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Physics: Two Dimensional Motion: Separating Your X From Your Y 10 Views


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Two dimensional motion: separating your X from your Y.

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English Language
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Transcript

00:01

do you know motion separating your ex from your Y well here we go [text on screen]

00:37

as we all know motion can go in one direction at a time right wrong [teacher speaking to students]

00:44

there is actually something called two-dimensional motion it's a little

00:48

more complicated than a one-dimensional motion as you can imagine so up until

00:52

now we've just been ignoring it haha but we can ignore it no longer in our [man jumps up to kick soccer ball]

00:57

previous lessons we've focused on displacement in just one direction or [dog walking down path]

01:01

one dimension to be precise the displacement could be negative or

01:05

positive it might have been all vertical or all horizontal but it was never boats [eagle flapping its wings]

01:10

in real life though we're dealing with more than one dimension let's say we're

01:15

playing fetch in the park with our pet anteater Charlie when we throw the ball [woman throws ball in park for anteater]

01:20

to Arvid to get we don't just throw it horizontally we've got to get some air

01:24

under the throw also so we throw it up in the air but not straight up because

01:30

all it needs his exercise so if you're thinking of this on a graph

01:34

we've got displacement on the y-axis and on the x-axis - which makes it easier to [graph on screen]

01:38

work with because we can look at the movement on each plane separately but

01:43

before we get too deep into this let's make things even easier here on earth

01:48

any motion has to deal with friction anything sliding on the ground has [train going by, anteater gets dragged away]

01:52

friction think you can escape it - by rolling instead no the friction is [anteater riding in a buggy]

01:56

different but it's still there even something flying in the air has the

02:00

force of friction for working against it which is why most meteorites burn up [meteorite zooming towards earth]

02:04

before they can hit surface but remember when we said we

02:07

like simple things so for now we're going to forget about friction we're

02:11

going to pretend it just isn't there don't worry all your friction fans we'll

02:15

get into it eventually but we want to understand the fundamentals of motion

02:19

here something else that will help us with those fundamentals we're going to

02:23

assume that any horizontal motion is constant we're also going to assume that

02:27

any vertical motion is accelerated by gravity and only gravity so when we

02:32

throw a ball in the air we're not going to be graphing its motion if an eagle [eagle steals ball]

02:35

swoops down and grabs it one important thing to understand is that horizontal

02:39

and vertical motion are independent of each other

02:41

what do we mean by that well let's do a little thought experiment say we're

02:46

going to play a little paintball I'm gonna fire off a test shot to make sure

02:50

nothing jams up when it counts so we line up the gun parallel with the ground

02:54

completely horizontal if our friend lets a paintball drop to the ground at the [man with paintball gun]

02:59

same height as our gun and it drops at the exact same time as we pull the [woman holding ball in hand]

03:04

trigger which ball hits the ground first the one shot out of the gun or the one

03:08

our friend just drops we might think that the ball that's shot out of the gun

03:13

will stay in the air longer after all it's covering so much distance

03:16

horizontally but in fact both would hit the ground at the exact same time and

03:22

that's because the horizontal motion is completely separate from the vertical [paint balls splatter on ground]

03:27

motion the effective gravity the downward acceleration is exactly the

03:32

same on both paintballs so even though the horizontal velocity is completely

03:36

different the vertical displacement velocity and acceleration are the same

03:41

if you want to see this with a real gun and a real bullet the Mythbusters did an [woman watching tv from couch]

03:46

experiment on the exact same things you can click on the link here to watch a

03:50

consolidated version of the experiment verdict physics tells the truth but then

03:55

physics always tells the truth that's why we like it so much as we've said

04:00

vertical and horizontal motion are independent of each other but that [writing on chalk board]

04:03

doesn't mean they're not linked what's the link between them time at any point

04:08

in time we can describe an object horizontal or vertical displacement its

04:13

horizontal or vertical velocity or its horizontal and vertical acceleration

04:18

and the same equations apply to both direction but we'll rewrite them

04:22

separately to make sure we don't confuse our X for our Y what are those equations

04:27

we thought you never asked these might look pretty familiar we've seen them in

04:32

previous lessons let's look at a simple one first we want to find the change in [writing on chalk board]

04:37

displacement along the x axis to do that we'll subtract the initial displacement

04:41

from the final displacement another way to find that displacement is if we have

04:45

the velocity and the time in that case the change in displacement equals the

04:49

velocity in the direction of the x axis that's why we have the V sub X here

04:54

times the change in time if I'm looking to find the same thing in the y axis

04:58

we'll just change all the X's in two y's like this if we're trying to find

05:02

displacement but we have to deal with acceleration then do we have an equation

05:06

for u in that case the change in displacement along the x axis equals the

05:11

initial velocity along the x axis which is what V sub X I stands for times time

05:17

plus one-half of the acceleration along the x axis times the square of the

05:21

elapsed time it just trips off the tongue doesn't it and again when we're

05:26

dealing with vertical motion which is going to substitute Y for every X even

05:30

the subscripts okay one last equation to look at and if all these B's and x's and

05:36

T's have your head spinning feel free to take a second to clear your head but [student with equations dancing around their head]

05:40

we're going to be using these equations like crazy in this unit so as you

05:44

Americans love to say that go up okay so this is what we'll use to find the final

05:50

velocity along which have access if we don't have info on how much time elapsed [writing on chalk board]

05:54

but we do have info on final velocity displacement and acceleration so the

06:00

square of the final velocity along the y axis yes that's right when mixing it up

06:05

on you leading with the Y motion this time equals the square of the initial

06:10

velocity along the y axis plus two times the acceleration along the x axis times

06:16

the change in displacement and this is what it looked like for the

06:20

x-axis rather than the y-axis it just looks X yeah and it's important

06:25

to recognize that we can never ever ever put X's and Y's in the same equation the

06:31

dimensions have to be kept separate which sounds like something from a

06:35

monster movie but this would result in something worse than an interdimensional [t-rex chasing X and Y]

06:40

monster it would result in the wrong answer that's really scary so let's put

06:46

these equations to work shall we and we'll start with something we'll are too

06:50

familiar with falling down anything that's in freefall experiences

06:55

acceleration in one direction straight down that's gravity for you and that

06:59

doesn't matter if we take a wrong turn and drive off a cliff or if Steph Curry

07:03

takes a half-court buzzer-beater in either case we have velocity along

07:07

the x axis but the only acceleration will be along the y axis with no

07:12

acceleration that horizontal speed will stay the same forever well not forever

07:17

forever but car will be coming to a sudden stop before too long this type of

07:23

motion with acceleration in the Y direction and the constant motion in the

07:26

X Direction is called projectile motion and when we have a projectile motion we [graph on screen]

07:32

get to assume acceleration along the x axis is 0 meters per second squared and

07:36

the acceleration along the y axis is negative 9.8 meters per second squared

07:42

when we have a projectile motion we're able to get rid of some of those [writing on chalk board]

07:46

equations we looked at before we had six equations three of each for x and y but

07:51

since we don't have any acceleration along the x axis we only need one

07:55

equation for that motion we'll need the one for the change in

07:58

displacement along VX which will either be the final displacement minus the

08:02

initial displacement all the velocity times the change in time since we do

08:07

have the acceleration in the Y direction we'll have a couple of equations that we

08:10

can use for that motion first we have this one where we'll use the velocity

08:15

the acceleration of gravity and and if we don't have the elapsed time we

08:19

can use this one that certainly cleans things up for us

08:22

if we have constant acceleration in one direction and constant motion in the [basketball game]

08:26

other we end up with a parabola just like that sweet Steph Curry jump shot

08:31

hmm we can see that represented here here

08:35

each basketball represents an equal interval of time we can see that the

08:39

speed is much faster at each end of the graph and slower at the top here let's

08:44

add some arrows to make that clearer see how all the horizontal arrows are the

08:49

same length that's that constant motion we keep

08:51

yapping about and the vertical arrows those are the same length or magnitude

08:55

at each position along the y axis it's just the directions that change going up

09:00

for the first half and down for the second half it's like the first half has

09:04

an evil twin in the second half of the jump shot so this is a graph of the

09:08

motion combining the x and y motions but we still have time that's binding them

09:12

together what would the graph for the motion in the X direction looked like in

09:16

terms of time funny you should ask we just so happen to have the graph

09:19

right here see that nice straight line that's constant velocity if we ever saw [graph on screen]

09:25

it just like we'd expect when using this equation and for the Y motion in terms

09:30

of time boom another parabola it's like poetry in motion or poetry in a motion

09:36

equation we're not going to lie two-dimensional motion is more

09:40

complicated than one-dimensional but as long as we keep x and y separate we

09:44

should be able to handle it just fine after all it's just a matter of applying

09:48

the right equations to the right direction and we've worked with these

09:52

equations before so we know we're up to the task

09:55

let's just be thankful there's no such thing as

09:58

dimension

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