CIRCULAR MOTION Linear Motion d distance in meters

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CIRCULAR MOTION

CIRCULAR MOTION

Linear Motion d – distance (in meters) v – velocity (in meters/second) a –

Linear Motion d – distance (in meters) v – velocity (in meters/second) a – acceleration (in meters/second 2) Distance = 2 r

Linear/Tangential Velocity Objects moving in a circle still have a linear velocity = distance/time.

Linear/Tangential Velocity Objects moving in a circle still have a linear velocity = distance/time. This is often called tangential velocity, since the direction of the linear velocity is tangent to the circle. v

Angular Motion – angular displacement (in radians) – angular velocity (in radians/second) – angular

Angular Motion – angular displacement (in radians) – angular velocity (in radians/second) – angular acceleration (in radians/second 2) r – radius of circle (in meters)

Circular Motion Terms The point or line that is the center of the circle

Circular Motion Terms The point or line that is the center of the circle is the axis of rotation. If the axis of rotation is inside the object, the object is rotating (spinning). If the axis of rotation is outside the object, the object is revolving.

Angular Velocity Objects moving in a circle also have a rotational or angular velocity,

Angular Velocity Objects moving in a circle also have a rotational or angular velocity, which is the rate angular position changes. Rotational velocity is measured in degrees/second, rotations/minute (rpm), etc. Common symbol, w (Greek letter omega) D

Rotational & Linear Velocity If an object is rotating: All points on the object

Rotational & Linear Velocity If an object is rotating: All points on the object have the same rotational (angular) velocity. All points on the object do not have the same linear (tangential) velocity. Linear velocity of a point depends on: The rotational velocity of the point. More rotational velocity means more linear velocity. The distance from the point to the axis of rotation. More distance from the axis means more linear velocity In symbols: v=r v r

Linear to Angular d = r v. T = r a. T = r

Linear to Angular d = r v. T = r a. T = r r

Angular & Linear Velocity If an object is rotating: All points on the object

Angular & Linear Velocity If an object is rotating: All points on the object have the same Angular velocity. All points on the object do not have the same linear (tangential) velocity.

Angular & Linear Velocity Linear velocity of a point depends on: The Angular velocity

Angular & Linear Velocity Linear velocity of a point depends on: The Angular velocity of the point. More rotational velocity means more linear velocity. The distance from the point to the axis of rotation. More distance from the axis means more linear velocity.

Acceleration As an object moves around a circle, its direction of motion is constantly

Acceleration As an object moves around a circle, its direction of motion is constantly changing. Therefore its velocity is changing. Therefore an object moving in a circle is constantly accelerating.

Centripetal Acceleration The acceleration of an object moving in a circle points toward the

Centripetal Acceleration The acceleration of an object moving in a circle points toward the center of the circle. This is called a centripetal (center pointing) acceleration. ac

Centripetal Acceleration The centripetal acceleration depends on: The velocity of the object. The radius

Centripetal Acceleration The centripetal acceleration depends on: The velocity of the object. The radius of the circle.

Circular Motion #1 A spinning ride at a carnival has an angular acceleration of

Circular Motion #1 A spinning ride at a carnival has an angular acceleration of 0. 50 rad/s 2. How far from the center is a rider who has a tangential acceleration of 3. 3 m/s 2?

Circular Motion #2 What is the tire’s angular acceleration if the tangential acceleration at

Circular Motion #2 What is the tire’s angular acceleration if the tangential acceleration at a radius of 0. 15 m is 9. 4 x 10 -2 m/s 2?

Circular Motion #3 A test car moves at a constant speed of 10 m/s

Circular Motion #3 A test car moves at a constant speed of 10 m/s around a circular road of radius 50 m. Find the car’s A) centripetal acceleration and B) angular speed.

Circular Motion #4 A test car moves at a constant speed around a circular

Circular Motion #4 A test car moves at a constant speed around a circular track. If the car is 48. 2 m from the track’s center and has a centripetal acceleration of 8. 05 m/s 2, what is its tangential speed?

Circular Motion #5 A race car moves along a circular track at an angular

Circular Motion #5 A race car moves along a circular track at an angular speed of 0. 512 rad/s. If the car’s centripetal acceleration is 15. 4 m/s 2, what is the distance between the car and the center of the track?

Circular Motion #6 A piece of clay sits 0. 20 m from the center

Circular Motion #6 A piece of clay sits 0. 20 m from the center of a potter’s wheel. If the potter spins the wheel at an angular speed of 20. 5 rad/s, what is the magnitude of the centripetal acceleration of the piece of clay on the wheel?

Equations for Circular Motion

Equations for Circular Motion

Angular Acceleration – angular velocity (radians/second) – angular acceleration (radians/second 2) t – time

Angular Acceleration – angular velocity (radians/second) – angular acceleration (radians/second 2) t – time (seconds)

Circular Motion #7 A ventilator fan is turning at 600 rev/min when the power

Circular Motion #7 A ventilator fan is turning at 600 rev/min when the power is cut off, and it turns 1000 rev while coasting to a stop. Calculate the angular acceleration and the time required to stop.

Circular Motion #8 A bicycle wheel rotates with a constant angular acceleration of 3.

Circular Motion #8 A bicycle wheel rotates with a constant angular acceleration of 3. 5 rad/s 2. If the initial speed of the wheel is 2 rad/s at t = 0 s. a) Through what angle does the wheel rotate in 2 s? b) what is the angular speed at t = 2 s?

Circular Motion #9 A potter’s wheel moves from rest to an angular speed of

Circular Motion #9 A potter’s wheel moves from rest to an angular speed of 0. 20 rev/s in 30 s. Find the angular acceleration in rad/s 2.

Circular Motion #10 A dentist’s drill starts from rest. After 3. 20 seconds of

Circular Motion #10 A dentist’s drill starts from rest. After 3. 20 seconds of constant angular acceleration it turns at a rate of 2. 51 x 104 rev/min. a) find the drill’s angular acceleration. b) Determine the angle (radians) through which the drill rotates during this period.

Circular Motion #11 A floppy disk in a computer rotates from rest up to

Circular Motion #11 A floppy disk in a computer rotates from rest up to an angular speed of 31. 4 rad/s in a time of 0. 892 s. A) What is the angular acceleration of the disk, assuming angular acceleration is uniform? B) How many revolutions does the disk make while coming up to speed? C) Find v if r = 4. 45 cm D) Find at if r = 4. 45 cm.

Centripetal Force Newton’s Second Law says that if an object is accelerating, there must

Centripetal Force Newton’s Second Law says that if an object is accelerating, there must be a net force on it. For an object moving in a circle, this is called the centripetal force. The centripetal force points toward the center of the circle.

Centripetal Force In order to make an object revolve about an axis, the net

Centripetal Force In order to make an object revolve about an axis, the net force on the object must pull it toward the center of the circle. This force is called a centripetal (center Fc seeking) force.

Centripetal Force Centripetal force on an object depends on: The object’s mass - more

Centripetal Force Centripetal force on an object depends on: The object’s mass - more mass means more force. The object’s velocity - more speed means more force. And…

Centripetal Force The centripetal force on an object also depends on: The object’s distance

Centripetal Force The centripetal force on an object also depends on: The object’s distance from the axis (radius). If linear velocity is held constant, more distance requires less force. If rotational velocity is held constant, more distance requires more force.

Centripetal Force

Centripetal Force

TORQUE

TORQUE

Torque

Torque

Torque Is the measure of how effectively a force causes rotation.

Torque Is the measure of how effectively a force causes rotation.

Torques in equilibrium When the torques associated with two masses balance each other.

Torques in equilibrium When the torques associated with two masses balance each other.

Torques in equilibrium Two people with the same mass. Which picture shows torques in

Torques in equilibrium Two people with the same mass. Which picture shows torques in equilibrium? A B

Torques in equilibrium A – the distances are not the same in B so

Torques in equilibrium A – the distances are not the same in B so the torques will not balance. A B

PROBLEM 1 Alfred weighs 400 N. He sits on one end of a seesaw

PROBLEM 1 Alfred weighs 400 N. He sits on one end of a seesaw 1. 5 m from the fulcrum. Ann weighs 200 N. How far from the fulcrum must she sit to balance the seesaw? ?

PROBLEM 1 F 1 = 400 N r 1 = 1. 5 m F

PROBLEM 1 F 1 = 400 N r 1 = 1. 5 m F 2 = 200 N r 2 = ? 1 = 2 F 1 r 1 = F 2 r 2 400(1. 5) = 200(r 2) r 2 = 3 m 3 m 1. 5 m

GRAVITATIONAL MOTION

GRAVITATIONAL MOTION

Newton’s Law of Universal Gravitation states that every particle in the universe attracts every

Newton’s Law of Universal Gravitation states that every particle in the universe attracts every other particle with a force that is directly proportional to the product of their masses and inversely proportional to the square of the distance between them.

Newton’s Law of Universal Gravitation

Newton’s Law of Universal Gravitation

Universal Constants

Universal Constants

ACCELERATION DUE TO GRAVITY So. . . g = ? Now work it out.

ACCELERATION DUE TO GRAVITY So. . . g = ? Now work it out. Work that problem out. Get that problem right.

Universal Gravitation #1 The mass of planet Jupiter is 1. 9 x 1027 kg

Universal Gravitation #1 The mass of planet Jupiter is 1. 9 x 1027 kg and that of the sun is 1. 99 x 1030 kg. The mean distance of Jupiter from the sun is 7. 8 x 1011 m. Calculate the gravitational force which the sun exerts on Jupiter.

Where will the ball go?

Where will the ball go?

What will happen to the Moon?

What will happen to the Moon?