How Long Does It Take for a Dropped Camera to Hit the Ground?

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A parachutist drops a camera from 50m while descending at 10m/s, raising questions about the correct use of speed and velocity in calculations. The initial velocity should be negative due to the downward motion, and the displacement must also be negative, set at -50m. The appropriate equation to use is -4.9t² - 10t + 50 = 0, which accounts for both the initial height and downward acceleration. Solving this quadratic equation will yield two roots, one of which will be negative, representing an impossible scenario. The focus should be on the positive root to determine the actual time it takes for the camera to hit the ground.
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A parachutist descending at a speed of 10m/s drops a camera from an altitude of 50m. How long does it take the camera to reach the ground?

Is speed the same thing as velocity in this case? If not, what do I do? I assumed it was the same and went: Vi= 10; a=-9.8; d=50 goes into formula d=Vit + 1/2at^2. But something's wrong... :mad:
 
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The camera is moving down initially, so vi has to be negative.
 
I keep getting a negative root when I try to do the quadratic formula. WHY? Wait, I tried a different formula and now I get negative time which is impossible. Are you sure it's supposed to be -10m/s?
 
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I forgot to say something: d is negative, too.

That's because d=y-y0. If your initial height is 50 m and your final height is 0 m, you can see that d=-50 m.
 
First establish your coordinate system: Take the ground to be 0, positive upward. Then a= -9.8 m/s2, initial velocity= -10 m/s, initial height= 50 m.
The equation for height of the camera is -4.9t2- 10t+ 50 and we want to determine when the height will be 0-
Solve -4.9t2- 10t+ 50= 0. One root will be negative- that's the time at which if you had thrown the camera up into the air it would now be at 50 m with downward velocity of -10 m/s. Obviously, you want the positive root.
 

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