Dynamics of uniform circular motion

AI Thread Summary
The discussion centers on a problem involving uniform circular motion, specifically analyzing forces experienced by a rider on a loop-the-loop amusement park ride. An electronic sensor measures the normal force exerted on the rider, showing values of 770 N when stationary and 350 N at the top of the loop. The radius of the loop is 21 meters, and calculations lead to a speed of 17.3 m/s at the top of the loop. Participants confirm the setup and approach for calculating centripetal acceleration and forces, indicating that the initial setup is correct. The conversation emphasizes understanding the dynamics of vertical circular motion through practical application.
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A special electronic sensor is embedded in the seat of a car that takes riders around a circular loop-the-loop ride at an amusement park. The sensor measures the magnitude of the normal force that the seat exerts on a rider. The loop-the-loop ride is in the vertical plane and its radius is 21 m. Sitting on the seat before the ride starts, a rider is level and stationary, and the electronic sensor reads 770 N. At the top of the loop the rider is upside down and moving, and the sensor reads 350 N. What is the speed of the rider at the top of the loop?

I think this problem is a great problem for centripetal acceleration in vertical circular motion; however, I cannot check to see if I understand the concept behind the problem because there is no answer provided. Could someone please let me know if at least my set-up is correct?

-----------------------------------------------------------------------------------------
Given
R = 21 meters
W = 770 N
m = 770/9.8 kg
FN = 350 N at the top

At the top:
Fc = mg + FN = mv2 / R
R[FN + mg] = mv2

Plug-n-Chug to solve for V
V = 17.3 m/s
 
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I haven't checked the numbers, but your set up looks fine to me :approve:
 
FANTASTIC THANK YOU :biggrin:
 

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