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Motion Under Gravity: Galileo's Experiment and Projectile Motion

Learn about Galileo's experiment on motion under gravity and explore the concept of projectile motion. Understand the independence of horizontal and vertical motions and how gravity affects objects in free fall. Discover the key points of projectile motion and its applications.

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Motion Under Gravity: Galileo's Experiment and Projectile Motion

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  1. Physics 106 Lesson #3Motion Under the Influence of Gravity: Galileo’s Experiment and Projectile Motion Dr. Andrew Tomasch 2405 Randall Lab atomasch@umich.edu

  2. Extended objects which do not change shape are called rigid bodies For a rigid body to be in equilibrium: For a rigid body to remain stationary in one place, the net force acting on it must be zero For a rigid body to remain stationary and not rotate the net torque about any axis through the body must be zero The net force/torque is the vector sum of all forces/torques acting on the body (analyze with Free Body Diagram) Last time: Equilibrium for Rigid Bodies

  3. Whenever physicists want the express how a quantity changes, they use a capital Greek Delta (Δ): Using the Delta we can define displacement, velocity and acceleration in a compact shorthand Some Shorthand: The Capital Delta

  4. Describing Motion:Four Basic Quantities

  5. Free Fall • What is “free fall”? • refers to objects that are dropped (or thrown) vertically • The earth’s gravity produces a nearlyconstantaccelerationof g = 9.8 m/s2downward • An object dropped from rest reaches a velocity of 9.8 m/s (~24 mph) after one second • In vacuum all objects accelerate • An object rolling down an incline is still in “free fall” under the influence of gravity!

  6. Demonstration:The Feather and the Farthing All objects near the earth are attracted with the same accelerationg = 9.8 m/s2 toward the Earth’s center (“downward”). In a vacuum all objects will fall with the same acceleration when released from rest, independent of their masses or sizes. Objects fall with different accelerations inaironly because of the drag force (“air resistance”) produced by the air on the falling object The feather and the farthing will fall togetherin a vacuum. Galileo

  7. Projectile Motion Galileo • Galileo: the vertical and horizontal motions of a projectile are independent • The horizontal motion is motion with constant velocity • The vertical motion is motion with constant acceleration( gthe acceleration of gravity) • The horizontal motion and the vertical motion do not affect each other

  8. Horizontal Motion (Constant Velocity) Vertical Motion (Constant Acceleration) The acceleration is g= 9.8 m/s2 everywhere along the trajectory, irrespective of position or velocity Projectiles: Two Motions Superposed g q Caution Quiz Ahead

  9. Concept Test #1 Caution Quiz Ahead A ball is thrown downward (not dropped) from the top of a tower. After being released, its downward acceleration will be: • Greater thang • Smaller than g • Exactlyg The acceleration of gravity always points downward with g = 9.8 m/s2 near the surface of the Earth. Once the ball is released it is in free fall with g = 9.8 m/s2 downward.

  10. Concept Test #2 In a baseball game, a batter hits a pitched ball that goes straight up in the air above home plate. At the top of its motion, the ball is momentarily motionless. At this point • the acceleration is zero because the ball is motionless at that instant. • the acceleration is zero because the motion is changing from slowing down to speeding up. • the acceleration is zero because at that instant the force from the impact with the bat is balanced by the pull of the earth. • the acceleration is 9.8 m/s2downward.

  11. The vertical and horizontal motions are independent and do not affect each other The time-of-flighttof depends only on the maximum heightH and increases with H The range R is the product of tofand the horizontal component of velocity at launch The longest rage for a given launch speed occurs at a launch angle of 45 degrees Projectiles: Key Points g q

  12. Concept Test #3 A battle ship simultaneously fires two shells at enemy ships. If the shells follow the parabolic trajectories shown, which ship gets hit first? • Ship A. • Ship B. • They will both be hit at the same time. • Need more information.

  13. Demonstration: The Slug Gun A slug gun is a device which fires a billiard ball exactly horizontally while dropping another vertically. Which ball will hit the ground first? The horizontal velocity does not affect how an object falls vertically. Therefore, both balls hit the ground at the same time.

  14. y h x Shooting the Falling Bear Trajectory of dart without gravity Nice try bear! Trajectory of dart with gravity θ Both the bear and the dart are in “free fall” under the influence of gravity. The dart hits the bear!

  15. Galileo’s Last Word: A Puzzle All objects near the earth are attracted with the same accelerationg = 9.8 m/s2 toward the Earth’s center (“downward”) irrespective of their masses Forces cause motion More massive objects have a larger downward force acting on them due to gravity How can these facts be consistent? Enter Sir Isaac Newton!

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