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Hello there, I'm Mr. Forbes and welcome to this lesson from the measuring and calculating motion Unit.

In it we're gonna be looking at calculations from motion graphs, and that involves using the graphs to find things like final displacement, distance travelled, speed, and acceleration.

By the end of this lesson you're gonna have looked at a wide range of motion graphs and be able to take readings from those graphs to calculate things like distance, displacement, speed, velocity, and acceleration.

You'll also be able to convert from one graph to the other through a series of calculations.

Here are the key words that will help you understand the lesson.

First off is the displacement-time graph.

And that's a type of graph that shows the displacement of an object over a period of time, where displacement is how far it is from its starting position.

There's also velocity-time graph, which shows the velocity of the object over the period of time.

Then there's velocity, and velocity is the rate of change of displacement, how fast the displacement is changing.

And finally, acceleration.

And the acceleration of an object is the rate of change of velocity, how much the velocity is changing each second.

And here's some explanations of those keywords that you can return to at any point in the lesson if you need some help.

In the first part of the lesson we're going to be comparing the two types of motion graph, velocity-time graphs and displacement-time graphs, and we'll see what type of information we can get from both.

In the second part of the lesson, we're going to be looking at one graph and trying to convert information we can obtain from it into the other type of graph.

So we'll take a velocity-time graph and use it to make a displacement-time graph, or a displacement-time graph and use that to make a velocity-time graph.

And in the third part of the lesson we can define information from both types of graphs and use that in a variety of calculations.

So when you're ready, we'll begin by looking at the two types of motion graph.

Displacement-time graphs and velocity-time graphs both look very similar and give us similar types of information, but they're not identical, they're very different in important ways.

So I've got a displacement-time graph and a velocity-time graph here.

And I'm gonna show you the movement of the same object on both graphs at the same time.

So in the first stage of movement here, I've got a displacement increasing at irregular amounts, and that indicates a constant velocity.

So if you look at the velocity-time graph, I've got a constant level of velocity there.

Then I've got this secondary displacement graph where the displacement doesn't change, and that means the velocity is zero.

And as you can see on the velocity-time graph, I've made the line go down to zero.

Then I'm gonna increase the velocity again, but this time it's a small velocity, and as you can see on the displacement-time graph, the line goes up again, but this time the gradient of the slope is lower.

So both graphs show information about movement but in different ways.

As you saw in those example graphs, the lines, even though they're representing the same movement, don't match each other on the graphs.

If I've got a displacement-time graph that's got a line like this, this indicates that there's a constant velocity.

This object is moving forward at a constant rate.

And that on the velocity-time graph would be represented by a line like this.

The velocity is remaining constant at a steady amount and it's producing a gradual increase in displacement giving us that straight line.

Now, objects aren't always moving, and the displacement can stay at a constant value.

So if I've got a displacement here where the objects not changing displacement over the period of time, well, that must indicate that the object's not moving, it's got zero velocity.

So on a velocity-time graph, I'd have a velocity remaining constant at zero.

On those two earlier graphs, we had constant velocities.

But velocity's not always constant, objects can accelerate.

So we can have an object like this, where we've got an increase in velocity, showing that the object is accelerating in a regular way.

And that's gonna cause a change in displacement that's going to be greater for every second that passes.

So on a displacement-time graph, I wouldn't get a straight line at all, I'd get a curve like this.

And as you can see in the first part of the movement, I've got a very shallow gradient and later on the object moving much faster and I've got a much steeper gradient.

So increasing velocity produces curves on displacement-time graphs.

Objects can also decelerate, so that would mean that the velocity is decreasing over time.

So on a velocity-time graph, that could be represented with something like this, a decrease in velocity means the change in displacement every second is gonna get smaller and smaller.

So I'd end up with a displacement-time graph something like this.

As you can see at the start, the displacement's increasing quickly and towards the end of the graph, later on in time, the displacement's flattening out, the gradient is much shallower.

So a decreasing velocity will gimme a curve in that direction.

Okay, let's check if you understood the relationship between these shapes on both types of graph.

I've got a set of movement graphs here, three displacement-time graphs and three velocity-time graphs, and each of them match up.

So each displacement-time graph has got a matching velocity-time graph, and what I'd like you to do is to match up those pairs.

So pause the video, match up the three sets of pairs, and then restart, please.

Welcome back.

The first pair we can match up is A and F.

This has got a decrease in velocity, so the displacement is a curve that flattens out.

The second pair we can match is B and D.

And in this one I've got a constant velocity, and therefore a constant gradient on my displacement-time graph.

And that leaves the third pair as C and E, where the displacement is increasing at a greater rate because the velocity is increasing.

Well done if you got those three.

So far we've just looked at simple sections of a graph where we've got just one phase of motion.

But graphs can show multiple phases of motion.

So we can have a displacement-time graph like this where I've got a steadily increasing displacement, and then displacement stops increasing over time.

So we get two phases there.

And that would match a velocity-time graph something like this.

So in the first part of the motion we've got a constant velocity, and that represents a slope on the displacement-time graph and a flat section of a velocity-time graph.

And then we've got the velocity falling to zero because the displacement no longer increases.

Now graphs can show gradual changes in motion as well.

So I'm going to try and plot a displacement-time graph that shows a constant velocity and then gradually slow into a stop instead of suddenly stopping, and a velocity-time graph that matches it.

So here's the first section.

We've got some constant velocity, which results in that time slope on the displacement-time graph.

And then I've got a gradual slowing here.

So that's represented by a curve on the displacement-time graph and a straight line on the velocity-time graph as the velocity gradually falls to zero.

And then when it reaches zero, I'll put that final section of the velocity-time graph in, and that gives me a displacement that doesn't change.

So I've got that final section on the displacement-time graph.

So I've got a complete picture of an object that's moving at steady speed, gradually slowing down to a stop.

Okay, it's time for you to try and interpret a graph that's got several phases of motion.

So I'd like you to decide which of the lines A, B, C, and D on the displacement-time graph, which is on the right there, matches the motion shown on the velocity-time graph, which is on the left? So pause the video, have a think about that, and then restart when you've made your selection.

Welcome back.

And the correct answer to that was answer B.

Well done if you selected that.

We've got a velocity that's constant, so that gives us a straight gradient upwards at first.

Then we've got a velocity that decreases.

So on the displacement-time graph we're gonna get a curved section.

And then in the final bit we've got another constant velocity, so we're looking for another straight section of the graph, but this time a shallower gradient, 'cause the velocity is less.

So well done if you selected B.

And now let's check if you can convert the graphs the other way.

So which line on the velocity-time graph matches the motion shown on the displacement-time graph? You can see there's a displacement-time graph there on the left and I've got four different lines on the right.

I'd just like you to decide which of those four lines on the right velocity-time graph matches that displacement-time graph.

So pause the video, make your selection, and restart, please.

Okay, welcome back.

And the correct answer to that was D.

Well done if you selected that.

We can see from the displacement-time graph, in the first part of the motion I've got a steadily increasing displacement, and that indicates a constant velocity.

Then I've got a curved section of the graph, and that indicates that the velocity is decreasing.

And then I've got a section of the graph where the displacement remains the same, so a zero velocity.

And the only line that matches that was line D.

Well done if you selected that.

So far we've only looked at graphs that have got positive velocity, but there are plenty of situations where we can have negative velocity on object moving backwards.

So we're gonna look at what that would produce on a displacement-time graph here.

So I've got a velocity-time graph and a matching displacement-time graph.

And we'll look at each section of the motion and try and explain it.

So in the first section of the motion, I've got a positive velocity of two, and that's gonna cause an increase in displacement, it's gonna increase by the same amount every second.

So I'm gonna get a straight line section of the graph sloping upwards like this.

And the next part of the graph, in this part I'm going to be decelerating towards zero velocity.

So that's going to change the gradient on my displacement-time graph.

It's gonna get gradually flatter and flatter.

So as you can see, it curves until we've got the sort of peak of the graph there.

In the next section of the motion I've got accelerating backwards.

I've got a velocity that's increasing or becoming more negative, I should say, and that's going to cause another curved section of the graph.

But this time it's curving in the other direction.

And in the final section I've got a constant negative velocity, so that's gonna give me a straight slope downwards.

So we've got four sections of motion there where the object is going forwards, then slowing down, and then starting to accelerate backwards, and then finally moving backwards.

Let's see if you understood my description involving positive and negative velocity.

I've got a graph here of a drone, and it's got positive and negative velocities.

I'd like to think carefully and decide at what time would the displacement of that drone be its maximum value? So pause the video, get your selection from those on the left there, and then restart, please.

Welcome back.

You should have chosen T = 40 seconds, because at that point the velocity is just about to become negative, so the drone's going to start moving backwards at 40 seconds.

That means that the displacement's gonna start to decrease at that point.

So well done if you spotted that.

It's time for a more challenging question about velocity-time and displacement-time graphs.

So this one involves negative velocities.

What I'd like you to do is to look carefully at the two lines on the velocity-time graph, labelled A and B, and select the two lines on the displacement-time graph that match that motion.

So pause the video, make your selections, and restart, please.

Okay, welcome back.

And you should have noted that A matches line E.

So if you look carefully at line A, we've got a gradual increase in velocity.

So what we'd be expecting is a curve upwards on the displacement-time graph, and that is line E.

For line B, that matches line C on the other graph.

You can see there's going to be an increase in displacement on the velocity is positive, and then the displacement's going to start decreasing when the velocity is negative.

Well done if you spotted those two.

And now it's time for the first task of the lesson, and what I'd like you to do is use everything you've learned so far to sketch a pair of graphs for me.

So I'd like you to sketch a velocity-time graph that matches the motion shown on the displacement-time graph on the left there.

And I'd like you to sketch a displacement-time graph that matches the motion shown on the velocity-time graph on the right there.

Now there's no numbers on the graphs, I just want the general shapes.

So pause the video, sketch your graphs, and then restart, please.

And welcome back.

The velocity-time graph you should have sketched for part one should look something like this.

We've got a constant forwards velocity at first, so constant positive velocity and that gives us that upward straight slope.

Then we've got a velocity of zero, because you can see the displacement doesn't change, so the object's not moving, it's got a velocity of zero.

And then we gradually curve upwards, and that means a gradual increase in velocity.

That gives us that upwards diagonal line on the velocity-time graph.

Well done if you sketched something that shape.

And here's the solution to the second part of that, your graph should look something like this.

At first we've got a high constant velocity, so we get a straight line going up like that on the displacement-time graph.

Then we have a decreasing velocity.

So that's a curved section on the displacement-time graph.

And finally we've got a constant lower velocity.

So well done if your graph looks something like this.

So let's move on to the second part of the lesson now, and in it we're going to be converting from one motion graph to another.

So we'll be reading information from one type of graph, a displacement-time graph, and then using that to construct a velocity-time graph, or the other way around.

So we're gonna be making those conversions from one graph type to another, and we need to follow a fairly standard procedure to do that that involves reading data from the first graph, and then we use that data in the speed or the velocity equations.

And finally, from the results of those equations we can plot the results on the second graph.

So let's start by looking at a few example graphs to see if we can do that.

So far we've sketched the graphs to get the general shape, but now we're going to try and take readings from one graph in order to plot the other.

So I'm going to take readings from a velocity-time graph and plot an accurate displacement-time graph for that motion.

So here's my velocity-time graph, and I've got three phases of motion here, I've got a constant velocity of 1.

5 metres per second, then stopped, and then a constant velocity of two metres per second.

So what I do is I break the motion down into phases, and the first phase here I'm going to calculate the total change in distance or the increase in displacement.

And I can do that using the speed equation.

So I've got a velocity of 1.

5 metres per second, and the object moves for two seconds, that gives me an increase in displacement of three metres.

And I can then plot that on my displacement-time graph, I've got a constant velocity, so I'm drawing a straight line, and it's got to go to three metres after two seconds.

So it gives me that red line section there.

Then I look at the motion between two and five seconds on the velocity-time graph, this section of motion here, and the velocity is zero, so there's gonna be no increase in displacement during two to five seconds.

So in this section of the graph I can just draw a straight line like this.

And finally, in the third section of the graph, I've got a velocity of two metres per second and a change in time from five to eight seconds.

So I can calculate the increase in displacement there.

And it's important to note it's the increase in displacement, which is six metres.

So my displacement's got to go up by another six metres in those final three seconds.

So I need to increase my displacement from three metres to nine metres to accommodate that.

And I've successfully converted a velocity-time graph to a displacement-time graph.

Okay, let's see if you can match up a velocity-time graph to the displacement-time graph that should be produced.

So which line on the displacement-time graph, which is the graph on the right, shows the same motion as the velocity-time graph on the left there? So pause the video, make your selection, and restart, please.

Okay, welcome back.

The answer you should have selected was line C.

So if you look carefully, the velocity is at one metre per second there.

So after two seconds, the object should have moved two metres.

Then the velocity increases to two metres per second.

So the gradient would increase on my displacement-time graph and I end up with a total distance after four seconds of six metres, and that indicates that the red line is the correct one.

Well done if you selected that.

We've looked at just positive velocities so far, so let's have a look at a case where there's some negative velocities as well.

So I've got a graph here of motion and I've got positive velocity for the first three seconds, then the velocity goes negative, and then it goes back to positive again.

So we'll look at each phase of that motion.

So in this first section and of the graph I've got a velocity of + three metres per second, and that will mean after three seconds I'll have travelled nine metres.

So that would give me the line there shown in red on the displacement-time graph.

In the second phase of motion here I've got a negative velocity, so the displacement's going to decrease by two metres every second.

So I get a line like this showing a velocity of - two metres per second, so my displacement will decrease by two metres every second though.

And in the third section of motion, again, I've got positive velocity again.

So my displacement's going to increase by one metre per second here, and that'll give me the final line like this, + one metres per second.

So you can see how to convert from a velocity-time graph to a displacement-time graph, and the velocity is positive and negative.

So a fairly challenging question here now.

I'd like you to decide which line on the displacement-time graph below shows the same motion as the velocity-time graph.

So pause the video, make your selection, and then restart, please.

Welcome back.

You should have selected line B, the dotted black line there.

And as you can see in the velocity-time graph, during the first two seconds, the velocity is three metres per second.

So I should see the displacement increase by three metres every second.

So after two seconds, the displacement would be six metres.

And that shows me that the black dotted line was the correct one.

Well done if you selected that.

So, so far we've converted velocity-time graphs into displacement-time graphs.

Now we're going to try and do that the other way around, a displacement-time graph into a velocity-time graph.

We follow a very similar procedure.

So we break each part of the motion down and then calculate the velocity for each part.

So I'm gonna look at my displacement-time graph here and break it into the three sections, and find the velocity for each section.

So in the first section here, I've got a change in displacement of six metres and a time difference of two seconds, and I can calculate the velocity as three metres per second.

So what I need to do then is translate that, put it onto the other graph, and draw a constant velocity of three metres per second at that green line there.

The second part of the motion, well, I've got no change in displacement, that tells me that I've got a velocity of zero metres per second, so I can quite simply draw that on the graph here, straight down to zero metres per second, and a line across for those two seconds there.

And in the third part motion, again, I find the change in displacement, and the change in displacement is four metres.

The displacement's gone up by four metres there, and the change in time is four seconds.

So I can find a velocity of one metre per second there, and I can plot that on the graph in the last section here.

And now I've successfully converted a displacement-time graph into a velocity-time graph.

Let's see if you can match up a displacement-time graph and a velocity-time graph.

So which line on the displacement-time graph shows the same motion as the velocity-time graph, which is on the right there? So pause the video, make your selection, and restart, please.

Welcome back.

You should have selected line A there.

So in the first part of the motion, the first two seconds, I've got a velocity of one metre per second.

So you would expect the displacement to be two metres after two seconds, which the blue line has.

Then you've got a velocity of zero for another two seconds.

So you should have a flat partner blue dash line, and you do.

And then we've got another increase in velocity to three metres per second.

And finally, the final section of the line between six and eight seconds, we've got no increase in displacement.

So that was the blue dash line.

Well done if you've got that.

And now it's time for the second task of the lesson.

And what I'd like you to do is use the techniques I've shown you to draw some accurate graphs.

So I'd like you to draw an accurate displacement-time graph using the information shown on the velocity-time graph there in red.

And then I'd like you to draw an accurate velocity-time graph using the information from the displacement-time graph, which is shown in the greeny-blue there on the right.

So pause the video, draw your two graphs accurately, and then restart, please.

Welcome back.

And for the first graph you should have drawn something like this.

We've got zero velocity for the first second, so there's no change in displacement.

Then we're moving at one metres per second for two seconds, so we should get up to two metres after that three second mark.

Then we've got a velocity of three metres per second, so that steeper line there.

And finally, back down to a velocity of 0.

5 metres per second for the end two section.

Well done if you've got that.

And for the second part of the task, you were asked to draw a velocity-time graph, and you should have come up with a velocity-time graph that looks like this.

Well done if you've got that.

And now it's time to move on to the final part of the lesson where we're going to be finding information from different motion graphs.

So we're gonna read values from the graphs and use them in different calculations to find things like distance travelled, velocity, and acceleration.

We have a displacement-time graph where the motion is only in one direction, where the direction of travel doesn't change.

It's quite simple to find total distance travelled.

So if I've got a graph like this, and as you can see I've got changes in velocity there, but I've not got a change in direction, I've got no decrease in displacement.

I can just read off the total distance travelled.

It's the same as the final displacement like this.

So the distance travel there would be 10 metres.

This graph, the distance travel would be 60 kilometres.

So as long as the direction of travel doesn't change, the displacement and the total distance travelled are the same.

In a lot of motion we've got direction of travel changing.

But as long as the direction of travel is just along a straight line, so north to south, or east to west, or something like that, the distance travel can still be found by just adding the separate phases of motion together.

So I've got a displacement-time graph here.

We've got displacement, kilometres, and timing, hours, and as you can see the displacement goes up, and then down, and then up again.

So I've got changes of direction here.

And so to find the total distance travelled, what I have to do is add up all of the changes in displacement.

So I've got an increase in displacement of 60 kilometres there, and then I travel backwards 40 kilometres, and then forwards again 30 kilometres.

And I can find the total distance travelled just by adding those three together.

So the distance travelled is those three values, and that gives a total distance travelled of 130 kilometres.

Let's see if you can find the total distance travelled for an object that's moving in two directions.

So I've got a graph showing the displacement and time for an elevator here.

As you can see, it goes upwards and downwards.

So what I'd like you to do is find the total distance travelled from its journey where it starts at 50 metres, to the ground, which is at displacement of zero.

So pause the video, make your selection from the list on the left, and then restart, please.

Welcome back.

You should have selected 130 metres.

In the first part of the motion, the elevator goes down 20 metres and the second part of the motion it goes back up 40 metres.

So we've already got 60 metres there, and then down from its maximum height of 70 to the ground, so 70 metres down.

And if we add those three values together, we get a total distance of 130 metres.

Well done if you've got that.

The distance travelled for any velocity-time graph can be calculated from the area beneath the line.

And you may have seen that in a previous lesson.

So if we wanted to calculate the distance travelled between 10 and 30 seconds on this graph, what we could do is break down that part of the motion into two simple areas that we can calculate, and then we can calculate those two areas, got area A, it's 20 seconds by 3 metres per second, that gives us 60.

Area B, that's a triangle, so we've gotta remember, 1/2 base x height, or 1/2 x 5, which is the difference in velocity there between 3 and 8, x 20 seconds, and we get those two areas.

And if we add those two areas together, we get the total distance travelled between 10 and 30 seconds, which is 80 metres.

Okay, I'd like you to use the same technique to calculate the total distance travelled between naught seconds and 30 seconds on this graph.

So you can ignore the rest of the graph, just concentrate on that first section between naught and 30 seconds.

So pause the video, get your selection from the list on the left there, and then restart.

And welcome back.

You should have selected 180 metres.

If we break down that section into two areas, a triangle and a rectangle, you can see area A, the rectangle, that's 4 high x 30 across, that's 120.

And the area of the triangular bit, and that again is four high, from four to eight, and 30 across, but it's 1/2 base x height.

So that gives us an area of just 60.

Adding those two together gives 180, so it's 180 metres.

Well done if you got that.

When there's a constant acceleration acting on an object, then we can find the acceleration from a velocity-time graph using the change in velocity and the change in time.

So I've got a velocity-time graph here, and the object is accelerating between two and four seconds.

You can see the velocity is increasing there.

So we can find acceleration using the acceleration equation that you may have seen before.

Acceleration is change in velocity, divided by change in time.

And in symbols, you might have seen it like this.

A = V - U over T, where V is the final velocity, and U is the initial velocity, and T is the time.

So if we look at this section of the graph where the acceleration's happening, we can read off some values and put those into the equation.

The acceleration is five metres per second minus two metres per second, or V was five metres per second, U two metres per second.

And T, the change in time, well, that's four seconds to two seconds.

So we take away two seconds from that four seconds, we carry out the calculation, and that gives us an answer for the acceleration of 1.

5 metres per second squared.

Okay, I'd like you to find out an acceleration for itself.

Now I've got a velocity-time graph here, and as you can see there's acceleration going on between one and four seconds.

So I'd like you to find the acceleration between one second and four second for the journey shown.

So pause the video, calculate the acceleration, and then restart, please.

Welcome back.

You should have selected C for that 1.

33 metres per second squared.

And if we read the values for this section of the graph, the part where it's accelerating as asked, we can substitute the values we read off the graph into the equation just like that.

And that gives us a final answer of 1.

33 metres per second squared.

Well done if you got that.

Acceleration isn't always a constant value, and we can see that by a change in gradient on a velocity-time graph.

So if I've got an object that's got a changing acceleration, I'll end up with a curve on a velocity-time graph like this, and that one there has got the lowest acceleration, because the curve isn't changing much, it's gradually increasing.

If I've got a slightly higher acceleration, then I'm going to have a curve that becomes more steep, more rapidly.

So that dotted black line there would be medium acceleration.

And as you'd expect, if I've got a higher acceleration, again, I'm going to get a curve that becomes steeper much more rapidly like that.

Let's see if you can identify the greatest deceleration here.

I've got an object that was moving at six metres per second, but which of those lines shows the object that is the greatest deceleration? Pause the video, make your selection from the lines below, and then restart, please.

Welcome back.

You should selected D, that becoming steepest more quickly.

The object is reaching a velocity of zero more rapidly, only takes four seconds.

So that must have the greatest deceleration.

Well done if you selected that.

And now we're onto the final task of the lesson, and there's five questions in total over these next two slides.

The displacement-time graph below shows the motion of a camera drone, and what I'd like you to do is to look carefully at that graph and find the total distance travelled between naught and eight seconds.

So that's the full length of the graph there.

Then I'd like you to find the greatest speed of the camera drone, identify when that happens, and then work out what that speed is.

Then I'd like you to look at the velocity-time graph here, which shows the motion of a boat.

I'd like you to find the total distance travelled between naught seconds and four seconds there.

So the first half of that graph, really.

Then I'd like you to find the deceleration between two seconds and four seconds, there you can see that downward slope.

And finally, I'd like you to try and describe the motion between five seconds and eight seconds.

So pause the video, while you work through those five questions, and then restart, please.

Welcome back.

Well, the total distance travelled there, it's the sum of those three sections of motion.

And to find the greater speed of the camera drone, we look for the steepest gradient, and that's this section here.

And we find the change in displacement and a change in time, and we can calculate a speed of nine metres per second there.

Or you could have put - nine metres per second.

I didn't ask for the direction, so I don't need the plus or minus in that.

Well done if you've got those two.

The total distance travel between naught seconds and four seconds, that's the sum of these three areas here, and I've have worked out the area of each of those shapes, added 'em together, and got 10 metres.

And the deceleration between two seconds and four seconds, again, I read the values off the graph for initial and final velocity and change in time, and that give me - one metres per second squared.

Well done if you got that.

And the final question here, describe the motion between five seconds and eight seconds.

Well, the toy boat's accelerating, because you can see the velocity is increasing, but you can see it's a curve there.

So it's not uniform acceleration, it's increasing acceleration.

So the rate of acceleration is increasing over time.

Well done if you got that.

Okay, we've reached the end of the lesson now, and here's a summary of everything we've learned.

Motion graphs can show the same information in different ways.

So I've got a displacement-time graph there, and constant velocity is shown by a straight line on that graph, and changing velocity is shown by a curve.

But in the velocity-time graph, constant velocity is shown by a horizontal line and constant acceleration is shown by a straight line.

If we've got constant velocity, we can calculate distance travel using X = V x T, distance travelled is velocity x time.

If we've got uniform acceleration we can find the acceleration using A = V - U over T.

So a final velocity - initial velocity divided by time.

Well done for reaching the end of the lesson.

I'll see you in the next one.