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Chapter 2 Motion 2-1. Speed 2-2. Vectors 2-3. Acceleration
2-4. Distance, Time, and Acceleration Free Fall System 2-6. Air Resistance 2-7. First Law of Motion 2-8. Mass 2-9. Second Law of Motion 2-10. Mass and Weight 2-11. Third Law of Motion 2-12. Circular Motion 2-13. Newton's Law of Gravity 2-14. Artificial Satellites
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2-1. Speed Definitions: v = d/t Speed General formula for speed:
The rate at which something moves a given distance. Faster speeds = greater distances General formula for speed: Speed = distance / time Abbreviations commonly used: d = distance t = time v = speed v = d/t
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2-1. Speed Velocity Distance Time
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2-1. Speed Average speed is the total distance traveled by an object divided by the time taken to travel that distance. Instantaneous speed is an object's speed at a given instant of time.
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2-2. Vectors Magnitude of a quantity tells how large the quantity is.
Scalar quantities have magnitude only. Vector quantities have both magnitude and direction.
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2-2. Vectors Velocity is a vector quantity that includes both speed and direction.
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2-3. Acceleration Acceleration of an object is the rate of change of its velocity and is a vector quantity. For straight-line motion, average acceleration is the rate of change of speed:
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2-3. Acceleration 3 Types of Acceleration Speeding Up Slowing Down
Turning
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2- 4. Distance, Time and Acceleration
(V1 + V2) Vavg = (20mph + 60mph) = 40mph d = vavg t d = ½at2 30mph 2hr = 60miles ½ 10m/s/s 52 = 125m
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2-5. Free Fall The acceleration of gravity (g) for objects in free fall at the earth's surface is 9.8 m/s2. Galileo found that all things fall at the same rate.
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2-5. Free Fall The rate of falling increases by 9.8 m/s every second.
Height = ½ gt2 For example: ½ (9.8 )12 = 4.9 m ½(9.8)22 = 19.6 m ½ (9.8)32 = 44.1 m ½ (9.8)42 = 78.4 m
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2-5. Free Fall A ball thrown horizontally will fall at the same rate as a ball dropped directly.
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2-5. Free Fall A ball thrown into the air will slow down, stop, and then begin to fall with the acceleration due to gravity. When it passes the thrower, it will be traveling at the same rate at which it was thrown.
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2-5. Free Fall An object thrown upward at an angle to the ground follows a curved path called a parabola.
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2-6. Air Resistance In air… In a vacuum
A stone falls faster than a feather Air resistance affects stone less In a vacuum A stone and a feather will fall at the same speed.
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2-6. Air Resistance Free Fall
A person in free fall reaches a terminal velocity of around 54 m/s With a parachute, terminal velocity is only 6.3 m/s Allows a safe landing
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2-6. Air Resistance Ideal angle for a projectile
In a vacuum, maximum distance is at an angle of 45o With air resistance (real world), angle is less Baseball will go furthest hit at an angle of around 40o
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2-7. First Law of Motion The first law of motion states: If no net force acts on it, an object at rest remains at rest and an object in motion remains in motion at a constant velocity.
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Foucault Pendulum Inertia keeps a pendulum swinging in the same direction regardless of the motion of the earth. This can be used to measure the motion of the earth. As the Foucault Pendulum swings it appears to be rotating, but it is the earth that is rotating under it. To the right is the Foucault Pendulum at the Pantheon in Paris, France.
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Other Web sites that illustrate the Foucault Pendulum.
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2-8. Mass Inertia is the apparent resistance an object offers to any change in its state of rest or motion.
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2-9. Second Law of Motion F = Ma
Newton's second law of motion states: The net force on an object equals the product of the mass and the acceleration of the object. The direction of the force is the same as that of the acceleration. F = Ma
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2-9. Second Law of Motion A force is any influence that can cause an object to be accelerated. The pound (lb) is the unit of force in the British system of measurement: 1 lb = 4.45 N (1 N = lb)
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2-10. Mass and Weight Weight
Definition: The force with which an object is attracted by the earth’s gravitational pull Example: A person weighing 160 lbs is being pulled towards the earth with a force of 160 lbs (712 N). Near the earth’s surface, weight and mass are essentially the same
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2-11. Third Law of Motion The third law of motion states: When one object exerts a force on a second object, the second object exerts an equal force in the opposite direction on the first object.
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2-11. Third Law of Motion Examples of the 3rd Law
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2-12. Circular Motion Centripetal force is the inward force exerted on an object to keep it moving in a curved path. Centrifugal force is the outward force exerted on the object that makes it want to fly off into space.
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2-12. Circular Motion
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833 N is needed to make this turn.
2-12. Circular Motion 833 N is needed to make this turn. If he goes too fast, which wheels are likely to come off the ground first?
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2-13. Newton's Law of Gravity
G = 6.67 x N•m/kg2
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2-13. Newton's Law of Gravity
How can we determine the mass of the earth using an apple? This illustrates the way scientists can use indirect methods to perform seemingly “impossible tasks”
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2-13. Newton's Law of Gravity
How can we determine the mass of the earth using an apple? This illustrates the way scientists can use indirect methods to perform seemingly “impossible tasks” = mg
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2-15. Artificial Satellites GPS-Global Positioning Satellite
The world's first artificial satellite was Sputnik I, launched in 1957 by the Soviet Union. GPS-Global Positioning Satellite
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2-15. Artificial Satellites
The escape speed is the speed required by an object to leave the gravitational influence of an astronomical body; for earth this speed is about 40,000 km/h.
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2-15. Artificial Satellites
The escape speed is the speed required by an object to leave the gravitational influence of an astronomical body; for earth this speed is about 40,000 km/h.
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Rotation & Revolution Axis
A straight line through which circular motion takes place All points on object orbit around the axis All rotation/revolution requires an axis
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Rotation & Revolution Rotation Revolution
Object rotating about an internal axis Ex. Daily motion of the Earth, spiral football Revolution Object rotating about an external axis Ex. Yearly motion of the earth
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How do we describe how fast something is rotating??
Speeds for objects in a straight line are called linear (or tangential) speeds, Linear speeds are a rate at which an object covers a certain distance (v =d/t) Ex. Unit – m/s , km/hr , mph
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Can’t express speeds of rotation with a linear speed,
b/c objects at different points on the rotating object have different linear speeds Rotational speed Expresses the rate at which an object rotates through a portion of a circle ( an angle) Ex. Unit RPM’s
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Below, a record spinning on a axis through its center (black dot)
Faster linear speed, Star or Smiley?? Smiley, travels a greater distance for each Full spin. Faster rotational speed, Star or smiley?? Both the same, b/c entire record is rotating at the same rate
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Are all people on Earth moving at the same speed??
Earth is rotating about an axis through its poles So that means we are all moving since we are all on the Earth.
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Are some of us moving with a greater LINEAR SPEED than others??
Yes, closer to the Equator, the faster you are moving…. Closer to poles, the slower you are moving Are some of us moving with a greater ROTATIONAL SPEED than others?? No, all people on earth have same rotational speed, because Earth is spinning at the same rate everywhere
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Centripetal Acceleration
Tangential speed (vt) depends on distance When tangential speed is constant, motion is described as uniform circular motion
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An object moving in a circle at a constant speed still has an acceleration due to its change in direction Velocity is a vector so acceleration can be produced by a change in magnitude and direction Centripetal Acceleration is acceleration caused by a change in direction, directed toward the center of a circular path ac = Vt2 / r
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Centripetal Acceleration
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Centripetal Force When driving in a circle, in what direction is a force acting on you? Pushing you outward from the circle, or inward? If you are swinging a yo-yo in a circle, and the string breaks…. What path does the yo – yo take?? Ans Inwards, toward the center of the circle Ans -- yo- yo goes in a path tangent to the circle ?
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Centripetal Force HOWEVER, People commonly think there is a force pushing you out from the circle Feels like you are being pushed outward Example ….. The Rotor- amusement park ride, a centrifuge, CD on your dashboard moving to the right when your turning left Why is this??
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The Rotor People Stand with backs against wall of a large cylinder, cylinder then starts spinning, and people are seemingly pushed against the wall, then floor drops, and people are stuck against the wall.
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So why is there no Force pushing you out from the circle??
A force does not cause this…… your INERTIA does!! Inertia makes you want to stay in a straight line, and by going in a circle, you are fighting your own inertia This is how Rotor works, and why CD on dashboard happens The only actual force acting on you is the Centripetal Force
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Centripetal Force Centripetal means “center- Seeking”
Force pushes you toward the center of the circle Is the force that keeps you moving in a circle, and keeps your inertia from taking you in a straight line Centripetal Force is affected by.. Mass (m), linear speed (vt), and radius (r)
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Centripetal Force Inertia wants to take objects in a tangent line, to the circular path Inertia is why you feel like your being pushed outward This outward pushing is sometimes called the Centrifugal Force but it is not actually a force, is only inertia Every object that moves in circular motion must experience a centripetal force from somewhere
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