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Mr. Klapholz Shaker Heights High School. Mechanics (2). This is the classic physics topic. Here is where physics began, and where physics has most influenced other sciences (especially economics).
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Mr. Klapholz Shaker Heights High School Mechanics (2) This is the classic physics topic. Here is where physics began, and where physics has most influenced other sciences (especially economics). Mechanics is a huge subject, that we divide into “kinematics” (description of motion) and “dynamics” (causes of motion).
A special challenge • Nowhere else in the IB physics curriculum is so much material covered in so little time. • Clearly IB does not ask us to learn it thoroughly, and this can be hard on students and awkward for teachers. • The challenge for us is to learn it well enough, but not to dwell on it too long.
A mistake by Tsokos • After looking at other IB texts, it seems clear that our author has messed up with ‘displacement’. • What follows is what the majority of IB texts use. • Even so, different cultures use the words in slightly different ways, so we’ll need to be on our toes in the IB world.
IB vs. USA • They say “Gradient of a line”, we say: • “Slope of a line” • They call it a “lift”, we call it an: • Elevator. • They say “Lorry”, we say: • “Truck” • They say “Trolly”, we say: • “Cart” • They say “Torch”, we say • “Flashlight” • I say: “GOOD LUCK!”
Position (x) • We use “x” to say __________ on the number line an object is located. • “Position” is a lot like the __________ of a point.
Position (x) • We use “x” to say where on the number line an object is located. • “Position” is a lot like the __________ of a point.
Position (x) • We use “x” to say where on the number line an object is located. • “Position” is a lot like the address of a point.
Distance (d or s) • “Distance” describes how far apart two points are. • Simply: it is how much string it would take to connect two points. • Distance is never negative. • Distance is a scalar.
Displacement (s) 1 of 3 • “Displacement” is like distance, but it is a __________ . Displacement has _________ . • Positive and negative depend on how we set up our x-y axes. • The magnitude (the size, the amount) of displacement, is __________ .
Displacement (s) 1 of 3 • “Displacement” is like distance, but it is a vector. Displacement has __________ . • Positive and negative depend on how we set up our x-y axes. • The magnitude (the size, the amount) of displacement, is __________ .
Displacement (s) 1 of 3 • “Displacement” is like distance, but it is a vector. Displacement has direction. • Positive and negative depend on how we set up our x-y axes. • The magnitude (the size, the amount) of displacement, is __________ .
Displacement (s) 1 of 3 • “Displacement” is like distance, but it is a vector. Displacement has direction. • Positive and negative depend on how we set up our x-y axes. • The magnitude (the size, the amount) of displacement, is distance.
Displacement (s) 2 of 3 • If you travel 100 m East, that could be a positive displacement. Then, if you traveled 100 m West, that would be a negative displacement. • Displacement is the change in __________ . • s = x2 – x1 • s = xf – xi • s = Dx {memorize this}
Displacement (s) 2 of 3 • If you travel 100 m East, that could be a positive displacement. Then, if you traveled 100 m West, that would be a negative displacement. • Displacement is the change in position. • s = x2 – x1 • s = xf – xi • s = Dx {memorize this}
Displacement (s) 3 of 3 • Draw a number line so that it is like a football field: 10 yards, 20, 30 , 40, 50. • An object starts at the 40 yard line. • The object then moves to the 30. • What is the displacement of the object? s = Dx = x2 – x1 s = 30 yd – 40 yd s = -10 yards
Speed (v) • You are traveling on the highway. What are the units for your speed? • What is the equation for speed? • Speed = __________ • If you travel 110 miles in 2 hours then your speed is?
Speed (v) • You are traveling on the highway. What are the units for your speed? • What is the equation for speed? • Speed = Distance ÷ Time • If you travel 110 miles in 2 hours then your speed is?
Velocity (v) • Velocity is like speed, but it is a vector. Velocity has __________ . • Guess the equation for velocity: • Velocity = • v = • The magnitude (the size, the amount) of velocity, is __________ .
Velocity (v) • Velocity is like speed, but it is a vector. Velocity has direction. • Guess the equation for velocity: • Velocity = • v = • The magnitude (the size, the amount) of velocity, is __________ .
Velocity (v) • Velocity is like speed, but it is a vector. Velocity has direction. • Guess the equation for velocity: • Velocity = displacement / time • v = • The magnitude (the size, the amount) of velocity, is __________ .
Velocity (v) • Velocity is like speed, but it is a vector. Velocity has direction. • Guess the equation for velocity: • Velocity = displacement / time • v = s ÷ t • The magnitude (the size, the amount) of velocity, is __________ .
Velocity (v) • Velocity is like speed, but it is a vector. Velocity has direction. • Guess the equation for velocity: • Velocity = displacement / time • v = s ÷ t • The magnitude (the size, the amount) of velocity, is speed.
Velocity (v) • If you walk from the 40-yard line of a football field to the 10-yard line in 5 seconds, what is your velocity? • v = Dx / t • v = (10 yd – 40 yd) / 5 s • v = (–30 yd) / 5 s • v = –6 yd s-1
Acceleration (a) • Acceleration is the rate of change of velocity. • a = Dv / t
Acceleration (a) • If you (in a sports car) go from 0 mph to 60 mph in 6 seconds, then your acceleration is: • 10 mph per second (10 mph s-1) • If I go from 0 to 60 mph in 10 seconds, then my acceleration is just 6 mph s-1. • We have the same change in velocity, but different accelerations.
Acceleration and Velocity • a = Dv / t • a = (v2 – v1) / t • Do a little algebra and see: • v2 = v1+ at • This says that the final velocity is equal to the initial velocity, plus the product of acceleration and time. • Some IB news…
Acceleration and Velocity • IB does not write it as: v2 = v1 + at • Instead we have:v = u + at • This saves us from the subscripts. • What does “v” represent? • What does “u” represent?
Velocities and Displacement (1 of 2) • 1: Average Velocity = Displacement / Time • 2: (u + v)÷2 = s / t • 3: s = {(u + v)÷2}•t
Velocities and Displacement (2 of 2) • If you accelerate, then of course that affects how far you go. • s = ut + (1/2)at2 • Combine some of the equations, and rearrange to get our last equation: • v2 = u2 + 2as
Graphs of Position vs. Time • The gradient (or slope) of a position graph is the velocity. • So, if an object is moving at constant velocity, then its x vs. t graph is a line. Draw. • If an object is not moving, then its position graph is a horizontal line. Draw. • If an object’s velocity is increasing, then the slope of its position graph is increasing. Draw.
Graphs of Velocity against Time • The gradient (or slope) of a velocity graph is the acceleration. • So, If an object is moving at constant velocity, then its velocity graph is a horizontal line. Draw. • If an object is moving at constant acceleration, then its v vs. t graph is a line. Draw. • The areaunder a graph of v vs. t is displacement.
Force (the cause of motion) • A force is a push or a pull. • Force is a vector. • An example of a force is when you push a button on your calculator. • Another example of a force is weight. Weight is the force that the earth puts on an object. The weight vector is always downward.
Mass • Mass is the amount of matter that an object possesses. • Mass is not a vector; mass does not have direction. • If an astronaut brings the key to her house with her on a mission, then the weight of the key will decrease, but the mass of the key will stay the same.
Sum of the forces. Net Force. SF • If you add up the forces that act on one object, you have the ‘sum’ of the forces or the ‘net force’. • What is the sum of the forces that act on a book that sits on a table? Is it zero? • Drop the book. Is the net force zero during the fall?
First Law of Motion • If the net force is zero, then the acceleration is zero. • If a = 0, then SF = 0. • This is the “Law of Inertia” discovered by Galileo (and embraced by Newton). • If the forces on an object add up to zero, then the object will continue to do what it was doing.
Second Law of Motion • Acceleration is determined by the _____ force and by the mass. • a = SF / m • If you see “F = ma”, then that ‘F’ must be the net force or “unbalanced force” or the “sum of the forces.”
Example of the Second Law of Motion • A book is resting on a table. • The mass of a book is 2 kg. • A person pushes Northward on the book with a force of 10 N. • Friction opposes this push with a force of 4 N. • What is the net force? • The net force is 6 N. • What is the acceleration? • a = (6 N) / (2 kg) = 3 m s-2.
Third Law of Motion • If object A puts a force on object B, then object B will put an equal and opposite force on object A. • This is sometimes called the “Action - Reaction” law.
If you stretch something, it pulls back.If you let it be, then there is no force.If you compress something, then it pushes back. http://cecs.boardeducation.net/dynamics-forum-f12/spring-force-hooke-s-law-t19.htm
Hooke’s Law • Always compare a spring to its ‘natural’ length. • If you compress the spring a distance Dx, then the spring will push back. And, the greater the Dx, the greater the push back. F = -Dx • Interestingly, it also works if you stretch the spring, and again the force that the spring exerts is opposite in direction to the change in length.