A ferris wheel with a radius of 30.0 m. Each of the sixty seats on the...

QUESTION 1. A ferris wheel has a radius of 12 m. The center of the ferris...

QUESTION 1. A ferris wheel has a radius of 12 m. The center of the ferris wheel is 14 m above the ground. When it is rotating at full speed the ferris wheel takes 10 s to make a full turn. We can track one seat on the ferris wheel. Let’s define t = 0 to be a time when that seat is at the top of the ferris wheel while the ferris wheel is rotating at full speed. (a)...

a ferris wheel has a radius of 5.0 m and makes one revolution every 8.0s with...

a ferris wheel has a radius of 5.0 m and makes one revolution every 8.0s with uniform rotation. a person who normally weighs 670N is sitting on one of the benches attached at the rim of the wheel. what is the apparent weight of the person as she passes through the lowest point of her motion?

A woman rides a carnival Ferris wheel at radius 17 m, completing 5.5 turns about its...

A woman rides a carnival Ferris wheel at radius 17 m, completing 5.5 turns about its horizontal axis every minute. What are (a) the period of the motion, and the magnitude of her centripetal acceleration at (b) the highest point and (c) the lowest point?

The original Ferris wheel had a radius of 38 m and completed a full revolution (2π...

The original Ferris wheel had a radius of 38 m and completed a full revolution (2π radians) every two minutes when operating at its maximum speed. If the wheel were uniformly slowed from its maximum speed to a stop in 35 seconds, what would be the magnitude of the instantaneous tangential speed at the outer rim of the wheel 20 sexonds after it begins ring its deceleration?

A Ferris wheel is a vertical, circular amusement ride with radius 8 m. Riders sit on...

A Ferris wheel is a vertical, circular amusement ride with radius 8 m. Riders sit on seats that swivel to remain horizontal. The Ferris wheel rotates at a constant rate, going around once in 8 s. Consider a rider whose mass is 54 kg. (Pls note answers in terms of vectors) A) What is the vector force exerted by the seat on the rider at the bottom of the ride? B) What is the Vector force exerted at the top...

Question 2: (CLO#6) A student of weight 667 N rides a steadily rotating Ferris wheel (the...

Question 2: (CLO#6) A student of weight 667 N rides a steadily rotating Ferris wheel (the student sits upright). At the highest point, the magnitude of the normal force on the student from the seat is 556 N. (a) Does the student feel “light” or “heavy” there? (b) What is the magnitude of at the lowest point? If the wheel’s speed is doubled, what is the magnitude at the (c) highest and (d) lowest point?

Q2: A student of weight 667 N rides a steadily rotating Ferris wheel (the student sits...

Q2: A student of weight 667 N rides a steadily rotating Ferris wheel (the student sits upright). At the highest point, the magnitude of the normal force ⃗FN on the student from the seat is 556 N. (a) Does the student feel “light” or “heavy” there? (b) What is the magnitude of ⃗FN at the lowest point? Q3: When the wheel of a car is replaced with a much greater wheels, explain what happens to the speedometer.

A Ferris wheel has diameter of 9.05 m and makes one revolution in 12.4 seconds. A...

A Ferris wheel has diameter of 9.05 m and makes one revolution in 12.4 seconds. A person weighing 588 N is sitting on one of the benches attached at the rim of the wheel. What is the apparent weight (that is, the normal force exerted on her by the bench) of the person as she passes through the highest point of her motion? Express your answer in N.

A Ferris wheel has diameter of 11.52 m and makes one revolution in 13.3 seconds. A...

A Ferris wheel has diameter of 11.52 m and makes one revolution in 13.3 seconds. A person weighing 591 N is sitting on one of the benches attached at the rim of the wheel. What is the apparent weight (that is, the normal force exerted on her by the bench) of the person as she passes through the highest point of her motion? Express your answer in N.

- Identify the physical principles and assumptions that you need to apply in order to solve...

- Identify the physical principles and assumptions that you need to apply in order to solve the problem. - Outline the steps needed to solve the problem including all mathematical calculations you will need to make. Make sure the numerical results allow you to answer the question posed. - Write explanatory language for all assumptions and mathematical steps and note all physical principles being applied during the solution. The Cosmoclock 21 Ferris wheel in Yokohama City, Japan, has a diameter...