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Transcript
Chapter Two and Chapter Three Objectives What is Motion? Measuring Motion Artstotle’s views Horizontal versus Vertical Motion Newton’s Laws of Motion Momentum Circular Motion Law of Gravition Motion and Measuring Motion Change in position Passage of time Measuring Motion Speed Distance/time Instantaneous versus Average Velocity Acceleration Change of velocity/ time Acceleration versus Deacceleration Motion Examples Speed: Example 2.1 Acceleration: Example 2.3 Aristotle’s Views Two spheres Sphere of perfection versus Sphere of change Natural versus Forced Motion Elements: earth, air, fire, and water Reqired force by people Could not explain interaction at a distance Horizontal versus Vertical Motion Horizontal Leaning Tower of Pisa Rolling Balls Inertia Vertical Free fall Galileo versus Aristotle Constant versus Accelerating objects Horizontal versus Vertical (cont.) Vertical (cont.) D=(1/2)at2 Confirmed with rolling ball A=g=9.8 m/s2 T=(2d/g) Compound Motion A combination of vertical and horizontal motion Newton’s Laws of Motion Edmund Halley Christmas Day, 1642 Trinity College, Cambridge Halley: Principia, planetary motion Well accepted Newton’s First Law of Motion “Every object retains it state of motion of its stat of uniform straight-line motion unless acted up by an unbalanced force” Inertia Mass Newton’s Second Law of Motion “The acceleration of an object is directly proportional to the net force acting on it and inversely proportional to the mass of the object” Weight is a force F = ma Newton’s Third Law of Motion “Whenever two objects interact, the force exerted on one object is equal in size and opposite in direction to the force exerted on the other object” Example: Standing on the Floor FAB = FBA Newton Examples Second Law: Example 3.1 Third Law: Example 3.5 Momentum “The total momentum of a group of interacting objects remains the same in the absence of external forces” P=mv Unusual P gives no clues Kg m/s has no other name Circular Motion Centripetal versus Centrifugal No true Centrifugal All circular motion inside ac=v2/r F=mv2/r Newton’s Laws of Gravitation “Every object in the universe is attractedto every other object with a force that is directly proportional to the product of their masses” F = GM1M2/R2 G = 6.67 X 10-11 Nm2/kg2 Force and Gravitation Examples Circular Motion: Example 3.7 Gaviation: Example 3.9, 3.10 Homework Chapter Two Questions for Thought 1, 6, 9 Parallel Exercise 3, 5 Chapter Three Questions for Thought 1, 4, 9 Parallel Exercise 4, 10
