College Physics, 7th Edition

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Presentation transcript:

College Physics, 7th Edition Lecture Outline Chapter 7 College Physics, 7th Edition Wilson / Buffa / Lou © 2010 Pearson Education, Inc.

Chapter 7 Circular Motion and Gravitation © 2010 Pearson Education, Inc.

FLT Given a Circular motion of macroscopic objects, SWBAT to define, explain and calculate the centripetal acceleration, centripetal force and torque and Newton’s Force of Gravitation Fg using a= v2/r Fc = mac = mv2/r Ƭ = r Fsinθ Fg = Gm1m2 / R2 at certain condition such as : a. critical conditions b. equilibrium

Using mathematical representations of Newton’s Law of Gravitation and Kepler’s law , SWBAT  to describe the motion of a satellite and apply the concepts of angular momentum and torque.   Using mathematical or computational representations , SWBAT to predict the motion of orbiting objects in the solar system . Performance Expectations : I can use mathematical representations of Newton’s Law of Gravitation to describe and predict the gravitational forces between two objects . Learning Targets: I can calculate the gravitational interaction between observable masses using Newton’s Law of Gravitation

Units of Chapter 7 Angular Measure Angular Speed and Velocity Uniform Circular Motion and Centripetal Acceleration Angular Acceleration Newton’s Law of Gravitation Kepler’s Laws and Earth Satellites © 2010 Pearson Education, Inc.

7.1 Angular Measure The position of an object can be described using polar coordinates—r and θ—rather than x and y. The figure at left gives the conversion between the two descriptions. © 2010 Pearson Education, Inc.

Example : Given the cartesian/rectangular coordinates(5m, 10m) What are the polar coordinates? #4 p 253 College Physics Angles are expressed in degrees and radians .How do you convert degrees to radians and vice versa ? Ex. 60°=_____radians(rad) Π/2 = _____° #2 p 253 College Physics

7.1 Angular Measure r is a distance that extends from the origin. r is the same for any point on a given circle. (like the radius!) Θ is an angle, and it changes with time. Linear Displacement…how do we calculate? Angular Displacement is VERY similar

7.1 Angular Measure Δθ = θ - θi The unit for angular displacement is the degree. There are 360 degrees in one complete circle.

7.1 Angular Measure The arc length, s, is the distance that is traveled along the circular path. The θ is said to define the arc length. It is most convenient to measure the angle θ in radians.

Sample Problems CW/HW :p 253

7.1 Angular Measure Relationship between arc length, the radius, and the angle: For one full circle, with s = 2πr (this is the circumference of the circle) © 2010 Pearson Education, Inc.

7.1 Angular Measure A spectator standing at the center of a circular running track observes a runner start a practice race 256m due east of her own position. The runner runs on the track to the finish line, which is located due north of the observer’s position. What is the distance of the run?

7.1 Angular Measure A sailor sights a distance tanker ship and finds that it subtends an angle of 1.15 degrees. He knows from the shipping charts that the tanker is 150m in length. Approximately how far away is the tanker?

Sample Problems CW/HW :p 253 Example #10 Class work #11

Sample Problems CW/HW :p 253

Design an Experiment Circular Motion Purpose: a. To measure the frequency (f) of a vertical circular motion for two different lengths . b. To determine period (T) for two different lengths ,using T = 1/f c. To calculate the angular velocity(ω) for two different lengths, using ω= 2Πf d. To calculate the tangential velocity for two different lengths, (v) using v = rω e. To determine the centripetal acceleration (ac) ,for two different lengths using ac = v2 /r f. To determine the centripetal Force (Fc) using Fc= mv2 / r g. To calculate the tension of the string at the bottom and the top of the vertical circular motion .

7.2 Angular Speed and Velocity How do we calculate speed? What’s the difference between average speed and instantaneous speed?

7.2 Angular Speed and Velocity In analogy to the linear case, we define the average and instantaneous angular speed: Units?? Angular Velocity?? © 2010 Pearson Education, Inc.

7.2 Angular Speed and Velocity The direction of the angular velocity is along the axis of rotation, and is given by a right-hand rule. How does this work? Counterclockwise is positive © 2010 Pearson Education, Inc.

7.2 Angular Speed and Velocity A particle moving in a circle has an instantaneous velocity tangential to its circular path. What is a tangent? Tangential speed (the particle’s orbital speed)

7.2 Angular Speed and Velocity Relationship between tangential and angular speeds: This means that parts of a rotating object farther from the axis of rotation move faster. © 2010 Pearson Education, Inc.

CW/HW 26,27,28,29, 32 P 254 College Physics

7.2 Angular Speed and Velocity An amusement park merry go round at its constant operational speed makes one complete rotation in 45 seconds. Two children are on horses, one at 3.0 m from the center of the ride and the other farther out at 6.0 m from the center. What are the angular speeds of each? What are the tangential speeds of each?

7.2 Angular Speed and Velocity The period is the time it takes for one complete revolution (rotation) For example: The period of revolution of the Earth around the Sun is one year. Or the period of the Earth’s axial rotation is 24 hours. Units: seconds or sometimes seconds/cycle © 2010 Pearson Education, Inc.

7.2 Angular Speed and Velocity the frequency is the number of revolutions (rotations) per second. [Units: Hertz] The relation of the frequency to the angular speed:

7.2 Angular Speed and Velocity A CD rotates in a player at a constant speed of 200 rpm. What are the CD’s Frequency? Period?

Centripetal Acceleration and Centripetal Force P 226- X Centripetal Acceleration P 229- 230 Y Centripetal Force Write your information – 10 bullet information Share your information

7.3 Uniform Circular Motion and Centripetal Acceleration What is uniform motion? What is uniform circular motion?

7.3 Uniform Circular Motion and Centripetal Acceleration The acceleration in uniform circular motion is called centripetal acceleration. Centripetal means “center-seeking.” Centripetal acceleration is directed inward or “into” the circle. The tangential velocity is perpendicular to the centripetal acceleration.

7.3 Uniform Circular Motion and Centripetal Acceleration Instantaneous centripetal acceleration Can also be written as… © 2010 Pearson Education, Inc.

49, 50

7.3 Uniform Circular Motion and Centripetal Acceleration A laboratory centrifuge operates at a rotational speed of 12,000 rpm. What is the magnitude of the centripetal acceleration of a red blood cell at a radial distance of 8.00 cm from the centrifuge’s axis of rotation? How does this acceleration compare with g?

7.3 Uniform Circular Motion and Centripetal Acceleration The centripetal force (net inward force) is the mass multiplied by the centripetal acceleration. This force is the net force on the object. As the force is always perpendicular to the velocity, it does no work. © 2010 Pearson Education, Inc.

Design an Experiment Circular Motion Purpose a. To measure the frequency (f) of a vertical circular motion . b. To determine period (T) c. To calculate the angular velocity(ω) using ω= 2Πf d. To calculate the tangential velocity (v) using v = rω e. To determine the centripetal acceleration (ac) using ac = v2 /r f. To determine the centripetal Force (Fc) using Fc= mv2 / r g. To calculate the tension of the string at the bottom and the top of the vertical circular motion . h. To compare the tangential velocity v with 2 different radius r

Design an Experiment Circular Motion Purpose a. To measure the frequency (f) of a vertical circular motion . b. To determine period (T) c. To calculate the angular velocity(ω) using ω= 2Πf d. To calculate the tangential velocity (v) using v = rω e. To determine the centripetal acceleration (ac) using ac = v2 /r f. To determine the centripetal Force (Fc) using Fc= mv2 / r g. To compare the tangential velocity for 2 different lengths V vs r

7.3 Uniform Circular Motion and Centripetal Acceleration A ball is attached to a string is swung with uniform motion in a horizontal circle above a person’s head. If the string breaks, which of the trajectories shown on the following slide would the ball follow.

7.4 Angular Acceleration The average angular acceleration is the rate at which the angular speed changes: In analogy to constant linear acceleration: © 2010 Pearson Education, Inc.

7.4 Angular Acceleration If the angular speed is changing, the linear speed must be changing as well. The tangential acceleration is related to the angular acceleration: © 2010 Pearson Education, Inc.

7.4 Angular Acceleration © 2010 Pearson Education, Inc.

7.5 Newton’s Law of Gravitation Newton’s law of universal gravitation describes the force between any two point masses: G is called the universal gravitational constant: © 2010 Pearson Education, Inc.

CW : Universal Law of Gravitation # 80 p 257- College Physics #s 15-20 p 180-181– Conceptual Physics

7.5 Newton’s Law of Gravitation Gravity provides the centripetal force that keeps planets, moons, and satellites in their orbits. We can relate the universal gravitational force to the local acceleration of gravity: © 2010 Pearson Education, Inc.

7.5 Newton’s Law of Gravitation The gravitational potential energy is given by the general expression: © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites Kepler’s laws were the result of his many years of observations. They were later found to be consequences of Newton’s laws. Kepler’s first law: Planets move in elliptical orbits, with the Sun at one of the focal points. © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites Kepler’s second law: A line from the Sun to a planet sweeps out equal areas in equal lengths of time. © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites Kepler’s third law: The square of the orbital period of a planet is directly proportional to the cube of the average distance of the planet from the Sun; that is, . This can be derived from Newton’s law of gravitation, using a circular orbit. © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites If a projectile is given enough speed to just reach the top of the Earth’s gravitational well, its potential energy at the top will be zero. At the minimum, its kinetic energy will be zero there as well. © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites This minimum initial speed is called the escape speed. © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites Any satellite in orbit around the Earth has a speed given by © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites Astronauts in Earth orbit report the sensation of weightlessness. The gravitational force on them is not zero; what’s happening? © 2010 Pearson Education, Inc.

7.6 Kepler’s Laws and Earth Satellites What’s missing is not the weight, but the normal force. We call this apparent weightlessness. “Artificial” gravity could be produced in orbit by rotating the satellite; the centripetal force would mimic the effects of gravity. © 2010 Pearson Education, Inc.

Summary of Chapter 7 Angles may be measured in radians; the angle is the arc length divided by the radius. Angular kinematic equations for constant acceleration: © 2010 Pearson Education, Inc.

Summary of Chapter 7 Tangential speed is proportional to angular speed. Frequency is inversely proportional to period. Angular speed: Centripetal acceleration: © 2010 Pearson Education, Inc.

Summary of Chapter 7 Centripetal force: Angular acceleration is the rate at which the angular speed changes. It is related to the tangential acceleration. Newton’s law of gravitation: © 2010 Pearson Education, Inc.

Summary of Chapter 7 Gravitational potential energy: Kepler’s laws: Planetary orbits are ellipses with Sun at one focus Equal areas are swept out in equal times. The square of the period is proportional to the cube of the radius. © 2010 Pearson Education, Inc.

Summary of Chapter 7 Escape speed from Earth: Energy of a satellite orbiting Earth: © 2010 Pearson Education, Inc.