How Does a Skydiver's Velocity Change with Distance After Parachute Deployment?

AI Thread Summary
A skydiver reaches a terminal velocity of 373 m/s before deploying a parachute at 1500m, where the drag force is modeled as bv² and weight is ignored. The discussion focuses on deriving an expression for velocity as a function of distance after parachute deployment, with initial attempts leading to confusion over the role of gravity and the correct application of equations. Participants emphasize the importance of eliminating time from the acceleration equation to find velocity in terms of distance. Clarifications are sought regarding the integration steps and the treatment of forces involved. Ultimately, the original poster expresses gratitude for the assistance and indicates progress in understanding the problem.
Will Freedic
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Homework Statement


A sky driver reaches his terminal velocity of 373 ms^-1 and deploys his parachute at a height of 1500m, the drag force =bv^2 and weigh can be ignored. Find an expression for velocity as a function of distance traveled from the point the parachute was deployed

The Attempt at a Solution


I can find velocity as a function of time easy enough but not a function of distance[/B]
 
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Hi Will, :welcome:

Please read the guidelines, use the template, don't delete parts of the template, show your work so far and we'll help you from the point where you get stuck.
 
Will Freedic said:

Homework Statement


A sky driver reaches his terminal velocity of 373 ms^-1 and deploys his parachute at a height of 1500m, the drag force =bv^2 and weigh can be ignored. Find an expression for velocity as a function of distance traveled from the point the parachute was deployed
A terminal velocity of 373 m/s is quite a feat. It's also greater than Mach 1, which makes it unlikely to occur. Are you sure a decimal point hasn't been misplaced?
 
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There is a standard trick for eliminating time from an acceleration equation.
##a=\frac{dv}{dt}=\frac{dv}{dx}\frac{dx}{dt}=v\frac{dv}{dx}##.
Note that if we apply this to F=ma and integrate wrt x we get ##\int F.dx=\frac 12 mv^2##.
 
Thank you!, so is it correct to say that:

Cv2 = ma
cv2 = mv dvdx.
Cm/x = v2 / 2 + c
Cheers
 
Will Freedic said:
Thank you!, so is it correct to say that:

Cv2 = ma
cv2 = mv dvdx.
Cm/x = v2 / 2 + c
Cheers
A couple of problems there. First, what happened to gravity? Secondly, I don't understand what you did to get from cv2 = mv dvdx (presumably you meant mv dv/dx) to Cm/x = v2 / 2 + c
 
haruspex said:
A couple of problems there. First, what happened to gravity? Secondly, I don't understand what you did to get from cv2 = mv dvdx (presumably you meant mv dv/dx) to Cm/x = v2 / 2 + c
Thank you for your help, i am new to these forums so am a little slow!, managed to get there now tho
 

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