Why distance is area under velocity-time line | Physics | Khan Academy

00:00

Let's say I have something moving

00:02

with a constant velocity of five meters per second.

00:07

And we're just assuming it's moving to the right,

00:10

just to give us a direction, because this is a vector

00:12

quantity, so it's moving in that direction right over there.

00:15

And let me plot its velocity against time.

00:19

So this is my velocity.

00:23

So I'm actually going to only plot

00:25

the magnitude of the velocity, and you

00:26

can specify that like this.

00:29

So this is the magnitude of the velocity.

00:33

And then on this axis I'm going to plot time.

00:39

So we have a constant velocity of five meters per second.

00:43

So its magnitude is five meters per second.

00:49

And it's constant.

00:50

It's not changing.

00:51

As the seconds tick away the velocity does not change.

00:54

So it's just moving five meters per second.

00:58

Now, my question to you is how far does this thing

01:02

travel after five seconds?

01:05

So after five seconds-- so this is one second, two second,

01:08

three seconds, four seconds, five seconds, right over here.

01:12

So how far did this thing travel after five seconds?

01:15

Well, we could think about it two ways.

01:16

One, we know that velocity is equal to displacement over

01:28

change in time.

01:29

And displacement is just change in position

01:32

over change in time.

01:36

Or another way to think about it--

01:38

If you multiply both sides by change

01:39

in time-- you get velocity times change in time,

01:44

is equal to displacement.

01:47

So what was of the displacement over here?

01:50

Well, I know what the velocity is--

01:51

it's five meters per second.

01:55

That's the velocity, let me color-code this.

01:57

That is the velocity.

01:59

And we know what the change in time is, it is five seconds.

02:05

And so you get the seconds cancel out the seconds,

02:07

you get five times five-- 25 meters-- is equal to 25 meters.

02:12

And that's pretty straightforward.

02:13

But the slightly more interesting thing

02:15

is that's exactly the area under this rectangle right over here.

02:23

What I'm going to show you in this video,

02:25

that is in general, if you plot velocity,

02:28

the magnitude of velocity.

02:30

So you could say speed to versus time.

02:32

Or let me just stay with the magnitude

02:33

of the velocity versus time.

02:35

The area under that curve is going

02:38

to be the distance traveled, because, or the displacement.

02:41

Because displacement is just the velocity times

02:44

the change in time.

02:46

So if you just take out a rectangle right over there.

02:48

So let me draw a slightly different one

02:50

where the velocity is changing.

02:52

So let me draw a situation where you have a constant

02:54

acceleration .

02:55

The acceleration over here is going

02:57

to be one meter per second, per second.

03:00

So one meter per second, squared.

03:03

And let me draw the same type of graph,

03:05

although this is going to look a little different now.

03:07

So this is my velocity axis.

03:11

I'll give myself a little bit more space.

03:13

So this is my velocity axis.

03:16

I'm just going to draw the magnitude of the velocity,

03:18

and this right over here is my time axis.

03:22

So this is time.

03:24

And let me mark some stuff off here.

03:25

So one, two, three, four, five, six, seven, eight, nine, ten.

03:31

And one, two, three, four, five, six, seven, eight, nine, ten.

03:37

And the magnitude of velocity is going

03:38

to be measured in meters per second.

03:41

And the time is going to be measured in seconds.

03:50

So my initial velocity, or I could

03:54

say the magnitude of my initial velocity--

03:58

so just my initial speed, you could say,

04:00

this is just a fancy way of saying

04:02

my initial speed is zero.

04:04

So my initial speed is zero.

04:06

So after one second what's going to happen?

04:08

After one second I'm going one meter per second faster.

04:12

So now I'm going one meter per second.

04:13

After two seconds, whats happened?

04:15

Well now I'm going another meter per second faster than that.

04:18

After another second-- if I go forward in time,

04:21

if change in time is one second, then I'm

04:23

going a second faster than that.

04:25

And if you remember the idea of the slope from your algebra one

04:29

class, that's exactly what the acceleration

04:31

is in this diagram right over here.

04:34

The acceleration, we know that acceleration

04:38

is equal to change in velocity over change in time.

04:46

Over here change in time is along the x-axis.

04:49

So this right over here is a change in time.

04:52

And this right over here is a change in velocity.

04:56

When we plot velocity or the magnitude of velocity

04:59

relative to time, the slope of that line is the acceleration.

05:04

And since we're assuming the acceleration is constant,

05:08

we have a constant slope.

05:09

So we have just a line here.

05:10

We don't have a curve.

05:12

Now what I want to do is think about a situation.

05:15

Let's say that we accelerate it one meter per second squared.

05:18

And we do it for-- so the change in time

05:24

is going to be five seconds.

05:27

And my question to you is how far have we traveled?

05:30

Which is a slightly more interesting question

05:32

than what we've been asking so far.

05:34

So we start off with an initial velocity of zero.

05:37

And then for five seconds we accelerate

05:39

it one meter per second squared.

05:42

So one, two, three, four, five.

05:44

So this is where we go.

05:45

This is where we are.

05:46

So after five seconds, we know our velocity.

05:48

Our velocity is now five meters per second.

05:53

But how far have we traveled?

05:56

So we could think about it a little bit visually.

05:58

We could say, look, we could try to draw rectangles over here.

06:02

Maybe right over here, we have the velocity

06:04

of one meter per second.

06:05

So if I say one meter per second times the second,

06:07

that'll give me a little bit of distance.

06:11

And then the next one I have a little bit more of distance,

06:14

calculated the same way.

06:15

I could keep drawing these rectangles here,

06:16

but then you're like, wait, those rectangles are missing,

06:19

because I wasn't for the whole second,

06:21

I wasn't only going one meter per second.

06:22

I kept accelerating.

06:23

So I actually, I should maybe split up the rectangles.

06:27

I could split up the rectangles even more.

06:30

So maybe I go every half second.

06:31

So on this half-second I was going at this velocity.

06:34

And I go that velocity for a half-second.

06:36

Velocity times the time would give me the displacement.

06:39

And I do it for the next half second.

06:41

Same exact idea here.

06:42

Gives me the displacement.

06:44

So on and so forth.

06:46

But I think what you see as you're getting-- is the more

06:49

accurate-- the smaller the rectangles,

06:51

you try to make here, the closer you're going to get to the area

06:55

under this curve.

07:00

And just like the situation here.

07:02

This area under the curve is going

07:06

to be the distance traveled.

07:09

And lucky for us, this is just going to be a triangle,

07:13

and we know how to figure out the area for triangle.

07:16

So the area of a triangle is equal to one half

07:23

times base times height.

07:24

Which hopefully makes sense to you,

07:25

because if you just multiply base times height,

07:27

you get the area for the entire rectangle,

07:29

and the triangle is exactly half of that.

07:31

So the distance traveled in this situation,

07:35

or I should say the displacement,

07:37

just because we want to make sure we're focused on vectors.

07:39

The displacement here is going to be--

07:41

or I should say the magnitude of the displacement,

07:43

maybe, which is the same thing as the distance,

07:45

is going to be one half times the base,

07:49

which is five seconds, times the height,

07:56

which is five meters per second.

07:59

Times five meters.

08:01

Let me do that in another color.

08:03

Five meters per second.

08:07

The seconds cancel out with the seconds.

08:09

And we're left with one half times five times five meters.

08:12

So it's one half times 25, which is equal to 12.5 meters.

08:19

And so there's an interesting thing here, well one,

08:21

there's a couple of interesting things.

08:22

Hopefully you'll realize that if you're plotting velocity

08:25

versus time, the area under the curve,

08:28

given a certain amount of time, tells you

08:30

how far you have traveled.

08:32

The other interesting thing is that the slope of the curve

08:34

tells you your acceleration.

08:36

What's the slope over here?

08:37

Well, It's completely flat.

08:39

And that's because the velocity isn't changing.

08:41

So in this situation, we have a constant acceleration.

08:45

The magnitude of that acceleration is exactly zero.

08:48

Our velocity is not changing.

08:50

Here we have an acceleration of one meter per second squared,

08:53

and that's why the slope of this line right over here is one.

08:57

The other interesting thing, is, if even

08:59

if you have constant acceleration,

09:00

you could still figure out the distance

09:02

by just taking the area under the curve like this.

09:04

We were able to figure out there we

09:06

were able to get 12.5 meters.

09:09

The last thing I want to introduce you to-- actually,

09:11

let me just do it until next video,

09:13

and I'll introduce you to the idea of average velocity.

09:15

Now that we feel comfortable with the idea,

09:17

that the distance you traveled is

09:19

the area under the velocity versus time curve.