardless of your reference point Example 1: Object in Circular Orbit • Find the angular momentum of a planet orbiting the sun. Assume a perfectly circular orbit Example 2: Angular Momentum of a Point Particle • Find the angular momentum for a 5-kg point particle located at (2,2) with a velocity of 2 m/s east • About point O at (0,0) • About point P at (2,0) • About point Q at (0,2) Angular Momentum and Net Torque Conservation of Angular Momentum • Spin angular momentum, the product of an object's moment of inertia and its angular velocity about the center of mass, is conserved in a closed system with no external net toques applied • L ⃗=Iω ⃗ Example 3: Ice Skater Problem • An ice skater spins with a specific angular velocity. She brings her arms and legs closer to her body, reducing her moment of inertia to half its original value. What happens to her angular velocity? What happens to her rotational kinetic energy? Example 4: Combining Spinning Discs • A disc with moment of inertia 1 km·m2 spins about an axle through its center of mass with angular velocity 10 rad/s. An identical disc which is not rotating is slide along the axle until it makes contact with the first disc. • If the two discs stick together, what is their combined angular velocity? Example 5: Catching While Rotating • Angelina spins on a rotating pedestal with an angular velocity of 8 radians per second. • Bob throws her an exercise ball, which increases her moment of inertia from 2 kg·m2 to 2.5 kg·m2 • What is Angelina's angular velocity after catching the exercise ball? (Neglect any external torque from the ball) 2005 Free Response Question 3 2014 Free Response Question 3

8.1 - Oscillations

Dec 08, 2017
Shawn
AP Physics C Mechanics
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Simple Harmonic Motion • Simple harmonic motion (SHM) is motion in which a restoring force is directly proportional to the displacement of an object • Nature's response to a perturbation or disturbance is often SHM Circular Motion vs. SHM Position, Velocity, Acceleration Frequency and Period • Frequency ○ Frequency is the number of revolutions or cycles which occur each second ○ Symbol is f ○ Units are 1/s, or Hertz (Hz) ○ f=(number of cycles)/second=(number of revolution)/second • Period ○ Period is the time it takes for one complete revolution, or cycle. ○ Symbol is T ○ Unites are seconds (s) ○ T = time for 1 cycle = time for 1 revolution • Relationship ○ f=1/T ○ T=1/f Angular Frequency • Angular frequency is the number of radians per second, and it corresponds to the angular velocity for an object traveling in uniform circular motion • Relationship ○ ω=2πf=2π/T ○ T=2πω=1/f ○ f=ω/2π=1/T Example 1: Oscillating System • An oscillating system is created by a releasing an object from a maximum displacement of 0.2 meters. The object makes 60 complete oscillations in one minute • Determine the object's angular frequency • What is the object's position at time t=10s? • At what time is the object at x=0.1m? Mass on a Spring Example 2: Analysis of Spring-Block System • A 5-kg block is attached to a 2000 N/m spring as shown and displaced a distance of 8 cm from its equilibrium position before being released. • Determine the period of oscillation, the frequency, and the angular frequency for the block General Form of SHM Graphing SHM Energy of SHM • When an object undergoes SHM, kinetic and potential energy both vary with time, although total energy (E=K+U) remains constant Horizontal Spring Oscillator Vertical Spring Oscillator Springs in Series Springs in Parallel The Pendulum • A mass m is attached to a light string that swings without friction about the vertical equilibrium position Energy and the Simple Pendulum Frequency and Period of a Pendulum Period of a Physical Pendulum Example 3: Deriving Period of a Simple Pendulum Example 4: Deriving Period of a Physical Pendulum Example 5: Summary of Spring-Block System Example 6: Harmonic Oscillator Analysis • A 2-kg block is attacked to a spring. A force of 20 N stretches the spring to a displacement of 0.5 meter • The spring constant • The total energy • The speed at the equilibrium position • The speed at x=0.30 meters • The speed at x=-0.4 meters • The acceleration at the equilibrium position • The magnitude of the acceleration at x=0.5 meters. • The net force at equilibrium position • The net force at x=0.25 meter • Where does kinetic energy = potential energy Example 7: Vertical Spring Block Oscillator • A 2-kg block attached to an un-stretched spring of spring constant k=200 N/m as shown in the diagram below is released from rest. Determine the period of the block's oscillation and the maximum displacement of the block from its equilibrium while undergoing simple harmonic motion. 2009 Free Response Question 2 2010 Free Response Question 3

9.1 - Gravity & Orbits

Dec 08, 2017
Shawn
AP Physics C Mechanics
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Newton's Law of Universal Gravitation Gravitational Field Strength Gravitational Field of a Hollow Shell • Inside a hollow sphere, the gravitational field is 0. Outside a hollow sphere, you can treat the sphere as if it's entire mass was concentrated at the center, and then calculate the gravitational field Gravitational Field Inside a Solid Shell • Outside a solid sphere, treat the sphere as if all the mass is at the center of the sphere. Inside the sphere, treat the sphere as if the mass inside the radius is all at the center. Only the mass inside the

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