A Ferris wheel with a 48-foot diameter makes one revolution every 3 minutes. The center of the wheel is 28 feet above the ground. A person on the Ferris wheel is closest to the ground at t=0 seconds. Let y=f(t) be the person's height above the ground at time t seconds.

The top of the Ferris wheel is at _____ ft

A Ferris wheel with a 48-foot diameter makes one revolution every 3 minutes. The center of the wheel is 28 feet above the ground. A person on the Ferris wheel is closest to the ground at t=0 seconds. Let y=f(t) be the person's height above the ground at time t seconds.

At t=0 seconds, the person is at _____ ft

A Ferris wheel with a 48-foot diameter makes one revolution every 3 minutes. The center of the wheel is 28 feet above the ground. A person on the Ferris wheel is closest to the ground at t=0 seconds. Let y=f(t) be the person's height above the ground at time t seconds.

At t=45 seconds, the person is at _____ ft

A Ferris wheel with a 48-foot diameter makes one revolution every 3 minutes. The center of the wheel is 28 feet above the ground. A person on the Ferris wheel is closest to the ground at t=0 seconds. Let y=f(t) be the person's height above the ground at time t seconds.

At t=90 seconds, the person is at _____ ft

A Ferris wheel with a 48-foot diameter makes one revolution every 3 minutes. The center of the wheel is 28 feet above the ground. A person on the Ferris wheel is closest to the ground at t=0 seconds. Let y=f(t) be the person's height above the ground at time t seconds.

At t=135 seconds, the person is at _____ ft

A Ferris wheel with a 48-foot diameter makes one revolution every 3 minutes. The center of the wheel is 28 feet above the ground. A person on the Ferris wheel is closest to the ground at t=0 seconds. Let y=f(t) be the person's height above the ground at time t seconds.

At t=180 seconds, the person is at _____ ft

A Ferris wheel with a 48-foot diameter makes one revolution every 3 minutes. The center of the wheel is 28 feet above the ground. A person on the Ferris wheel is closest to the ground at t=0 seconds. Let y=f(t) be the person's height above the ground at time t seconds.

The equation of the Ferris wheel is $y=-A\cos\left(\frac{\pi}{90}t\pi\right)+28$ .