Ferris Wheel Sinusoidal Motion
A Ferris wheel with 60-foot diameter and center 35 feet above ground completes one rotation every 120 seconds. Model the rider's height with a transformed negative cosine function, then solve to find how long the rider stays above 50 feet per rotation.
Learning Resources
This content is part of the Mathos AI open learning library. Designed to help students visualize and understand complex mathematical problems.
Problem
A Ferris wheel has a diameter of feet, a center feet above the ground, and a period of seconds; the rider starts at the bottom at , and the task is to model the height with a transformed negative cosine function and find how long the rider is above feet each rotation.
Step 1: Build the height function
The radius is half the diameter, so the amplitude is feet. Since one revolution takes seconds, the cosine coefficient is
The vertical shift is the center height, , and because the rider starts at the minimum height, the model uses negative cosine:
Step 2: Set up the height condition
To find when the rider is above feet, solve
Subtracting gives
Dividing by flips the inequality:
Step 3: Find the time interval above feet
Cosine is less than when the angle is between and , so
Multiplying through by gives
So the rider is above feet for
seconds during each rotation.
Answer
The height function is , and the rider stays above feet for seconds per rotation.
Concepts
Sinusoidal Modeling
Using sine or cosine functions to model periodic real-world phenomena such as temperature cycles, tides, and circular motion. Determine the amplitude, period, phase shift, and midline from the data.
More videos
© 2026 Mathos. All rights reserved



