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Physics: More Fun with Vector Components 11 Views


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Time to have more fun with vector components! What's that? You've never had any fun with vector components? Huh...then...time to spend more time with vector components!

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Transcript

00:02

Putting it all together: more fun with vector components we say fun with

00:08

vector component that's like fun....

00:20

all right story time yeah I'll do that

00:26

okay time to take a break from vectors and hit the slopes just glide down a [Man skiing on the slopes]

00:31

mountain letting gravity do all the work moving horizontally and vertically in a

00:35

diagonal direction, uh-oh sounds like a two-dimensional vector doesn't it make

00:40

sense skiing is a lot like that experiment Galileo did the one where he [Galileo skiing down a mountain]

00:45

discovered the force of gravity by rolling a ball down a ramp a bunch of

00:48

times except with skiing we don't have some old Italian guy timing us with a

00:52

water clock and like we said gravity will be the force that's sending us

00:56

downhill sadly our jet-powered skis haven't been [Man with jet-powered skis appears]

00:59

delivering us yet so there won't be any horizontal acceleration just vertical

01:03

however because we'll be going down on an incline aren't we're all velocity

01:08

magnitude will be increasing but hold on we're really awesome at skiing so we'd [Man performs ski jump]

01:14

be doing all sorts of radical jumps and stuff right and it would throw off all

01:18

the math so instead we'll be observing the motion of our buddy Rex

01:23

Tyrannosaurus Rex yeah he's a newbie to this winter wonderland so he'll just [T-Rex skiing down mountain]

01:27

hope to stay upright.... so let's say t-rex is going down a mountainside and

01:36

for the sake of simplicity we'll say this is a completely frictionless

01:40

ice-covered hill and we'll put the hill in an angle of 40 degrees you know what

01:45

Rex's speed went from 200 meters from the ski lift, first things first we

01:50

know the total distance along this diagonal yeah Rex just keep skiing

01:56

and we know the angle of incline well do we have enough to calculate the velocity

02:03

well the best equation to use would be this one it tells us that the square of [Equation of velocity appears]

02:07

the final velocity equals the square of the initial velocity plus two times the

02:12

acceleration times the distance well the initial velocity will be zero and the

02:17

distance will be 200 meters but we don't have the acceleration let's take care of

02:22

that problem right now as the Italian stallion

02:26

Galileo himself taught us acceleration down an incline equals the force of [Galileo appears galloping on a horse]

02:31

gravity times the sine of the angle of inclination well the acceleration of

02:37

gravity is 9.8 meters per second squared just like always when we multiply that

02:42

times the sine of 40 degrees we get an acceleration of six point three meters

02:45

per second squared which is a lot of acceleration for a nine-ton reptile okay

02:51

now we can use that velocity equation we looked at before since the initial

02:55

velocity is zero the square of the final velocity equals two times the

02:59

acceleration times the distance well doing that math gives us two thousand

03:03

five hundred twenty meters per second ah but we need to find the square root of

03:06

that number to be able to find the final velocity while taking the square root

03:11

gives us a final velocity of fifty point two meters per second but there might be

03:15

a little problem remember when we said Rex was new to this whole skiing thing [People skiing and T-Rex appears]

03:20

and that he's super big yeah he's not gonna be stopping anytime soon in fact

03:25

it looks like he's gonna go over the edge of the mountain which would be [T-Rex falls off edge of mountain]

03:28

about 12 meter fall before he hits the ground below so what's the speed at the

03:33

bottom of this tumble well in this case the initial velocity is definitely not

03:37

zero after all we just figured out that our big friend was going fifty point two

03:41

meters per second and since this is a vector quantity it needs a direction as

03:46

well that direction was 40 degrees but we need to break that velocity down into

03:50

its vertical and horizontal components and yep we're getting triggy with it all

03:54

right so if we put this on a graph we can see that we have a right triangle

03:57

here and the velocity that we calculated is the hypotenuse of that triangle [Triangle appears on graph]

04:02

hypotenuse that thing right there since we know the incline angle we can use

04:06

trig functions to find out the magnitude of the component velocities which make

04:11

up the other sides of this triangle, time for for sohcahtoa

04:15

...... it's not an island in the South

04:21

Pacific it's how we remember our primary trig functions well the soh when

04:26

sohcahtoa reminds us that the sine of an angle equals its opposite side divided

04:31

by the hypotenuse so the sine of 40 degrees equals v sub y over 50 point two

04:36

meters per second when we multiply each side by fifty point two meters per

04:40

second we find that the vertical velocity v sub y equals 32.3

04:45

meters per second all right now for the horizontal velocity that makes up the [Triangle appears with horizontal velocity]

04:50

adjacent side of our triangle which means we need to use the cah in

04:54

sohcahtoa the cosine of an angle equals its adjacent side over the hypotenuse so

05:00

once again we multiply both sides of the equation by the hypotenuse to solve for

05:04

v sub x well that math we're doing here tells us that the horizontal velocity is

05:10

38.5 meters per second okay we're making progress on this velocity stuff and

05:15

Rex is making progress getting himself upright yeah [Rex attempts to stand up from ditch]

05:20

those little arms aren't helping though all right now we can find the vertical

05:23

velocity that Rex achieved right before he hit the ground to do that we'll use

05:27

this equation again well this time we do have an initial velocity it's a thirty

05:32

two point three meters per second we just figured out a minute ago and the

05:36

acceleration will just be our good old 9.8 meters per second squared buddy

05:41

there aka gravity, oh in the displacement well that'd be the twelfth meter plummet

05:47

we plug in those numbers don't forget to find that square root and we get a final

05:52

velocity of thirty five point eight meters per second and that's it all done

05:56

we just need some hot cocoa and a paleontologist make sure Rex didn't break [Man with skis appears at lodge]

06:00

any bones but oh wait there's one more things there always is we have our final

06:06

vertical velocity and the horizontal velocity stayed the same

06:09

until the Dino met the ground yeah but we need to figure out the combined

06:15

velocity to get our actual final vector and we can do that with the Pythagorean

06:20

theorem Pythagorean theorem that was

06:23

Pythagoras' best theorem by far for this triangle v sub x squared plus v sub

06:28

y squared will equal the square of the combined velocity so when we add the [Equations appear]

06:34

squares and find that square root we get a final velocity 52.6 meters per second

06:39

so Rex didn't pick up a ton of speed on his way down but it was only a 12 meter

06:43

fall so not a big deal when we have a problem where the motion changes we need

06:48

to be sure to break those motions into separate chunks then we just need to

06:53

make sure we're using the right equation and that we're keeping track of any [Rex skiing down a slope]

06:56

changes in the vector components like when Rex went off that cliff

07:00

we had to factor in the vertical velocity he started with when he began

07:04

as freefall to get the right combined velocity so make sure to take things

07:08

step by step and pay attention to anything that needs to be carried over

07:11

from the previous step all right let's go back to the lodge hope they have [man with skis appears at the lodge]

07:15

those little marshmallows for the cocoa but Rex is still having a hard time

07:19

trying to deal with all his you know equipment well looks like he's got his

07:23

helmet balanced on top of one of his skis and he's trying to take those

07:26

boots off at the same time if that ski tips so that one end is 60 centimeters

07:31

lower than the other and the ski is 2 meters long well what are the final

07:35

velocity x and y-components for the helmet when it slides down and off the

07:39

ski ok oh this looks pretty familiar we just need to find the acceleration, well

07:44

acceleration equals gravity times the sine of the theta angle but we don't

07:48

know the degrees of that angle so more thinking, like we said before the sine of

07:53

an angle equals its opposite over the hypotenuse when we have the length of

07:58

the opposite side which is 60 centimeters and we have the hypotenuse

08:01

which is 2 meters well to find the angle it's almost like we need to work

08:05

backwards actually it's exactly like we need to work backwards like every trig [Rex skiing backwards]

08:09

function has an inverse function so if the sine of x equals y the inverse sine

08:16

of y equals x the inverse functions can look like this with a cute little

08:20

negative 1 in superscript like that or you can add arc to the beginning of the

08:25

function so the inverse of tangent is arctangent in the inverse of cosine is [inverse tangents appear]

08:30

arc cosine and the inverse of sine is arc sine so let's make sure our

08:34

calculator is set to use the inverse functions and that it's in degree mode [Rex using calculator]

08:39

and let's put in those numbers all right the arc sine of 60 meters which we'll

08:43

put in terms of meters over 2 meters equals 17 point five degrees now if you

08:49

use that number to find the helmets acceleration as it slides down the ski [helmet slides down the ski]

08:52

just isn't Rex's day so we'll go back to our acceleration equation acceleration

08:58

equals gravity 9.8 meters per second squared times the sine of the theta

09:02

angle which is 17.5 degrees okay so the helmet is picking up speed at a rate of

09:07

2.94 meters per second too fast for a dinosaurs slow

09:11

reflexes especially in the cold but remember we're trying to figure out the [Helmet hits man on the head]

09:15

final component velocities here but to do that we need to find the combined

09:20

velocity first we'll use this equation again and the initial velocity will be

09:25

zero so we just need to calculate 2 times the acceleration times the 2 meter

09:30

distance, O and find the square root so our combined final velocity is 3.4 [Combined final velocity equation appears]

09:36

meters per second and that's it okay now we're in the homestretch we

09:41

just need to break that vector down to its components it's important to

09:44

recognize that earlier when we were figuring out the degrees of the incline we

09:48

were working with lengths we weren't using velocity vectors just plain old

09:52

scalar lengths so even though the triangle looks the same we're working on

09:56

a whole new level well to find the component velocities we

10:00

just need a little bit more trig and then we're done to find the horizontal

10:03

vector we'll multiply our combined velocity times the cosine of the

10:07

17.5 degree angle making the velocity in the x-direction

10:13

3.27 meters per second and the vertical well, same basic idea except

10:19

we'll be using the sine instead of the cosine which gives us a vertical

10:23

velocity of 1.03 meters per second and yeah that makes sense since the [Skis propped up against a tree]

10:28

angle isn't very steep most of the velocity is along the horizontal axis

10:33

that's why the horizontal side of our triangle is a lot longer than the

10:37

vertical these lines represent the magnitude of these vectors see all that [Boy and Rex sat at a table]

10:41

works out okay now we're done for reals this time turns out all this ski stuff

10:46

was just an excuse to do more math, in reality were terrible at skiing we do

10:51

have a t-rex friend though....[Rex eats boy]

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