Drag racing (a symbolic power problem)

AI Thread Summary
The discussion revolves around calculating the elapsed time for a dragster race under constant power conditions. The participant initially derives the equation t = (m*a*d)/P but is confused by the book's solution, which involves a cube root. They suspect that integration is necessary to arrive at the correct formula, specifically t = ((3d/2)^(2/3))((m/2P)^(1/3)). The conversation emphasizes the importance of understanding the relationship between power, force, and energy changes in solving the problem. Ultimately, the focus is on learning the correct problem-solving techniques rather than simply finding an answer.
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Homework Statement



A dragster of mass m races another a distance d from a dead stop. Assume a constant instaneous power P for the entire race (provided by engine) and the dragster is like a particle. Find the elapsed time for the race.


Homework Equations



Well, P = Fv is needed for this I know, and F = ma and v = d/t

so P = (m*a*d)/t

and Pt = m*a*d

so t = (m*a*d)/P

The Attempt at a Solution



Ok, I thought that the final equation was enough, but evidently there is some manipulating of variables that I am oblivious to, because hte back of the book says t = ((3d/2)^(2/3))((m/2P)^(1/3)).

I have no idea where a cube or cube root would come into play in determining the time. I have a feeling there is some integration involved, but how would a work integral give me what the book says?

So you now know I am not looking for an answer, but a method. (Judging by the fact that these conditions have been mandated for the first time I have seen them, I'm guessing people were just trying to get easy answers. I just want to learn the problem solving technique from the pros.)
 
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Integration will be required. Also, you need to go one step back from P = Fv to see where that relationship comes from and decide if it is valid in your problem.
 
Another approach would be to remember that power is change in energy per unit time. So the change in energy per time is constant in this problem.
 

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