Basic question re Motion (1 Viewer)

akkatracker · Jan 28, 2015

Something really basic here (I must be missing the obvious - first day back at school)

I've had to graph two graphs...
One velocity vs time and the other displacement vs time squared.
They are both straight line plots.
Assuming this should the gradients be the same (they were based off the same data) and shouldn't they both result in the acceleration?
The velocity vs time has a gradient of 1.8ms^2 and the displacement vs time has a gradient of 0.9ms^2
Another thing that's throwing me off is that if you rearrange the equation r = ut + 1/2 *at^2 you end up with a/2 = r/t^2
If this is the case the gradient of the displacement vs time graph wouldn't be the acceleration (however meters divided by time squared = ms^2)
Any help would be appreciated.

InteGrand · Jan 28, 2015

akkatracker said:
Something really basic here (I must be missing the obvious - first day back at school)

I've had to graph two graphs...
One velocity vs time and the other displacement vs time squared.
They are both straight line plots.
Assuming this should the gradients be the same (they were based off the same data) and shouldn't they both result in the acceleration?
The velocity vs time has a gradient of 1.8ms^2 and the displacement vs time has a gradient of 0.9ms^2
Another thing that's throwing me off is that if you rearrange the equation r = ut + 1/2 *at^2 you end up with a/2 = r/t^2
If this is the case the gradient of the displacement vs time graph wouldn't be the acceleration (however meters divided by time squared = ms^2)
Any help would be appreciated.

If $s = \frac{1}{2}a t^2$ (no idea why the HSC Physics syllabus uses r for displacement), then the gradient of the displacement vs. time-squared is $\frac{1}{2} a$ (initial velocity must have been 0 for this graph to be a straight line, as the acceleration is constant (the acceleration is constant, since the v-t graph is a straight line)).

Velocity time is $v = at$ (assuming initial velocity 0), so the gradient is a. So the graphs have different gradients, differing by a factor of 2.

akkatracker · Jan 28, 2015

Thanks, that was what I suspected.

akkatracker · Jan 28, 2015

InteGrand said:
If $s = \frac{1}{2}a t^2$ (no idea why the HSC Physics syllabus uses r for displacement), then the gradient of the displacement vs. time-squared is $\frac{1}{2} a$ (initial velocity must have been 0 for this graph to be a straight line, as the acceleration is constant (the acceleration is constant, since the v-t graph is a straight line)).

Velocity time is $v = at$ (assuming initial velocity 0), so the gradient is a. So the graphs have different gradients, differing by a factor of 2.

Actually one last thing:

You said the gradient of r vs time squared = 1/2 (a)

How come s/t^2 is equal to acceleration then?

InteGrand · Jan 28, 2015

akkatracker said:
How come s/t^2 is equal to acceleration then?

It's not. It's equal to $\frac{1}{2}a$ . (So it still has units of $m s^{-2}$ .)

Basic question re Motion (1 Viewer)

akkatracker

Member

InteGrand

Well-Known Member

akkatracker

Member

akkatracker

Member

InteGrand

Well-Known Member

Users Who Are Viewing This Thread (Users: 0, Guests: 1)