Position-Time graph vs. Velocity-Time graph

AI Thread Summary
The discussion focuses on understanding the relationship between position-time and velocity-time graphs, particularly how to interpret curves in the position graph. The constant velocity between position 0 and time 8.2 seconds is identified as 1.5 m/s, but there is confusion regarding the representation of curved sections on the velocity-time graph. It is suggested that these curves indicate constant acceleration, leading to a parabolic shape on the velocity graph. Participants recommend identifying straight sections of the velocity graph and connecting them with straight lines, while also clarifying how to represent slowing down on the graph. The conversation emphasizes the importance of accurately translating position changes into velocity representations.
BloodyMinded
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The page layout is included in the picture attachments which are in order.
So far, if I'm correct, the constant velocity between position- 0 and time- 8.2 is 1.5m/s
The part I'm having trouble with is the curves of the line (how to figure them out and how to place them on the velocity-time graph).
What I've done for the curves is: 14-13/10-8.2 = .555 but I don't think that is right.
I would be most appreciative if you guys could help me out.
 

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BloodyMinded said:
The page layout is included in the picture attachments which are in order.
So far, if I'm correct, the constant velocity between position- 0 and time- 8.2 is 1.5m/s
The part I'm having trouble with is the curves of the line (how to figure them out and how to place them on the velocity-time graph).
What I've done for the curves is: 14-13/10-8.2 = .555 but I don't think that is right.
I would be most appreciative if you guys could help me out.

In the absence of any conflicting data, it is reasonable to a assume that the curved sections are parabolic - meaning constant acceleration - meaning the v-t graph will be sloping up or down at a constant rate.

I would usually identify the long straight sections of the v-t graph - you have the first one, the next one will last from 10 seconds to 18 seconds Then just join the ends of the straight sections [those sections will probably be disjoint] with straight lines. same for the last bit.
 
Okay, so I'm learning the same exact thing in my science class. In fact, we just had a test over it today! So, the first one is a position vs. time graph, right? Okay, so the line that you're having trouble with is more of a little "hump" like shape. The "hump" basically means that the speed of the elevator is decreasing a little.

So, you're trying to figure out how to place it on a velocity vs. time graph. Well, to show that you're slowing down on a velocity vs. time graph, you would abandon that small little diagonal line that you drew, and instead, make a straight line.

So, to put it simpler, you have your straight line, and then, make a vertical line going all the way down to 1 m/s.
*The reason you go down to 1 is because the slope of the line in the position vs. time graph is 1/1 or 1.
Then you move the line over 1 second.

(The next part kind of exceeds what your asking, but you could use it to check your work)

After that, you would go down to 0 on the horizontal axis from 10 seconds to 18 seconds. Then, since the slope of the last diagonal line is -1, you would go down (using a vertical line) to -1 on the x-axis and draw a horizontal line from 18 to 25 seconds.

Hope I helped you just a little. It took a while for me to type:)
 
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