# Chapter 8 Motion and Forces. Reference Frame Clues are often given by looking at other objects in your surroundings Clues are often given by looking at.

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Chapter 8 Motion and Forces Slide 2 Reference Frame Clues are often given by looking at other objects in your surroundings Clues are often given by looking at other objects in your surroundings Normally you think of walls or signs as not moving, or as being stationary objects Normally you think of walls or signs as not moving, or as being stationary objects When you do this you use the walls or signs as a frame or reference When you do this you use the walls or signs as a frame or reference Slide 3 Object that you assume is fixed in place Object that you assume is fixed in place Reference frames also move relative to each other which may cause confusion Reference frames also move relative to each other which may cause confusion The perception of motion depends on the observers frame of reference The perception of motion depends on the observers frame of reference Reference Frame Slide 4 Describe the motion observed by one of the boys in the drawing, how does the motion appear to be different to the other boy? Describe the motion observed by one of the boys in the drawing, how does the motion appear to be different to the other boy? Slide 5 Imagine you are the girl observing the bus, describe the motion of each object that you can see Imagine you are the girl observing the bus, describe the motion of each object that you can see Slide 6 Frame of Reference How would the earths movement appear to astronauts? How would the earths movement appear to astronauts? What are up and down directions to the astronauts? Why? What are up and down directions to the astronauts? Why? What do you use as your frame of reference most of the time? What do you use as your frame of reference most of the time? Slide 7 Measuring Motion How do you describe motion taking place? How do you describe motion taking place? To describe motion you discuss speed To describe motion you discuss speed Speed is the distance an object travels per unit of time Speed is the distance an object travels per unit of time To calculate its speed you divide the distance it travels by the time it travels To calculate its speed you divide the distance it travels by the time it travels Slide 8 Measuring Motion Speed is sometimes expressed in kilometers per hour Speed is sometimes expressed in kilometers per hour Or meter per second Or meter per second An objects speed doesnt indicate all there is to know about its motion An objects speed doesnt indicate all there is to know about its motion An objects speed together with its direction of motion is called velocity An objects speed together with its direction of motion is called velocity Slide 9 Measuring Motion People often use the word speed when they mean velocity People often use the word speed when they mean velocity Since a moving object always travels in some direction, velocity is a more precise term for describing motion Since a moving object always travels in some direction, velocity is a more precise term for describing motion Meteorologists use wind velocity measurements to help predict weather Meteorologists use wind velocity measurements to help predict weather Slide 10 Constant speed A moving object that doesnt change its speed travels at constant speed A moving object that doesnt change its speed travels at constant speed Constant speed means equal distances are covered in an equal amount of time Constant speed means equal distances are covered in an equal amount of time Suppose you and a friend want to run around a track at constant speed for half an hour Suppose you and a friend want to run around a track at constant speed for half an hour Slide 11 Constant speed How can you check to see if your speed is constant? How can you check to see if your speed is constant? Your measurement can be even more accurate if you measure how long it takes to travel very short distances of equal length Your measurement can be even more accurate if you measure how long it takes to travel very short distances of equal length If all the times are the same they must be constant. If all the times are the same they must be constant. Slide 12 How does this graph display speed? How does this graph display speed? Slide 13 Why are these graphs different? Why are these graphs different? How was the motion different? How was the motion different? Slide 14 Average Speed Average speed is equal to the total distance of the course divided by the runners total timer. Average speed is equal to the total distance of the course divided by the runners total timer. Slide 15 Calculating Speed Speed = Distance Time Speed = Distance Time If a runner travels 100 m in 10 seconds what was his average speed? If a runner travels 100 m in 10 seconds what was his average speed? Probably not constant Probably not constant Can solve for the other pieces too Can solve for the other pieces too Distance = speed x time Distance = speed x time Time = Distance Speed Time = Distance Speed Slide 16 D ST Cover the one youre looking for Slide 17 Practice A car race is 500 km long. It takes the winner 2.5 hours to complete it. How was he going? A car race is 500 km long. It takes the winner 2.5 hours to complete it. How was he going? It is 320 km to Las Vegas. If you average 80 km/hr, how long will it take you to get there? It is 320 km to Las Vegas. If you average 80 km/hr, how long will it take you to get there? You are going on a trip. You average 80 km/hr for 6 hours. How far did you go? You are going on a trip. You average 80 km/hr for 6 hours. How far did you go? Slide 18 Velocity Is both speed and direction. Is both speed and direction. 40 km/hr = speed 40 km/hr = speed 40 km/hr west = velocity 40 km/hr west = velocity Can change velocity two ways Can change velocity two ways Change speed Change speed Or change directions Or change directions Slide 19 Momentum A truck is harder to stop than a car A truck is harder to stop than a car Mass affects motion Mass affects motion Momentum = mass x velocity Momentum = mass x velocity Symbol is p Symbol is p p = mv p = mv Units kgm/s Units kgm/s Has direction just like velocity Has direction just like velocity Slide 20 Calculating Momentum A 75 kg man is traveling 10 km/hr west. What is his momentum? A 75 kg man is traveling 10 km/hr west. What is his momentum? A 0.25 kg ball is moving at 160 km/hr toward home plate. What is its momentum? A 0.25 kg ball is moving at 160 km/hr toward home plate. What is its momentum? Slide 21 Law of Conservation of Momentum The total amount of momentum in a system is conserved. The total amount of momentum in a system is conserved. Add up all the momentum Add up all the momentum Take into account the direction. Take into account the direction. Used to predict motion of cars after a collision Used to predict motion of cars after a collision Slide 22 Change in Velocity Each time you take a step you are changing the velocity of your body. Each time you take a step you are changing the velocity of your body. You are probably most familiar with the velocity changes of a moving bus or car. You are probably most familiar with the velocity changes of a moving bus or car. The rate at which velocity changes occur is called acceleration. The rate at which velocity changes occur is called acceleration. Slide 23 Acceleration= final velocity- starting velocity Acceleration= final velocity- starting velocity time time Change in velocity = final starting velocity velocity Change in velocity = final starting velocity velocity Acceleration= change in velocity Acceleration= change in velocity time time Slide 24 Positive acceleration Negative acceleration Slide 25 Acceleration Any change in velocity is acceleration, even if the speed of the object remains the same. Any change in velocity is acceleration, even if the speed of the object remains the same. When ever an object changes how it moves, the velocity changes. When ever an object changes how it moves, the velocity changes. A change in direction is a change in velocity, and acceleration. A change in direction is a change in velocity, and acceleration. Slide 26 Motion in a circle An object moving in a circle or a curve is constantly changing direction. An object moving in a circle or a curve is constantly changing direction. Centripetal = acceleration towards the center of the circle. Centripetal = acceleration towards the center of the circle. Slide 27 Force A push or a pull A push or a pull Can cause a change in motion Can cause a change in motion Can cause a change in velocity Can cause a change in velocity Can cause acceleration Can cause acceleration There can be no acceleration without a force There can be no acceleration without a force Slide 28 Net Force Usually many forces are acting at the same time Usually many forces are acting at the same time Have to add up these forces to see whether they add up or cancel out. Have to add up these forces to see whether they add up or cancel out. Balanced Forces cancel out and give a net force of zero Balanced Forces cancel out and give a net force of zero Balanced forces can not cause a change in motion Balanced forces can not cause a change in motion Like a tug of war Like a tug of war Slide 29 Balanced Forces Slide 30 Unbalanced Forces The forces dont cancel out The forces dont cancel out Cause a change in motion Cause a change in motion Act as one force Act as one force Slide 31 Friction A force between two objects that opposes motion A force between two objects that opposes motion A ball will not roll forever A ball will not roll forever It will slow down because it rubs against the ground It will slow down because it rubs against the ground The friction causes a negative acceleration The friction causes a negative acceleration To keep a car moving at a constant speed, you need to keep applying a force To keep a car moving at a constant speed, you need to keep applying a force Slide 32 Friction Friction can keep an object from moving Friction can keep an object from moving Rougher surfaces have greater friction Rougher surfaces have greater friction Smoother surfaces have less friction Smoother surfaces have less friction Larger surface area has more friction Larger surface area has more friction Greater weight has more friction Greater weight has more friction Sliding friction is greater than rolling friction. Sliding friction is greater than rolling friction. Slide 33 Friction Friction affects every object on the earth. Friction affects every object on the earth. Why we use oil and bearings Why we use oil and bearings Without friction you wouldnt be able to walk without slipping and falling down. Without friction you wouldnt be able to walk without slipping and falling down. Slide 34 Air Resistance The force of the air against a moving object The force of the air against a moving object Increases as the velocity of the motion increases Increases as the velocity of the motion increases The size and shape of the object also effect the air resistance The size and shape of the object also effect the air resistance Larger surface area more resistance Larger surface area more resistance Car designers try to minimize it Car designers try to minimize it Overcoming air resistance uses more fuel Overcoming air resistance uses more fuel Slide 35 Gravity A force of attraction between objects A force of attraction between objects Can act at a distance, they dont have to touch Can act at a distance, they dont have to touch The strength of the force depends on the mass of the objects and the distance The strength of the force depends on the mass of the objects and the distance You multiply the masses together You multiply the masses together Gravity is a weak force Gravity is a weak force The masses need to be large to be noticed The masses need to be large to be noticed Slide 36 Gravity Like the size of planet Like the size of planet And divide by the distance squared And divide by the distance squared Twice as far is one quarter as strong Twice as far is one quarter as strong Three times is one ninth as strong Three times is one ninth as strong Slide 37 Newtons Laws of Motion An object at rest stays at rest until an outside force causes it to move. An object at rest stays at rest until an outside force causes it to move. An object in motion continues to move in the same direction at the same speed until a force stops it or changes its direction. An object in motion continues to move in the same direction at the same speed until a force stops it or changes its direction. So, an object at rest will stay at rest, and an object in motion will remain in motion unless acted by an outside force. So, an object at rest will stay at rest, and an object in motion will remain in motion unless acted by an outside force. Newtons First Law of Motion Newtons First Law of Motion Slide 38 Inertia An object at rest stays at rest until an outside force causes it to move. An object at rest stays at rest until an outside force causes it to move. An object in motion continues to move in the same direction until a force stops it or changes its direction. An object in motion continues to move in the same direction until a force stops it or changes its direction. So, an object at rest will stay at rest, and an object in motion will remain in motion unless acted by an outside force. So, an object at rest will stay at rest, and an object in motion will remain in motion unless acted by an outside force. Slide 39 Inertia Inertia: the tendency of an object to remain at rest or in motion until acted upon by an external force. Inertia: the tendency of an object to remain at rest or in motion until acted upon by an external force. Friction is an outside force that resists motion when two surfaces come in contact. Friction is an outside force that resists motion when two surfaces come in contact. The surfaces can be between two objects or between an object and air or water. The surfaces can be between two objects or between an object and air or water. Slide 40 Second Law of Motion Acceleration depends on the mass of the object and the unbalanced force applied Acceleration depends on the mass of the object and the unbalanced force applied F = m x a F = m x a more mass, harder to accelerate more mass, harder to accelerate more force, faster acceleration more force, faster acceleration Newton is the unit of force Newton is the unit of force equal the force needed to change the velocity of a 1 kg mass by 1 m/s 2 equal the force needed to change the velocity of a 1 kg mass by 1 m/s 2 Slide 41 Free fall When the force of gravity is the only force acting on an object When the force of gravity is the only force acting on an object If there was no air, all objects would fall at the same speed If there was no air, all objects would fall at the same speed The acceleration caused by gravity is 9.8 m/s 2 The acceleration caused by gravity is 9.8 m/s 2 Called g Called g Is the same for all objects Is the same for all objects Slide 42 Weight The force of gravity on an object. The force of gravity on an object. F = m x a F = m x a W = m x g W = m x g Larger mass, larger weight Larger mass, larger weight Astronauts in orbit in the shuttle are falling with the same acceleration as the shuttle Astronauts in orbit in the shuttle are falling with the same acceleration as the shuttle There is apparent weightlessness There is apparent weightlessness Different planets different values of g, so you would weigh different amounts Different planets different values of g, so you would weigh different amounts Slide 43 How Things Fall Slide 44 Galileo 1600s 1600s Studied how things fell Studied how things fell Didnt have a good clock Didnt have a good clock Rolled balls down an inclined plane Rolled balls down an inclined plane Found that the speed increased as it rolled down the ramp Found that the speed increased as it rolled down the ramp Slide 45 Galileo t = 0 t = 1 second t = 2 seconds t = 3 seconds Slide 46 Galileo u Same things happen when things fall u Didnt drop things from Tower of Pisa Slide 47 Falling Things accelerate Things accelerate acceleration needs a force acceleration needs a force caused by gravity caused by gravity Doesnt depend on mass Doesnt depend on mass 9.8 m/s 2 9.8 m/s 2 After 1 second falling at 9.8 m/s After 1 second falling at 9.8 m/s After 2 seconds 19.6 m/s After 2 seconds 19.6 m/s 3 seconds 29.4 m/s 3 seconds 29.4 m/s Slide 48 Falling Air resistance will increase as it falls faster Air resistance will increase as it falls faster An upward force on the object An upward force on the object Eventually gravity will balance with air resistance Eventually gravity will balance with air resistance Reaches terminal velocity - highest speed reached by a falling object. Reaches terminal velocity - highest speed reached by a falling object. Slide 49 Terminal velocity Force of gravity is constant Force of gravity is constant u air resistance increases as you speed up u until the force is equal u Equal forces, no acceleration u constant velocity terminal velocity Slide 50 Motion in Two Directions Things can move sideways and vertically at the same time Things can move sideways and vertically at the same time If no force other than gravity acts, If no force other than gravity acts, the sideways velocity will remain the same the sideways velocity will remain the same The vertical velocity will change The vertical velocity will change Gives a curved path Gives a curved path Parabola Parabola Slide 51 Motion in two directions Slide 52 Slide 53 Third Law of Motion For every force, there is an equal and opposite force For every force, there is an equal and opposite force For every action there is an equal and opposite reaction. For every action there is an equal and opposite reaction. Rockets Rockets gases get pushed out gases get pushed out Rocket moves forward Rocket moves forward Skating Skating Slide 54 http://www.cath- mem.org/physics/contents.htm http://www.cath- mem.org/physics/contents.htm http://www.cath- mem.org/physics/contents.htm http://www.cath- mem.org/physics/contents.htm http://www.physicsclassroom.com/mme dia/index.html http://www.physicsclassroom.com/mme dia/index.html http://www.physicsclassroom.com/mme dia/index.html http://www.physicsclassroom.com/mme dia/index.html http://webphysics.ph.msstate.edu/jc/lib rary/8-2a/pendel5.htm http://webphysics.ph.msstate.edu/jc/lib rary/8-2a/pendel5.htm http://webphysics.ph.msstate.edu/jc/lib rary/8-2a/pendel5.htm http://webphysics.ph.msstate.edu/jc/lib rary/8-2a/pendel5.htm http://jersey.uoregon.edu/vlab/Cannon/ http://jersey.uoregon.edu/vlab/Cannon/ http://jersey.uoregon.edu/vlab/Cannon/ http://www.phy.ntnu.edu.tw/java/proje ctileOrbit/projectileOrbit.html http://www.phy.ntnu.edu.tw/java/proje ctileOrbit/projectileOrbit.html Slide 55