A circular Ferris wheel has a radius of 20 feet.  The center of the Ferris wheel is 26 feet above the ground.  There is one hanging seat hooked up and this seat always hangs straight down 4 feet from a point on the circumference of the Ferris wheel.  When running the Ferris wheel makes one revolution every 20 seconds and turns counterclockwise.  Construct a position function for the point at the bottom of the hanging seat (the point always 4 feet directly below a point on the circumference of the Ferris wheel).  In doing this assume the Ferris wheel reaches full speed in less than 1/4 revolution and model your position function such that the point on the circumference of the Ferris wheel directly above the hanging seat is at three o'clock at time t = 0.  From your position function find a velocity function for the point on the bottom of the hanging seat.  With the Ferris wheel at full speed, find the magnitude of the velocity of the point on the bottom of the hanging seat 5/3 seconds after it reaches its lowest point.  What is its lowest point?  Click here to see an animation.

DANCE LINE OF CIRCLES

Dancing Circles is an animation consisting of eight small circles traveling around the four limacons pictured below, two circles traveling on each limacon.  The centers of the circles follow the paths given parametrically at the right.  The centers always remain in a straight line.  Dance Line of Circles is the same animation with the addition of the rotating straight line through the centers of the circles and also a small black circle at the origin that does not move

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DANCING EYES

Click the graph to see an animation.