course PHY201 }Нďw{assignment #009
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15:20:41 Introductory prob set 3 #'s 1-6 If we know the distance an object is pushed and the work done by the pushing force how do we find the force exerted by the object?
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RESPONSE --> work = force * distance solve for force: force = work / distance confidence assessment: 2
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15:21:12 ** Knowing the distance `ds and the work `dW we note that `dW = F * `ds; we solve this equation and find that force is F=`dw/`ds **
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RESPONSE --> self critique assessment: 3
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15:26:19 If we know the net force exerted on an object and the distance through which the force acts how do we find the KE change of the object?
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RESPONSE --> `dW = F * `ds
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15:29:06 **`dW + `dKE = 0 applies to the work `dW done BY the system and the change `dKE in the KE OF the system. The given force acts ON the system so F `ds is work done ON the system. The work done BY the system against that force is `dW = -F * `ds. When you use the energy equation, this is the work you need--the work done BY the system. **
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RESPONSE --> I think I understand this, but in the answer it says: `dW = -F * `ds and I would have thought that this would have been: `dKE = -F * `ds I think I may have gotten this backwards, I am not sure.
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15:35:13 Why is KE change equal to the product of net force and distance?
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RESPONSE --> Because `dKE and `dW are offsetting values, they always sum to 0. Net force and distance equal work done on an object, and that object exerts an equal and opposite force such that the force that an object exerts will be the opposite value of the product of net force and distance done against that object. confidence assessment: 1
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15:57:01 ** It comes from the equation vf^2 = v0^2 + 2 a `ds. Newton's 2d Law says that a = Fnet / m. So vf^2 = v0^2 + 2 Fnet / m `ds. Rearranging we get F `ds = 1/2 m vf^2 - 1/2 m v0^2. Defining KE as 1/2 m v^2 this is F `ds = KEf - KE0, which is change in KE. **
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RESPONSE --> I will copy this out to my notes and take a closer look at it. I need to spend some more time with these new concepts. self critique assessment: 1
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16:01:12 When I push an object with a constant force, why is KE change not equal to the product of the force I exert and the distance?
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RESPONSE --> The only thing I can think of is that there are losses due to friction, but I think that the question probably assumes a theoretical environment without friction, in which case I don't understand the question, I thought that KE would be changed the amount of the product of force and distance. Unless the force was not applied in a direction parallel to the motion of the object. confidence assessment: 0
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16:08:07 ** Change in KE is equal to the work done by the net force, not by the force I exert. When I push an object in the real world, with no other force 'helping' me, there is always at least a little force resisting my push. So the net force in this case is less than the force I exert, in which case the change in KE would be less than the product of the force I exert and the distance. If another force is 'helping' me then it's possible that the net force could be greater than the force I exert, in which case the change in KE would be greater than the product of the force I exert and the distance. It is actually possible for the 'helping' force to exactly balance the resisting force, but an exact balance would be nearly impossible to achieve. ANOTHER WAY OF LOOKING AT IT: If I push in the direction of motion then I do positive work on the system and the system does negative work on me. That should increase the KE of the system. However if I'm pushing an object in the real world and there is friction and perhaps other dissipative forces which tend to resist the motion. So not all the work I do ends up going into the KE of the object. **
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RESPONSE --> I think I had the gist of question correct.
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