How High Does Henry Bounce on the Trampoline?

AI Thread Summary
To determine how high Henry bounces on the trampoline, the discussion emphasizes using principles of physics such as conservation of energy and spring-force laws rather than relying solely on standard formulas. Participants suggest treating the trampoline like a spring, which stores energy when compressed and releases it to achieve height. The net forces acting on Henry, including upward and downward forces, are crucial for calculating the maximum height. The conversation highlights the importance of applying physics knowledge creatively to derive the necessary equations. Ultimately, understanding these concepts will aid in solving the problem effectively.
MarkB4077
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The question is: Henry is bouncing on a trampoline, using the given data below, calculate the height at which Henry will bounce to from his lowest position.

Lowest position: -0.50m
Henry's Mass: 75kg
upward acceleration: 13.3 m/s^2
upward force: 1750N
downward force: 750N
Net force: 1000N
acceleration/deceleration due to gravity: 10 m/s^2
Maximum height = ?
 
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Welcome to PF;
Can you show us where you got stuck?
The way to get the best out of these forums is to attempt the problem and then we can figure out where best to give you a hand.

eg. have you tried treating the trampoline as a spring?
 
Thanks for the reply, for me it seems every formula I try either involves knowing the time it takes or the initial and final velocity. I can't seem to find any that go solely on force and acceleration AND provides the height/distance the question requires me to give.

So really I am trying to find any formulas that I may have missed or not known about. The textbook we use is absolutely worthless, so that's no help.
 
Well you are making a mistake looking for equations and formulas to start with.
For problems like this you need to use your knowledge of physics to make up your own formulas.

In this case - try conservation of energy and the spring-force laws.
Imagine the person is bouncing on a big spring.
When the spring is compressed, it stores energy. When that energy is released - it turns into another kind of energy that you know a relation for that uses height. You also know a relation for how far a spring is compressed and the force the spring exerts.

If you use those relations, and the other laws you know, you can construct the correct equation that you need without looking anything up.

That is pretty much what the problem wants you to learn to do.
 
Thanks Simon, you made a lot more sense of that than the teacher did, I think I'll get it now.
 
OK - let me know how you get on.
 

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