Terminal Velocity Given Acceleration at Instantaneous Velocity

AI Thread Summary
The discussion revolves around calculating terminal velocity given specific acceleration and velocity values, with the equation ma = mg - kv being central to the problem. The user initially struggled with substituting values correctly but eventually found that not replacing ma with zero and using v^2 led to a solution of 40 m/s. There is confusion regarding the relevance of mass in the calculations, as it appears unnecessary for arriving at the terminal velocity in this context. The conversation highlights the importance of understanding when to use velocity versus velocity squared in such problems. Ultimately, the user successfully resolved the question despite initial difficulties.
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Homework Statement


This is a repost of a homework like question. The previous thread I did not understand.
In the assumption that drag is proportional to velocity, and when v = 20 m/s, a = 7.35 m/s^2, find the terminal velocity.

Homework Equations


The thread stated that the equation most relevant would be ma = mg - kv.

The Attempt at a Solution


I substituted all know values to make m(7.35) = m(9.8) - k(20), and attempted to solve, but the answer is 40 m/s.
 
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How far did you get? Did you get stuck anywhere? It is too soon to give a hint, not enough has been done.
 
verty said:
How far did you get? Did you get stuck anywhere? It is too soon to give a hint, not enough has been done.
None of that information is needed. The initial question is that it is dropped from a large height. The only information given is the information proveded (v and a).
 
Never mind. I solved it by not replacing ma with 0 but by dividing by m first and replacing v with v^2.

In these types of problems, when is v or v^2 used?
 

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