What is Newton's first law of motion?

Newton's first law of motion states that an object at rest will remain at rest, and an object in motion will continue in its motion at the same speed and in the same direction unless acted upon by a force.

What is the key takeaway from the air track experiment involving a block and a rubber band?

The takeaway is that a constant force on an object results in constant acceleration, demonstrating the direct relationship between force and acceleration and the inverse relationship between acceleration and mass.

How is force related to acceleration and mass according to Newton's second law?

According to Newton's second law, force is directly proportional to acceleration and inversely proportional to mass, as represented by the equation F = ma.

What is the unit of force?

The unit of force is the Newton (N), which is equivalent to a kilogram meter per second squared.

What does Newton's third law of motion state?

Newton's third law states that for every action, there is an equal and opposite reaction. This means that forces always occur in pairs of equal magnitude but opposite direction.

How does one draw a free body diagram?

To draw a free body diagram, identify all the forces acting on an object, draw a coordinate system, represent the object as a dot, and draw vectors for each force, ensuring each vector is labeled.

What happens to an object on Earth with no net force acting on it?

An object with no net force acting on it will either remain at rest or continue to move at a constant velocity.

How does mass affect acceleration if the force is constant?

If the force is constant, increasing the mass of an object will decrease its acceleration, as acceleration and mass are inversely proportional.

Why do all forces occur as action-reaction pairs?

All forces occur as action-reaction pairs because, according to Newton's third law, forces are interactions between two objects, each exerting an equal and opposite force on the other.

What is a practical application of understanding forces and free body diagrams?

Understanding forces and free body diagrams is essential for solving physics problems involving motion, such as calculating the net force on an object or determining how different forces interact to affect motion.

College Physics 1: Lecture 14 - Newton's Laws and Free-Body Diagrams

00:36:26

https://www.youtube.com/watch?v=Q6eP5uq0pJI

Summary

TLDRThis lecture provides an overview of Newton's three laws of motion and their implications, alongside the practical aspect of illustrating these concepts through free body diagrams. Newton's first law discusses the behavior of objects with no net force acting on them, emphasizing inertia. Newton's second law introduces the equation F = ma, linking force, mass, and acceleration, and explains the units of force, the Newton. Newton's third law, known for introducing the concept of action-reaction pairs, highlights that forces come in equal but opposite pairs. The lecture also dives into practical examples to explain these laws, such as the concept of constant acceleration on a frictionless surface and action-reaction examples like hammering a nail. Additionally, it details the process of drawing free body diagrams, which show all forces acting on an object and help visualize problem-solving in physics by breaking down forces into vectors. Exemplified through multiple-choice question discussions and real-life scenarios, the lecture thoroughly prepares students to apply these concepts to everyday phenomena and complex physics problems alike.

Takeaways

🚀 Newton's first law describes inertia and the behavior of objects without a net force.
📏 Newton's second law links force, mass, and acceleration with F = ma.
💡 Force is measured in newtons, equivalent to kilograms meter per second squared.
↔️ Newton's third law explains that forces come in action-reaction pairs.
📊 Free body diagrams visually represent forces acting on an object as vectors.
🎢 Constant force results in constant acceleration; mass inversely affects acceleration.
🌌 Space provides ideal scenarios to see Newton's laws without friction.
🔍 Identifying forces is crucial in drawing accurate free body diagrams.
🔄 Acceleration occurs with net force; without it, motion remains constant.
🔧 Real-life applications include understanding vehicle dynamics and other mechanics.

Timeline

00:00:00 - 00:05:00
The lecture begins with a recap of Newton's first law, which states that an object with no forces acting on it will remain at rest if stationary, or continue moving in a straight line at constant speed if in motion. This concept is difficult to visualize on Earth due to the presence of gravity, but is exemplified by objects in space, like an astronaut or dog floating in zero gravity, moving in straight lines at constant speeds.
00:05:00 - 00:10:00
The lecture introduces an experiment involving a block on a frictionless surface pulled with a constant force using a rubber band. The experiment illustrates that with constant force, an object will have constant acceleration, acceleration increases with increased force, and acceleration decreases with increased mass. This leads to Newton's second law, formulated as F=ma, where force is proportional to acceleration and inversely proportional to mass. The unit of force is defined as a Newton (1 N = 1 kg·m/s²).
00:10:00 - 00:15:00
Newton's third law of motion is discussed, emphasizing the action-reaction principle: if an object A exerts a force on object B, B will exert an equal and opposite force on A. This applies to all forces, including gravity, exemplified by the Earth and moon. The lecture then transitions to introducing free body diagrams (FBDs), crucial for visualizing forces acting on an object.
00:15:00 - 00:20:00
The lecture details steps to create a free body diagram: identify all forces acting on an object, draw a coordinate system, represent the object as a dot and forces as vectors, and optionally label the net force vector. Emphasis is placed on correctly identifying and labeling forces for accurate problem-solving in physics.
00:20:00 - 00:25:00
A series of conceptual and practical questions are posed to assess understanding of Newton's laws and free body diagrams. Examples involve accelerating objects, tension, weight, and net forces. Students are encouraged to think about the relationships between force, mass, and acceleration using the examples provided such as a train vs. skier, and scenarios involving ropes and forces.
00:25:00 - 00:30:00
Then, the lecture proceeds with exercises surrounding drawing and interpreting free body diagrams for various scenarios including an elevator stopped by a rope, a ball tossed upward, and a parked car on a hill. Correctly representing forces, considering direction and magnitude, and using Newton's laws for analysis is emphasized. Action-reaction pairs and equilibriums in forces like tension and weight are discussed.
00:30:00 - 00:36:26
The lecture concludes with practical examples to solidify understanding of free body diagrams, emphasizing equal and opposite forces for objects moving with constant speeds. It hints at future lectures integrating mathematics with these diagrams for problem-solving. The importance of accurately creating and interpreting free body diagrams for understanding forces in physics is reiterated.

Mind Map

Video Q&A

What is Newton's first law of motion?
Newton's first law of motion states that an object at rest will remain at rest, and an object in motion will continue in its motion at the same speed and in the same direction unless acted upon by a force.
What is the key takeaway from the air track experiment involving a block and a rubber band?
The takeaway is that a constant force on an object results in constant acceleration, demonstrating the direct relationship between force and acceleration and the inverse relationship between acceleration and mass.
How is force related to acceleration and mass according to Newton's second law?
According to Newton's second law, force is directly proportional to acceleration and inversely proportional to mass, as represented by the equation F = ma.
What is the unit of force?
The unit of force is the Newton (N), which is equivalent to a kilogram meter per second squared.
What does Newton's third law of motion state?
Newton's third law states that for every action, there is an equal and opposite reaction. This means that forces always occur in pairs of equal magnitude but opposite direction.
How does one draw a free body diagram?
To draw a free body diagram, identify all the forces acting on an object, draw a coordinate system, represent the object as a dot, and draw vectors for each force, ensuring each vector is labeled.
What happens to an object on Earth with no net force acting on it?
An object with no net force acting on it will either remain at rest or continue to move at a constant velocity.
How does mass affect acceleration if the force is constant?
If the force is constant, increasing the mass of an object will decrease its acceleration, as acceleration and mass are inversely proportional.
Why do all forces occur as action-reaction pairs?
All forces occur as action-reaction pairs because, according to Newton's third law, forces are interactions between two objects, each exerting an equal and opposite force on the other.
What is a practical application of understanding forces and free body diagrams?
Understanding forces and free body diagrams is essential for solving physics problems involving motion, such as calculating the net force on an object or determining how different forces interact to affect motion.

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00:00:01
hello and welcome to college physics 1
00:00:03
lecture 14 newton's laws and free body
00:00:06
diagrams
00:00:09
in our last lecture we introduced force
00:00:11
and different types of forces
00:00:14
in this lecture our goal is to go
00:00:16
through newton's three laws of motion
00:00:19
and then introduce how we represent each
00:00:21
of these forces we've discussed
00:00:23
visually with free body diagrams
00:00:27
to begin let's recap newton's first law
00:00:29
because we did introduce this in our
00:00:31
past lecture
00:00:33
in general uh when we think of newton's
00:00:36
first law we're considering any object
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that has no forces acting on it none
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whatsoever
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so in theory this is fairly
00:00:46
unrealistic on earth because almost
00:00:49
everything has a force acting on it
00:00:50
especially because of weight
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but that said if we consider an object
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that has no forces acting on it
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whatsoever
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then we can talk about newton's first
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law
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if the object is at rest
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with no forces acting on it
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it will remain at rest
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i mean this makes sense saying you leave
00:01:10
a pencil sitting on your tabletop it's
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not going to move unless something acts
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to move it
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and then if the object is moving with no
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forces acting on it it will continue to
00:01:22
move in that same direction in other
00:01:24
words a straight line and without
00:01:26
changing its speed it'll stay the same
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constant speed until
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something acts on it
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now again this is somewhat hard to
00:01:35
visualize on earth because it's not
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realistic
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so that takes us to space
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in many cases the best example of this
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is an object moving through
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space
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so on the top i just put in an image
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from south park of kenny uh floating
00:01:51
through space but notice he's moving in
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a straight line and perhaps somewhat
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hard to tell but at a constant speed
00:01:57
and then another great example is this
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dog
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that was in orbit or on the earth so
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effectively experiencing zero g's
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and as a result in each of the frames of
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this animation you can see the dog
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moving in a straight line and at a
00:02:11
constant speed even when he's paddling
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in one of the frames it's not changing
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his motion at all
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so
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this is newton's first law again this is
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just a recap
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so this brings us then to something new
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here we're going to consider an
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experiment that we can't really do well
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or easily on earth
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in my class in person
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we can use an air track that is a
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surface like an air hockey table where
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there's holes in it and air blown into
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the surface
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so that's anything laying on top of the
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surface can
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experience almost no friction but even
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still it's not a perfect experiment
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so just consider a block
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on a frictionless surface
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and then imagine you take a rubber band
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put it around the block
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and then you pull it
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specifically you pull it to maintain a
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constant force in other words you aren't
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letting the rubber band compress or
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stretch at all so it's staying at a
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constant force or a constant
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stretchiness
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if we do this experiment successfully we
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would find a number of different things
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first of all and this is the hardest one
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to visualize
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the block pulled with a constant force
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in other words not letting your rubber
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band stretch or compress
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would have to move with a constant
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acceleration
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meaning
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you would have to constantly pick up
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speed
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and again even if we had the air track
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and i showed you it it's hard to
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visualize it because you aren't the one
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actually moving the block you'd have to
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feel how stretchy the rubber band is but
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just try to visualize that
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so if you want to move something with a
00:03:55
constant force you would have to
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constantly accelerate it
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the other two results of this experiment
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are fairly straightforward
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the acceleration of the object would
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increase if you increase the force
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in other words if you pull harder the
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block would accelerate faster
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and
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the acceleration would decrease
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if the mass of the block increased
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so just imagine you try to apply the
00:04:24
same force to an object that's 10 times
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heavier
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well it's going to be harder to
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accelerate that object
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so what we can do with this information
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is sort of combine it all into one big
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piece of information
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the first statement statement we made
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was that with a constant force you have
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a constant acceleration
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and the acceleration will increase if
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the force does
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so that's telling us that there is a
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direct relationship between force and
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acceleration
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if force increases so does acceleration
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and then we say acceleration decreases
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if the mass increases in other words
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acceleration and mass are inversely
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proportional to one another
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putting all of that together we arrive
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at newton's second law
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newton's second law is a mathematical
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equation
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it states an object of mass m
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subjected to forces be it 1 2 3 and so
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on
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will undergo an acceleration given by
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f net
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over m
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where f net is the net or total force
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and m is the mass
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so recognize on this left-hand equation
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that
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we see a direct relationship between a
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and f we said that if you increase the
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net force you increase the acceleration
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but if you increase the mass in other
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words you increase m underneath this
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fraction
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well then you're dividing by more which
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means your acceleration would decrease
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so this equation
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is what we just stated in our experiment
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it's just a formulation to show it
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now this rearranges of course to one of
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the most famous equations in all of
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physics
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f equals m a
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i'd argue that this and probably e
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equals m c squared are like the two most
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well-known equations in physics
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um and for good reason this is going to
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be an equation that we use throughout
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the next
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i don't know
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seven lectures probably um it's the
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premise of all the problems we're going
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to work out uh and we'll actually see
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that an equation this small and innocent
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looking is not so much that case as we
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get into this further
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now the only thing left to discuss on
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this
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equation is the units
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up until this point we've introduced
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what forces but we never said what the
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units of force are
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this equation allows us to visualize
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that
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we see f is equal to m a
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m or mass is measured in physics
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in kilograms
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a or acceleration is measured in meters
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per second squared
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so combine the two you have a kilogram
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times a meter per second squared
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that is the unit of force
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a kilogram meter per second squared
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but that's kind of ugly and we don't
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like to work with that most of the time
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so we just give it a new name
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we call a kilogram meter per second
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squared a newton or 1n
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this is what we use as the unit of force
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the newton
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all right this then brings us to
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newton's third law of motion out of
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three newton's third law is an action
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reaction discussion
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so consider for example you are
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hammering a nail into a wall
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obviously you with the hammer are
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applying a force to the nail so that it
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is put punched into the wall
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but the nail also pushes back at the
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hammer in fact you experience that as a
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recoil
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right if you hit something really hard
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with a hammer you can feel that recoil
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in the handle
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an even better example perhaps is if you
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fire a rifle or a shotgun with the stock
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of that weapon up against your shoulder
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when you fire the bullet or the shell
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out the front the weapon kicks back into
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your shoulder
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you can experience that reaction
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so in general we don't have to be
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specific and say a hammer or a gun we
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can just say if object a exerts a force
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on some object b then object b will
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exert a force back on a
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this is a pair of forces that we call an
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action reaction pair
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now i will note i don't necessarily at a
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personal level like that term action
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reaction
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mostly just because by definition
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reaction means
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you see or experience something and then
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respond
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these forces occur simultaneously so
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it's not really that one happens and
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then the other one decides hey i need to
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apply a force too they happen at the
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exact same time
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but regardless well i mean thinking of
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it as action reaction is just a really
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easy way to remember what's happening so
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it is useful
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so newton's third law says in general
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that every single force
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occurs as a member of this
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action-reaction pair of forces
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and they have equal magnitude so it's an
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equal force between the two
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but they are pointed in opposite
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directions
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so you commonly hear this is for every
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action there's an equal and opposite
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reaction that's a common statement
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so with this we now have a basic
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understanding of what forces are and the
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three laws of motion that govern them
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these laws apply to any object anywhere
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anywhere in the universe
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and what's kind of crazy to think about
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is that this newton's third law this
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action reaction it's true for every
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single force
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it's even true for the gravity of earth
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holding the moon in orbit the moon is
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also tugging on the earth with an equal
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force the difference is the moon is so
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much smaller that it orbits around the
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earth instead of vice versa
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but i digress
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to conclude the notes part of this
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lecture we have to introduce free body
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diagrams
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now if you have my actual course you
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will hear me say this a lot but these
00:10:40
are severely important you really want
00:10:42
to understand these
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so
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in the next slide here i'm just going to
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step you through what a free body
00:10:49
diagram is and how to draw them
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and then for the remainder of this
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lecture we're just going to work out
00:10:54
problems like questions together
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so you can get some practice working
00:10:58
with these free body diagrams before we
00:11:00
try drawing them ourselves
00:11:04
so
00:11:05
in general a free body diagram or as i
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abbreviate them fbd
00:11:10
these are diagrams that represent
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objects as a particle or dot
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and then show all of the forces acting
00:11:16
on the object as vectors or arrows
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pointing away from the dot
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so you'll see a lot more about what i
00:11:24
mean here in just a few minutes but
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let's run through the steps the single
00:11:28
most important step to all of this
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is identifying the forces that are
00:11:33
acting on your object
00:11:35
if you don't know what forces are acting
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on your object you can't draw one of
00:11:38
these diagrams properly and then you
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certainly couldn't work out the problem
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correctly
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so really everything relies on you
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understanding the problem you have
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and then the forces involved within it
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so identify your forces
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steps two and three kind of go together
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and they're hardly steps at all
00:11:59
for every free body diagram you draw a
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coordinate system in other words an x
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and a y axis and if you're along a ramp
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like we discussed in the past you tilt
00:12:08
your axes along the incline so that the
00:12:11
x-axis is along the slope
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so i mean really these all start by you
00:12:17
just drawing basically a large plus sign
00:12:18
on your paper your coordinate axes
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don't forget to label them and then step
00:12:25
three again barely even a step just draw
00:12:27
a big dot at the center
00:12:30
so at this point all you've done is
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drawn a big plus sign and a little dot
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in the middle
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now once you've identified your forces
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you'll be able to draw them onto your
00:12:40
free body diagram
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so draw vectors in other words arrows
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representing each of the forces that
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you've identified
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last but not least and
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i tend to forget this one myself or just
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not do it i'd say that it's optional
00:12:58
i would still like you to do this but
00:13:00
you want to draw and label the net force
00:13:02
vector afterward
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you typically don't draw this directly
00:13:06
onto the axes like you do with the other
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forces though
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a lot of times you'll just kind of draw
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this off to the side
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just so that you
00:13:14
for your own sake
00:13:16
can remember what direction the net
00:13:18
force will be pointing if there is one
00:13:21
and i suppose i should add into step
00:13:23
number four and it's very important that
00:13:25
you label each of your vectors
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otherwise it's just a bunch of arrows on
00:13:31
a page
00:13:33
so labeling them appropriately is very
00:13:35
important as well especially when it
00:13:36
comes to me grading your diagrams
00:13:38
because
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like i mentioned if there's no labels i
00:13:41
don't know what force you're thinking of
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and it's just an arrow on the page
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so don't forget to label your vectors
00:13:49
okay so this isn't entirely helpful
00:13:51
since you haven't even seen one of these
00:13:53
drawn yet so let's step through a few
00:13:55
questions and after several of them we
00:13:57
will get to free body diagrams
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so
00:14:01
we're going to go through a lot of
00:14:02
questions here i believe there's
00:14:03
actually 12 of them
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so
00:14:06
i encourage you to pay attention to each
00:14:08
one as they are very important it'll get
00:14:10
you some practice with these diagrams
00:14:12
toward the end as well
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so question one
00:14:17
a cart is pulled to the right as shown
00:14:19
below at a uh with a constant force
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it asks how will its acceleration graph
00:14:25
look
00:14:26
so this is a throwback to graphs take a
00:14:28
moment to think about your answer and
00:14:30
then come back when you think you have
00:14:31
it
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okay
00:14:36
well in this case the key here is that
00:14:37
it's being pulled with a constant force
00:14:41
generally what you want to do is think
00:14:43
of newton's second law here which says f
00:14:46
net
00:14:48
is equal to m a
00:14:51
so with this in mind
00:14:54
it says that there's a constant force
00:14:56
being applied so your force f is not
00:14:59
changing
00:15:01
well we know mass isn't changing
00:15:03
so if neither f or m are changing well
00:15:06
then how can a change
00:15:08
right
00:15:09
if a net force is constant the
00:15:11
acceleration also has to be constant
00:15:14
so on an acceleration graph
00:15:17
that would show up as a straight
00:15:18
horizontal line like we see here
00:15:22
in c
00:15:23
a constant force means you're you'll be
00:15:25
applying a constant acceleration to the
00:15:27
object
00:15:31
all right
00:15:32
question two
00:15:34
a constant force causes an object to
00:15:37
accelerate at four meters per second
00:15:39
squared
00:15:40
what is the acceleration of an object
00:15:42
with twice the mass but the same force
00:15:47
i'll give you a hint it has to do with f
00:15:49
equals ma
00:15:55
okay
00:15:56
the problem here is asking about the
00:15:58
acceleration so let me rearrange our
00:16:00
equation
00:16:01
a
00:16:02
equal f over m
00:16:04
equal to f over m
00:16:08
well what we've done is in this problem
00:16:10
it says that we are going to
00:16:14
double the uh mass right
00:16:17
so it says it has twice the mass so what
00:16:19
we're basically doing is
00:16:21
doubling the mass so multiply by two
00:16:23
down here but it has the same force so
00:16:26
one
00:16:28
so we're keeping the same force we're
00:16:31
doubling the mass
00:16:33
so our acceleration is going to change
00:16:35
by a factor of one half
00:16:38
in other words if we started out with
00:16:39
four meters per second squared we would
00:16:42
end up with an answer
00:16:44
of two meters per second squared
00:16:47
and again this holds true to ride our
00:16:49
idea that if you increase the mass
00:16:51
you're going to decrease
00:16:53
the acceleration
00:16:59
all right let's do one more like the
00:17:00
last
00:17:01
an object when pushed with a net force f
00:17:04
has an acceleration of 2 meters per
00:17:06
second squared
00:17:08
now
00:17:09
you double the force and you quadruple
00:17:12
the mass
00:17:14
its acceleration will be what
00:17:26
all right
00:17:27
well again this problem is asking about
00:17:29
acceleration so let me rearrange the
00:17:31
equation again
00:17:33
for f over m
00:17:36
similar to what we did last time let's
00:17:38
think about by what factor we are
00:17:40
changing things we are saying that the
00:17:42
force is twice as large
00:17:45
so
00:17:45
you're changing the force by a factor of
00:17:47
two
00:17:49
well we're also quadrupling the mass or
00:17:51
multiplying it by four times
00:17:55
so
00:17:56
we've changed our acceleration by a
00:17:57
factor of two over four which is one
00:18:01
half
00:18:02
so we
00:18:03
have our
00:18:05
acceleration once again
00:18:07
so the answer
00:18:09
half of two meters per second squared
00:18:12
is one meter per second squared
00:18:18
all right well let's step away from the
00:18:20
math for the rest of our questions let's
00:18:21
think conceptually and then visually as
00:18:23
well
00:18:25
the next two questions are very good i
00:18:26
like these ones a lot
00:18:28
this question says a 40 car train
00:18:32
travels along a straight track at 40
00:18:34
miles per hour
00:18:36
separately
00:18:37
a skier speeds up as she skis downhill
00:18:41
based on these two different situations
00:18:44
on which could we say that the net force
00:18:46
is greater if either
00:18:48
at all
00:18:55
a lot of times with this question my
00:18:57
students will just have a big question
00:18:58
mark above their head
00:19:00
uh it's weird to think about i mean a
00:19:02
train and a skier and how can you
00:19:04
compare their forces
00:19:06
well i mean you can you actually can
00:19:09
tell there's a key here
00:19:12
the skier is speeding up
00:19:14
the train is moving at 40 miles per hour
00:19:18
the train's moving at a constant speed
00:19:21
the skier is accelerating
00:19:23
again think of f equals ma
00:19:28
to have a force a net force right
00:19:31
we need to be
00:19:33
accelerating
00:19:35
if you don't have an acceleration you do
00:19:38
not have a net force
00:19:40
so the train even though it's this giant
00:19:42
massive object has no net force acting
00:19:45
on it
00:19:46
but the skier even though we don't have
00:19:48
a number
00:19:50
does have an acceleration we know
00:19:51
there's an acceleration because she is
00:19:54
speeding up
00:19:56
so we don't know how big the net force
00:19:58
is but we know it's more than zero
00:20:00
so the skier
00:20:02
has the greater net force
00:20:06
okay so again the train does not have a
00:20:08
net force because it is not accelerating
00:20:11
the skier is accelerating so they do
00:20:14
have a net force
00:20:15
so the answer is b
00:20:21
all right let's move on to question five
00:20:25
an object on a rope is lowered at a
00:20:28
constant speed
00:20:29
which of the following is true
00:20:36
okay
00:20:37
well here we should be able to recognize
00:20:39
what forces are acting on our object
00:20:42
we should note that there is a weight
00:20:45
pulling downward on the object
00:20:47
right we have a weight pulling down
00:20:50
and there is a tension holding this
00:20:52
object upward
00:20:54
so we know that there's a weight and a
00:20:56
tension
00:20:58
now
00:20:58
the key here is it says it's at a
00:21:00
constant speed as we just stated on our
00:21:03
last question by f equals m a
00:21:07
we should recognize that
00:21:09
in order to have a net force you would
00:21:11
have to have an acceleration
00:21:14
we don't accelerate in this problem so
00:21:16
we do not have a net force
00:21:19
right no acceleration
00:21:21
no net force
00:21:23
which means
00:21:25
even though there are forces there can't
00:21:27
be a net force which must mean
00:21:31
the tension pointing up has to equal the
00:21:33
weight pointing down so that there is no
00:21:36
net force
00:21:38
in other words one of them isn't pulling
00:21:40
harder
00:21:41
in the other direction
00:21:43
so the answer is that they are equal
00:21:46
our answer is b
00:21:51
okay
00:21:54
question six
00:21:55
a very similar one the only difference
00:21:58
is
00:21:58
now instead of moving at a constant
00:22:00
speed it says that it is lowered at a
00:22:03
decreasing speed
00:22:06
which is true
00:22:15
okay
00:22:16
well the situation is the same we have a
00:22:18
weight pointing downward so i'll draw
00:22:20
that
00:22:22
here's our weight
00:22:25
upward is our tension
00:22:26
but here is the key and this is
00:22:28
important be careful with how i or pay
00:22:30
attention to how i say this
00:22:33
it is lowered
00:22:35
at a decreasing speed
00:22:38
from past lectures we learned how to
00:22:40
deal with the direction of acceleration
00:22:44
recall that if an object is slowing down
00:22:47
like the object here
00:22:49
acceleration points in the opposite
00:22:51
direction of the object's motion
00:22:55
so if our object is pointing downward
00:22:58
or moving downward which it is
00:23:00
then our acceleration because it's
00:23:02
slowing down must point in the opposite
00:23:03
direction or upward
00:23:07
so if we have
00:23:10
an upward pointing acceleration
00:23:14
then we must also have an upward
00:23:16
pointing net force
00:23:18
if a points up
00:23:20
net force points up
00:23:22
which means we have to have a larger
00:23:24
force that points upward
00:23:27
so i'll draw that as a longer arrow for
00:23:30
tension
00:23:32
so tension in this case is greater than
00:23:35
the weight of the object
00:23:36
so the answer
00:23:38
is a
00:23:40
so again be careful this is not very
00:23:43
easy for a lot of students
00:23:45
we are slowing down while moving
00:23:47
downward which means because we're
00:23:49
slowing down acceleration points in the
00:23:50
opposite direction or upward
00:23:53
and based on our concept of the
00:23:55
relationship between f and a
00:23:58
if acceleration is pointing upward so
00:24:00
does the net force
00:24:02
so whichever force is pointing upward
00:24:04
also
00:24:05
or uh has to be the larger force
00:24:08
that's the tension force so the answer
00:24:11
is a
00:24:15
all right
00:24:16
on to my favorite question out of the
00:24:18
bunch
00:24:19
a mosquito runs head-on into a truck
00:24:22
splat
00:24:24
which of the following is true
00:24:25
during the collision
00:24:30
in this case we have to think about
00:24:33
newton's
00:24:34
third law
00:24:36
newton's third law states that every
00:24:38
force occurs as an action reaction pair
00:24:41
where the forces are in opposite
00:24:43
directions
00:24:44
but are equal in magnitude
00:24:49
equal in magnitude
00:24:51
which means
00:24:52
perhaps surprisingly to some people
00:24:55
the answer is c
00:24:56
they will exert the same force on each
00:24:58
other the mosquito to the truck and the
00:25:00
truck to the mosquito
00:25:02
now this is very odd to some people so
00:25:05
let me just
00:25:06
show efficient again
00:25:12
in the case of let's say the truck
00:25:13
hitting the mosquito
00:25:15
well think about what's going on here
00:25:17
the truck has a really large mass
00:25:22
but
00:25:23
because the truck hits the mosquito is
00:25:25
it going to change its speed very much
00:25:27
i mean no the mosquito's not going to
00:25:28
slow the truck down at all so it has a
00:25:31
very
00:25:32
low
00:25:33
acceleration
00:25:36
on the other hand the mosquito has a
00:25:38
really low mass
00:25:41
i mean tiny mess
00:25:43
but it's just floating around around
00:25:45
having its you know day trying to ruin
00:25:47
people's day and then it's suddenly hit
00:25:49
by a truck moving i don't know 70 miles
00:25:51
per hour so it's going to be suddenly
00:25:53
accelerated
00:25:54
really quickly so it's got a low mass
00:25:57
and a high acceleration but the truck
00:25:59
has a high mass and a low acceleration
00:26:02
they are equal
00:26:06
all right
00:26:07
let us now practice free body diagrams
00:26:10
now that we have this background
00:26:12
let's try drawing them
00:26:15
the first of five of these diagram
00:26:18
questions
00:26:19
says an elevator which is lifted by a
00:26:21
cable is moving upward and slowing down
00:26:25
which is the correct diagram
00:26:32
all right well it's moving up and
00:26:34
slowing down we know there are two
00:26:36
forces in this problem weight pointing
00:26:38
downward
00:26:40
tension in the cable pointing upward
00:26:42
like d shows there is not a third force
00:26:45
it says f elevator
00:26:47
the force pointing upward is caused by
00:26:50
the tension so there isn't an extra
00:26:51
force here
00:26:53
so that's irrelevant
00:26:55
it is moving upward but motion is not a
00:26:58
force
00:27:01
and because it is slowing down that
00:27:03
means there is an acceleration which
00:27:05
means there is a net force
00:27:08
we can rule out option d and e as a
00:27:10
result now
00:27:16
so
00:27:17
keeping in mind what we said in our last
00:27:19
question
00:27:21
we have a situation where we're moving
00:27:24
up but slowing down
00:27:26
slowing down means acceleration points
00:27:28
in the opposite direction of motion
00:27:30
which would be downward
00:27:33
so if we have an acceleration that's
00:27:35
pointing downward
00:27:36
we have to have a net force that is
00:27:38
pointing downward as well
00:27:41
in other words whichever force is
00:27:42
pointing downward has to be the larger
00:27:44
force
00:27:45
leaving us with the answer of c
00:27:49
weight down tension up but because
00:27:51
acceleration points downward the force
00:27:54
that's pointing downward has to be
00:27:55
larger to give us the larger net force
00:28:01
all right so that's a chain
00:28:03
of thought processes you have to go
00:28:04
through to get there so be careful with
00:28:07
these
00:28:09
question nine
00:28:11
a ball has been tossed straight up
00:28:14
which of the following is the correct
00:28:15
free body diagram just after the ball
00:28:18
has left the hand
00:28:19
as always
00:28:20
ignore air resistance
00:28:26
in this case
00:28:28
the ball has left the hand
00:28:30
meaning there are no contact forces on
00:28:32
the ball nothing is physically touching
00:28:35
it
00:28:36
what that means is there's only
00:28:38
one force acting on it
00:28:41
it's weight the weight due to gravity as
00:28:44
it moves through the air
00:28:46
the answer is d
00:28:47
any object moving through the air
00:28:50
will only ever have one force acting on
00:28:53
it the weight
00:28:55
assuming we're ignoring air resistance
00:28:56
of course
00:28:59
so the answer is d only the weight is
00:29:01
acting on the ball
00:29:03
if the ball was still in the person's
00:29:05
hand as it was being pushed upward
00:29:08
then you'd certainly have an upward
00:29:09
force but we don't in this case
00:29:16
next question
00:29:18
a ball is hanging from the ceiling by a
00:29:20
string
00:29:21
it is pulled back and released
00:29:23
which is the correct free or which
00:29:25
diagram below is the correct one just
00:29:27
after the ball has been released like
00:29:29
you can see on the image on the top
00:29:30
right
00:29:35
all right
00:29:37
in this case
00:29:38
the first thing i'll mention is that
00:29:41
the rope is at an angle
00:29:43
but it's not an object moving on a ramp
00:29:46
or an incline so we do not tilt our axes
00:29:49
in this case like shown in c or excuse
00:29:52
me like shown in e
00:29:54
we don't tilt our axes that is only for
00:29:56
objects that are moving along an
00:29:58
inclined surface this is just a ball
00:30:00
swinging back and forth
00:30:04
let's think about one of the forces
00:30:06
acting on this ball one of the forces is
00:30:09
weight
00:30:10
by definition weight always points
00:30:13
vertically downward
00:30:15
which means we can rule out
00:30:17
d
00:30:18
d does not show the weight force
00:30:20
pointing downward so that is incorrect
00:30:24
a b and c all show that
00:30:27
so a shows that there's only the weight
00:30:30
but
00:30:31
there's more than that
00:30:34
the object is being held up by a rope
00:30:37
so there should be a tension force
00:30:40
that tension force by definition always
00:30:42
points in the direction of your rope
00:30:43
which is up and to the right
00:30:45
both b and c show that
00:30:49
at this point we just have to ask
00:30:50
ourselves is there a third force
00:30:54
c shows the third force pointing down
00:30:56
into the right which is
00:30:58
the direction of the well not quite it
00:31:01
is the direction of the object's motion
00:31:04
but
00:31:05
motion is not a force
00:31:08
nothing is physically pushing the ball
00:31:11
down into the right
00:31:12
there is no third force
00:31:16
just to give you an idea on why it does
00:31:18
move that way
00:31:20
think of vector addition
00:31:22
right if you can just visualize this say
00:31:24
someone's pulling down on the ball here
00:31:26
someone's pulling up on the right to the
00:31:27
ball there that means the ball is going
00:31:29
to move with a net force that points in
00:31:32
that direction
00:31:34
right those two forces combined are
00:31:36
going to pull the object down into the
00:31:37
right which is why we see the ball doing
00:31:39
that
00:31:41
anyways this means the answer is
00:31:44
b you have the weight of the ball acting
00:31:46
downward and the tension in the row
00:31:48
pointing up and to the right
00:31:53
question 11
00:31:55
a car is parked on a hill
00:31:58
which is the correct free body diagram
00:32:04
well in this case we are on an incline
00:32:06
so we do tilt our axes which all of
00:32:08
these show
00:32:10
what we need to do though is start
00:32:12
listing our forces first of all like any
00:32:15
problem on earth we have a weight
00:32:18
we know that weight
00:32:20
always points vertically downward
00:32:23
well
00:32:24
d does not show a force pointing
00:32:27
straight down
00:32:29
d is incorrect because of that
00:32:31
a b c and e all show a weight force
00:32:35
pointing straight down
00:32:38
let's think of another force
00:32:41
car is parked on a hill
00:32:44
it's parked meaning it's not moving
00:32:47
so something has to be resisting its
00:32:49
motion and that's friction
00:32:52
friction is acting to resist the motion
00:32:54
of this car the car wants to move down
00:32:57
the hill
00:32:58
so there must be a friction force
00:33:00
pointing
00:33:01
up the hill
00:33:03
a
00:33:04
does not show a force pointing up the
00:33:06
hill in the x direction
00:33:08
b
00:33:09
does not show a force pointing up the
00:33:11
hill it shows a force pointing down the
00:33:13
hill which is not correct
00:33:15
both c and e show the weight pointing
00:33:18
downward and a friction force pointing
00:33:20
up the hill
00:33:22
so we now at this point ask ourselves is
00:33:24
there a third force
00:33:27
in this case
00:33:29
there is
00:33:31
there is a third force the answer is c
00:33:34
here
00:33:35
that third force is because the car is
00:33:37
on a surface
00:33:39
a surface always pushes back
00:33:41
perpendicularly by the normal force
00:33:45
so that's what we're seeing here we're
00:33:46
seeing a normal force pointing off the
00:33:48
surface of the ramp
00:33:49
a static friction force holding the car
00:33:52
in place
00:33:54
and the weight of the car pulling it
00:33:56
downward
00:33:57
c is the correct
00:33:59
free body diagram
00:34:03
this brings us to our very last question
00:34:06
there's been a lot of them
00:34:08
question 12.
00:34:09
a car is towed by a rope to the right at
00:34:12
a constant speed
00:34:13
which diagram is correct
00:34:19
okay i'm going to go through this one a
00:34:21
little quicker since we should have some
00:34:22
practice
00:34:23
we know there's a weight pulling the car
00:34:25
downward all of them show that
00:34:28
we know there is a normal force pulling
00:34:30
or pushing upward
00:34:32
all of them show that
00:34:34
there should be
00:34:35
a tension force in the cable pulling it
00:34:38
forward to the right
00:34:41
a does not show a force to the right
00:34:44
but there should also be a force
00:34:46
resisting the car's motion
00:34:48
it doesn't say that it's frictionless so
00:34:50
there should be a friction force
00:34:52
resisting the car's motion as well
00:34:56
against the up against the direction of
00:34:57
the car so to the left
00:35:00
so there isn't a force to the left in b
00:35:02
we can rule that one out as well
00:35:05
this brings us to options c d and e
00:35:08
all of these show the correct four
00:35:10
forces
00:35:11
but there's a difference
00:35:13
c shows that the tension is greater than
00:35:16
the friction
00:35:18
uh oops that's normal force this is
00:35:21
weight
00:35:22
um imagine using the same letters over
00:35:24
here
00:35:25
in d the two forces friction and tension
00:35:27
are the same
00:35:29
and in e the friction is the larger of
00:35:31
the two
00:35:33
well keep in mind it says that this is
00:35:35
moving at a constant speed
00:35:38
that means there is no net force
00:35:42
so all of the forces should be equal and
00:35:44
opposite
00:35:45
and that's what d shows
00:35:48
d shows our equal and opposite forces
00:35:51
so that is our answer
00:35:56
all right so uh at this point we've at
00:35:58
least introduced what a free body
00:36:00
diagram is now and how to draw them
00:36:03
so in the future we will actually be
00:36:05
drawing them ourselves from scratch not
00:36:06
just picking them from a multiple choice
00:36:08
question
00:36:09
so hopefully at least for now this has
00:36:11
given you at least
00:36:12
a basic understanding of what they look
00:36:14
like and how they will be drawn
00:36:16
in our next lecture we will start to add
00:36:18
some math into all of this and start
00:36:20
drawing these ourselves but until then
00:36:23
thanks for watching and have a great day