Whether the drag force can be treated as solely linear or quadratic depends on the speed of the object. Both the linear and quadratic terms are always present. In the low velocity limit, the linear term dominates. This makes the quadratic term negligible. As the velocity increases, the quadratic term becomes more relevant. At large enough speeds the linear term is the one that can be neglected, which is what yields the model your referring to.

Could you help me understand why we take the derivative of u with respect to v. Like I get we have to get it to u, but what’s the point of doing it.

@@MarkSmith-vo1vn It's a substitution. it's for changing the variable from v to u so he can make use of the property integral{du/u} = ln|u| + c

@@phandinhthanh2295 So before the substitution I am reading it as take the integral with respect to v. I get you have to replace dv with du, but why must you take the derivative if it’s already derived to v, since acceleration is dv/dt. 1/u is equivalent to the pre-subisution, which is already derived. Like I get what he does, I just don’t get why he does it. Like isn’t it already equivalent. I am seeing dv is more of a notation than a variable idk if I am getting that bit wrong(do we not know the derivative of velocity already, like isn’t the derivative of velocity dv/dt = (mg-kv)/m Thanks for help

@@MarkSmith-vo1vn I'm not sure I understand your question. Everytime I make a substitution when I solve a integral, I always take a derivative of the new variable wrt the old variable to get the relationship between the differential(the du, dv-part) of the new and the old variable. B/c you have to change not only the variable in the integrand(the function under the integral sign) but also in the differential(dv-> du). Perhaps, he wants to simplify the integral making it easier for us to follow the steps.

How did you still retain = mg/k? From your method, we divide both sides by m. Gives us g - (k/m)v = dv/dt. Then we add (k/m)v to both sides We now only have dv/dt + (k/m)v = g. Can you explain if there was something else you did?

That's at velocities much greater than the critical velocity. Watch the 8.01x lecture on Drag and Resistive forces and you'll see what I mean :)

In air, yes! You can check out this video ( kzbin.info/www/bejne/jZS2nHqHqKt-g6c ) for projectile motion in 1 dimension with (quadratic) air drag, and this video ( kzbin.info/www/bejne/eZuxiKmJmMxnipI ) 2 dimensional projectile motion with (quadratic) air drag!

When the velocity is very high, then its equal go v^2

Its a constant

A constant that involves the density of the fluid(air) it is moving through, the shape of the object and the area of the object that is in contact with the fluid (air)

Yes! And that's where the constant K comes in. It is proportional to the area pf the object you're studying. Hreater area, greater K, so that mg/K denominator gets smaller. And don't forget the negative exponent of the exponential function. If it gets vreater,than again the result is gonna be smaller (smaller velocity, in this case).